key: cord-008695-y7il3hyb authors: nan title: Pandemic Flu: Clinical management of patients with an influenza-like illness during an influenza pandemic date: 2007-01-25 journal: J Infect DOI: 10.1016/s0163-4453(07)60001-2 sha: doc_id: 8695 cord_uid: y7il3hyb nan • This document is intended for use in the UK in the event that the World Health Organisation declares that an influenza pandemic has started 1 , and the Department of Health in England (UK-wide lead agency on pandemic influenza, including the devolved administrations) has declared UK Pandemic Alert Level 2 (cases of pandemic influenza identified within the UK). • These guidelines are not relevant for the management of patients affected by seasonal/interpandemic influenza, lower respiratory tract infections, community-acquired pneumonia or exacerbations of chronic obstructive pulmonary disease (COPD). • Once an influenza pandemic is under way, users are strongly urged to ensure that they refer to the most up-todate version of these guidelines (from web-based access points). Synopsis 1. Clinical management of adults referred to hospitals S1.1. Severity assessment in hospital • Patients with uncomplicated influenza infection would be expected to make a full recovery and do not require hospital care. • In uncomplicated infection, the illness usually resolves in seven days although cough, malaise and lassitude may persist for weeks. • Patients with worsening of pre-existing co-morbid medical conditions should be managed according to best practice for that condition with reference to published disease-specific guidelines, if available, for example, the National Institute of Clinical Excellence's COPD guideline. • In hospital, patients with influenza-related pneumonia and who have a CURB-65 score of 3, 4 or 5 (see Box A) are at high risk of death and should be managed as having severe pneumonia. • Patients with bilateral lung infiltrates on chest radiography consistent with primary viral pneumonia should be managed as having severe pneumonia regardless of CURB-65 score. • Patients who have a CURB-65 score of 2 are at increased risk of death. They should be considered for short stay inpatient treatment or hospital supervised outpatient treatment. This decision is a matter of clinical judgment. • Patients who have a CURB-65 score of 0 or 1 are at low risk of death. They can be treated as having non-severe pneumonia and may be suitable for home treatment. • Patients with primary viral pneumonia or a CURB-65 score of 4 or 5 should be considered for HDU/ICU transfer. • General indications for HDU/ICU transfer include: (1) persisting hypoxia with PaO 2 < 8 kPa despite maximal oxygen administration (2) progressive hypercapnia (3) severe acidosis (pH < 7.26) (4) septic shock • Patients with influenza admitted to intensive care unit should be managed by specialists with appropriate training in intensive care, respiratory medicine and/or infectious diseases. Pandemic flu. Clinical management of patients with an influenza-like illness during an influenza pandemic S3 S1.4. General investigations • The following investigations are recommended in patients referred to hospital: Who this applies to Full blood count All patients Urea and electrolytes All patients Liver function tests All patients Chest X-ray All patients Pulse oximetry All patients. If <92% on air, then arterial blood gases. Patients with cardiac and respiratory complications or co-morbid illnesses. C-reactive protein If influenza-related pneumonia is suspected • In those patients who are subsequently followed up in a hospital outpatient clinic or by a general practitioner a repeat chest X-ray should be obtained at around six weeks if respiratory symptoms or signs persist or where there is a higher risk of underlying malignancy (especially smokers and those over 50 years of age). • Further investigations including a CT thoracic scan and bronchoscopy should be considered if the chest X-ray remains abnormal at follow up. S1.5. Microbiological investigations S1.5.1. Early in a pandemic (UK alert levels 1, 2 and 3) • Virology all patients (1) Nose and throat swabs in virus transport medium. (2) If presentation is more than seven days after onset of illness, an 'acute' serum (5 10 ml clotted blood) should be collected and a 'convalescent' sample (5 10 ml clotted blood) obtained after an interval of not less than seven days. • Bacteriology patients with influenza-related pneumonia (1) Blood culture (preferably before antibiotic treatment is commenced) (2) Pneumococcal urine antigen (20 ml urine sample) (3) Legionella urine antigen (20 ml urine sample) (4) Sputum gram stain, culture and antimicrobial susceptibility tests on samples obtained from patients who: (i) are able to expectorate purulent samples, and (ii) have not received prior antibiotic treatment. (5) Paired serological examination for influenza/other agents. Acute serum should be collected and a 'convalescent' sample obtained after an interval not less than seven days (both 5 10 ml clotted blood). • Virology not routinely recommended • Bacteriology patients with influenza-related pneumonia in accordance to the severity of illness. (a) Non-severe pneumonia (CURB-65 Score 0, 1 or 2) No routine testing. In patients who do not respond to empirical antibiotic therapy, sputum samples should be sent for Gram stain culture and antimicrobial susceptibility tests. b Severe pneumonia (CURB-65 Score 3, 4 or 5, or bilateral CXR changes) Blood culture, preferably before antibiotic treatment is commenced Pneumococcal urine antigen (20 ml urine) Sputum gram stain, culture and antimicrobial susceptibility tests on samples obtained from patients who are able to expectorate purulent samples, and have not received prior antibiotic treatment. Paired serological examination for influenza/other agents. 'Acute' serum should be collected and a 'convalescent' sample obtained after an interval not less than seven days (both 5 10 ml clotted blood). Tracheal or endotracheal aspirate samples, if available, should be sent for Gram stain, culture and antimicrobial susceptibility testing. S1.6. General management S1. 6 • Hypoxic patients should receive appropriate oxygen therapy with monitoring of oxygen saturations and inspired oxygen concentration with the aim to maintain PaO 2 8 kPa and SaO 2 ges; 92%. High concentrations of oxygen can safely be given in uncomplicated pneumonia. • Oxygen therapy in patients with pre-existing chronic obstructive pulmonary disease complicated by ventilatory failure should be guided by repeated arterial blood gas measurements. Non-invasive ventilation may be helpful. • In patients without pre-existing COPD who develop respiratory failure, NIV may be of value as a bridge to invasive ventilation in specific circumstances when level 3 beds are in high demand. Respiratory and/or critical care units experienced in the use of NIV are best placed to ensure the appropriate infection control measures are adopted at all times. • Patients should be assessed for cardiac complications and also volume depletion and their need for additional intravenous fluids. • Nutritional support should be given in severe or prolonged illness. • Temperature, respiratory rate, pulse, blood pressure, mental status, oxygen saturation and inspired oxygen concentration should be monitored and recorded initially at least twice daily and more frequently in those with severe illness or requiring regular oxygen therapy. An Early Warning Score system is a convenient way to perform this. • In patients who are not progressing satisfactorily a full clinical reassessment and a repeat chest radiograph are recommended. • Patients should be reviewed 24 hours prior to discharge home. Those with two or more of the following unstable clinical factors should consider remaining in hospital: (1) temperature >37.8ºC (2) heart rate >100/min (3) respiratory rate >24/min (4) systolic blood pressure <90 mmHg (5) oxygen saturation <90% (6) inability to maintain oral intake (7) abnormal mental status • Follow up clinical review should be considered for all patients who suffered significant complications or who had significant worsening of their underlying disease, either with their general practitioner or in a hospital clinic. • At discharge or at follow up, patients should be offered access to information about their illness, take home medication and any follow up arrangements. • It is the responsibility of the hospital team to arrange the follow up plan with the patient and the general practitioner. • Individuals should only be considered for treatment with antivirals (neuraminidase inhibitors) if they have all of the following: (1) an acute influenza-like illness (2) fever (>38ºC) and (3) been symptomatic for two days or less. • Treatment schedule: Adults Oseltamivir 75 mg every 12 hours for five days. (Dose to be reduced by 50% if creatinine clearance is less than 30 ml/minute, i.e. 75 mg od). • Patients who are unable to mount an adequate febrile response, e.g. the immunocompromised or very elderly, may still be eligible for antiviral treatment despite lack of documented fever. • Hospitalised patients who are severely ill, particularly if also immunocompromised, may benefit from antiviral treatment started more than 48 hours from disease onset, although there is no evidence to demonstrate benefit, or lack of it, in such circumstances. S1.8. Antibiotic management S1.8.1. Influenza • Previously well adults with acute bronchitis complicating influenza, in the absence of pneumonia, do not routinely require antibiotics. • Antibiotics should be considered in those previously well adults who develop worsening symptoms (recrudescent fever or increasing dyspnoea). • Patients at high risk of complications or secondary infection (Appendix 2) should be considered for antibiotics in the presence of lower respiratory features. • Most patients can be adequately treated with oral antibiotics. • The preferred choice includes co-amoxiclav or a tetracycline. • A macrolide such as clarithromycin (or erythromycin) or a fluoroquinolone active against Streptococcus pneumoniae and Staphylococcus aureus is an alternative choice in certain circumstances. • Most patients can be adequately treated with oral antibiotics. • Oral therapy with co-amoxiclav or a tetracycline is preferred. • When oral therapy is contra-indicated, recommended parenteral choices include intravenous co-amoxiclav, or a second or third generation cephalosporin (cefuroxime or cefotaxime). • A macrolide (erythromycin or clarithromycin) or a fluoroquinolone active against S. pneumoniae and Staph. aureus is an alternative regimen where required eg. for those intolerant of penicillins. Currently levofloxacin and moxifloxacin are the only recommended fluoroquinolones licensed in the UK. • Antibiotics should be administered within four hours of admission. • Patients with severe pneumonia should be treated immediately after diagnosis with parenteral antibiotics. • An intravenous combination of a broad spectrum b-lactamase stable antibiotic such as co-amoxiclav or a second (e.g. cefuroxime) or third (e.g. cefotaxime) generation cephalosporin together with a macrolide (e.g. clarithromycin or erythromycin) is preferred. • An alternative regimen includes a fluoroquinolone with enhanced activity against pneumococci together with a broad spectrum b-lactamase stable antibiotic or a macrolide. Currently levofloxacin is the only fluoroquinolone with an intravenous formulation licensed in the UK. • Patients treated initially with parenteral antibiotics should be transferred to an oral regimen as soon as clinical improvement occurs and the temperature has been normal for 24 hours, providing there is no contra-indication to the oral route. • For most patients admitted to hospital with non severe and uncomplicated pneumonia, seven days of appropriate antibiotics is recommended. • For those with severe, microbiologically undefined pneumonia, ten days treatment is proposed. This should Synopsis 1. Clinical management of adults referred to hospitals Synopsis of main recommendations Pandemic flu. Clinical management of patients with an influenza-like illness during an influenza pandemic S5 be extended to 14 to 21 days where Staph aureus or Gram negative enteric bacilli pneumonia is suspected or confirmed. • For those with non-severe pneumonia in hospital on combination therapy, changing to a fluoroquinolone with effective pneumococcal and staphylococcal cover is an option. • Adding further antibiotics effective against MRSA is an option for those with severe pneumonia not responding to combination antibiotic therapy. • High fever (>38.5ºC) and cough or influenza-like symptoms. These children should seek advice from a community health professional. If there are no features that put them at high risk of complications they should be treated with oseltamivir, and given advice on antipyretics and fluids. Children aged <1 year and those at risk of complications (Appendix 2) should be seen by a GP. • High fever (>38.5ºC) and cough or influenza-like symptoms, plus at risk group. These children should be seen by a GP or in A&E. Children may be considered at increased risk of complications if they have cough and fever (or influenza-like illness) and temperature >38.5ºC, plus either chronic co-morbid disease or one of following features: breathing difficulties severe earache vomiting >24 hours drowsiness These patients should be offered an antibiotic as well as oseltamivir (in those >1 year of age) and advice on antipyretics and fluids. Children aged <1 year with none of the above features should be treated with antipyretics and fluids with a low threshold for antibiotics if they become more unwell. • Indicators for hospital admission are: (1) Signs of respiratory distress. markedly raised respiratory rate grunting intercostal recession breathlessness with chest signs (2) Cyanosis (3) Severe dehydration (4) Altered conscious level (5) Complicated or prolonged seizure (6) Signs of septicaemia extreme pallor, hypotension, floppy infant • Most children admitted to hospital are likely to need oxygen therapy and/or intravenous support as well as antibiotics and oseltamivir. • Indications for transfer to high dependency or intensive care are: (1) failure to maintain SaO 2 > 92% in FiO 2 > 60% (2) the child is shocked (3) severe respiratory distress and a raised PaCO 2 (>6.5 kPa) (4) rising respiratory rate and pulse rate with clinical evidence of severe respiratory distress with or without a raised PaCO 2 (5) recurrent apnoea or slow irregular breathing (6) evidence of encephalopathy • When there are no PICU beds available, children will have to be triaged on the basis of the severity of their acute and co-existing disease, and the likelihood of their achieving full recovery. • A full blood count with differential, urea, creatinine and electrolytes, liver enzymes and a blood culture should be done in all severely ill children. • A CXR should be performed in children who are hypoxic, have severe illness or who are deteriorating despite treatment. • Pulse oximetry should be performed in every child being assessed for admission to hospital with pneumonia. • Virology all children (1) Nasopharyngeal aspirate or nose and throat swabs (2) If presentation is more than 7 days after onset of illness, an 'acute' serum (2 5 ml clotted blood) should be collected and a 'convalescent' sample (2 5 ml clotted blood) obtained after an interval of not less than 7 days. • Bacteriology children with influenza-related pneumonia (1) Blood culture (before antibiotic treatment is commenced) (2) Sputum samples obtained from older children (3) Paired serological examination for influenza/other agents. • Virology not routinely recommended • Bacteriology children with influenza-related pneumonia (1) Blood culture (before antibiotic treatment is commenced) (2) Sputum samples obtained from older children • Patients whose oxygen saturation is 92% or less while breathing air should be treated with oxygen given by nasal cannulae, head box, or face mask to maintain oxygen saturation above 92%. • When children are unable to maintain oral intake, supplementary fluids should, when possible, be given by the enteral route. Intravenous fluids in those with severe pneumonia should be given at 80% basal levels. • Children can be safely discharged from hospital when they: (1) are clearly improving (2) are physiologically stable (3) can tolerate oral feeds (4) have a respiratory rate <40/min (<50/min in infants) (5) have an awake oxygen saturation of >92% in air. • In the setting of a pandemic, children should only be considered for treatment with antivirals if they have all of the following: (1) an acute influenza-like illness (2) fever (>38.5ºC) and (3) been symptomatic for two days or less • Oseltamivir is the antiviral agent of choice. • In children who are severely ill in hospital oseltamivir may be used if the child has been symptomatic for <6 days (but there is no evidence to demonstrate benefit, or lack of it, in such circumstances). • Children (a) who are at risk of complications of influenza or (b) with disease severe enough to merit hospital admission during an influenza pandemic should be treated with an antibiotic that will provide cover against S. pneumoniae, Staph. aureus and H. influenzae. • For children under 12 years co-amoxiclav is the drug of choice. Clarithromycin or cefuroxime should be used in children allergic to penicillin. For children over 12 years doxycycline is an alternative. • Oral antibiotics should be given provided oral fluids are tolerated. • Children who are severely ill with pneumonia complicating influenza should have a second agent added to the regime (e.g. clarithromycin or cefuroxime) and the drugs should be given intravenously to ensure high serum and tissue antibiotic levels. To facilitate preparedness planning, this document has been written in advance of the emergence of the next influenza pandemic, at a time when the identity of the causative virus remains unknown. These guidelines are based on the best evidence available from previous pandemic and interpandemic influenza periods. The guidance may evolve as clinicopathological information on the eventual pandemic virus emerges. Once an influenza pandemic is under way, users are strongly urged to refer to the most up-todate version of these guidelines (from web-based access points). Seasonal influenza is a familiar infection in the UK, especially during winter. Every year strains of influenza (type A or B) circulate, giving rise to clinical consultations in primary care (age-specific impact varies by season), episodes of hospital treatment (mainly in older persons and young children, but occasionally in working age adults), and deaths (mainly in the elderly). Treatment in primary care and hospital may be required due to the direct effects of influenza virus infection or its possible complications, most commonly secondary bacterial pneumonia. Increases in GP consultations for influenza-like illness and winter bed pressures are frequently associated with periods of known community influenza activity 6 . Pandemic influenza occurs when a new influenza A virus subtype emerges which is markedly different from recently circulating subtypes and strains, and is able to: • infect humans; • spread efficiently from person to person; • cause significant clinical illness in a high proportion of those infected. Because the virus is novel in humans, a high proportion of the population will have little or no immunity, producing a large pool of susceptible persons; accordingly the disease spreads widely and rapidly. Influenza pandemics occur sporadically and unpredictably. In 1918, a devastating and unusual pandemic caused by influenza A/H1N1 ('Spanish flu') killed between 20 and 40 million people worldwide. Other pandemics that followed had a less devastating impact but were nevertheless severe. Influenza A/H2N2 ('Asian flu') emerged in 1957, and H3N2 ('Hong Kong flu') in 1968; both produced roughly 1 million excess deaths worldwide 7 . The circumstances still exist for a new influenza virus with pandemic potential to emerge and spread, and the longest interval so far recorded between pandemics is 39 years (1918 1957) . The unpredictability of the timing of the next pandemic is underlined by the occurrence of several large outbreaks of highly pathogenic avian influenza associated with epizootic transmission to humans 8 . By far the most serious has been the massive and unprecedented outbreak of highly pathogenic influenza (A/H5N1) affecting poultry in East and South East Asia in late 2003, which is still continuing. This outbreak has so far been associated with a small number of human cases but a high proportion of deaths. Recently, epidemiological and virological changes have been reported from northern Vietnam which may indicate that the virus is beginning to adapt to humans 9 . Although the emergence of an A/H5N1 strain with capacity to spread efficiently between humans is neither inevitable nor imminent, international concern has increased regarding the possibility that avian influenza A/H5N1 may evolve to produce the next pandemic. Other events and developments that inform the creation of this guidance are the development and licensing of a new class of drug (neuraminidase inhibitors) active against influenza, and UK government's announcement of plans to procure 14.6 million treatment courses of oseltamivir (Tamiflu ® ) 10 for use in the UK in the event of a pandemic. be involved in the management of patients with influenza. It is intended that these guidelines also be of value to health-care practitioners who do not usually manage patients with influenza but may be called upon to do so in a pandemic situation. Modification of some recommendations at a local level may be necessary in specific instances. These guidelines are not relevant for the management of patients affected by seasonal influenza, sporadic acute exacerbations of chronic obstructive pulmonary disease (AECOPD), lower respiratory tract infections (LRTIs) or community-acquired pneumonia (CAP). At the primary care level, a national Operational Plan including the following three broad areas is deemed important: (a) clinical management of patients with influenza (b) management of patient demand, including patients who do not have influenza (c) health service delivery plans These guidelines cover the first of these areas and will serve as the source document for the Primary Care Operational Plan. The Primary Care Operational Plan will incorporate all three areas within a single reference and is being developed by the DH in collaboration with the RCGP and the BMA. Even though it is impossible to predict with certainty the impact of the next pandemic, based upon the available epidemiological and modelling information, it is clear that it will generate demands for health care which may saturate or overwhelm normal NHS acute services for a period of time, perhaps several weeks or months. Accordingly, it should be anticipated that the NHS (in common with all health systems around the world) will need to revert to emergency arrangements. These are laid out in further detail in Operational Guidance for Health Service Planners 4 , the UK Operational Framework for stockpiling, distributing and using antiviral drugs in the event of pandemic influenza 5 and in the Primary Care Operational Plan. With regard to the delivery of medical care for patients with influenza this is normally achieved through: • GP treatment of community patients 'well' enough to be managed in the community • hospital care in acute medicine for persons considered too ill to be managed at home. In the event of a pandemic, the following additional care settings may have to be considered as the threshold for hospital admission rises: • Treatment of patients in the community (who would normally receive care from a GP) by other health-care professionals (nurses, paramedics, pharmacists etc.) following treatment guidance laid out in this publication and using Prescription-only medicines according to Patient Group Directives (PGDs). • Treatment of patients in their own homes or in temporary intermediate care facilities by a GP, following treatment guidance laid out in this publication when, under normal circumstances, such patients would have been admitted for hospital care. • Treatment of severely ill patients in hospital by medical and nursing teams who do not normally manage patients with influenza or community-acquired pneumonia, in areas of the hospital not normally used for providing medical care (for example, surgical teams and bed space diverted from routine elective work towards pandemic response). The recommendations offered in the current guidelines are based on a matrix of evidence centred mainly around seasonal influenza, expert opinion and group consensus. Grading of these recommendations based on the strength of the evidence base was deemed inappropriate. Section 2. Epidemiology and health impact projections (1) The scale and severity of illness (and hence consequences) caused by pandemic influenza generally exceed those of even the most severe winter epidemics. (2) Mortality in the UK is likely to exceed 50,000 deaths, possibly appreciably higher. (3) Besides the elderly, excess mortality is also likely in younger adults and children. (4) Modelling studies suggest that after a case occurs in Hong Kong, because of international travel, it will take less than one month for the virus to reach the UK. (5) Once cases begin to occur in the UK it will take only two to three weeks before activity is widespread and roughly a further three weeks (six weeks after initial cases in UK) until activity peaks. (6) It is possible that there will be more than one epidemic wave (with an interval of several months) and, if a second wave occurs, it may be more severe than the first. (7) Cumulative clinical and serological attack rates across all waves together may be in the order of 25% and 50% respectively. (8) Increases in demand for health-care services are likely to be very substantial in both primary care and hospital settings. When an influenza pandemic occurs, a substantial proportion (possibly all) of the population is likely to be non-immune, producing a large pool of susceptible persons. In past pandemics, the scale and severity of illness (and hence consequences) have been variable but broadly of a §2. Epidemiology and health impact projections Introductory observations higher order than even the most severe winter epidemics. It is reasonable to expect this to be the case with the next pandemic as well. Excess mortality due to influenza occurs in most winter seasons but is especially marked during epidemics. The average annual excess mortality attributable to influenza in recent years is around 12,000 deaths per annum in England and Wales 11 , although there is considerable yearly variation and some years are notably much higher than the average (est. 26,000 in 1989/90 epidemic). Excess mortality in England and Wales associated with the three pandemics of the twentieth century has also varied widely; this was estimated at 198,000 civilians in 1918/19, and 37,500 in 1957/58. In 1968/69 and 1969/70 (both seasons considered to be associated with the influenza A/H3N2 pandemic), there were an estimated 31,000 and 47,000 deaths respectively 7 . Therefore the extent of mortality associated with the next pandemic cannot be reliably predicted although it is reasonable to plan for a scenario worse than a severe winter epidemic of normal influenza. Typically, there are changes in the age-distribution of cases compared with seasonal influenza. Mortality, which in typical seasonal influenza is usually confined to age groups over 65 years, tends to be increased in younger age groups. The size of any increase in morbidity and mortality and the extent to which a shift in age distribution occurs depend on a variety of factors including the nature of the pandemic virus and pre-existing immunity but appears to be a consistent phenomenon 12 . Therefore, clinicians can expect to see relatively larger amounts of influenza-related illness in younger adults compared with normal winter activity. At least one third of all excess deaths may be expected in persons under 65 years of age. Virological and clinical surveillance of influenza have improved markedly since the last pandemic in 1968. However, the extent of international travel has also grown. Modelling studies using transmission characteristics based on the 1968/69 pandemic and international air-traffic data from 2002 indicate that the approximate delay between a first case in Hong Kong and first introduction to UK will be less than one month 13 . In terms of the spread within the UK, it will probably take only two to three weeks from the initial introduction(s) until activity is widespread and a further three weeks (six weeks from initial UK cases) until activity peaks. The temporal and spatial spread of a pandemic strain is important, particularly in terms of the demand placed on health-care services. Pandemic activity taking the form of a brief but severe peak in cases will be more difficult for all services to cope with, compared with an identical number of cases distributed over a longer time course. For example, during the A/H3N2 pandemic a long first wave occurred in the winter of 1968/9 with morbidity and mortality approximately at the same level as the previous seasonal influenza; but in the following winter of 1969/70 a short and more severe epidemic occurred with a threefold higher peak in general practice consultation rates and a four-fold higher peak in mortality attributed to influenza, bronchitis and pneumonia. The high peak in consultation rates is well illustrated in Fig. 2 .1. In 1918/19, the A/H1N1 pandemic occurred in three distinct epidemic waves: early spring 1918, autumn 1918 Introductory observations §2. Epidemiology and health impact projections S10 Provisional guidelines from BIS/BTS/HPA in collaboration with the Department of Health, Version 11 (2 October 2006) and late winter 1919. The second wave was by far the largest and case-fatality rates were also higher than in the first wave. The A/H3N2 pandemic caused an epidemic wave in the winter of 1968/69 but a more severe one in 1969/70. In contrast, the second wave of the 1957/58 pandemic in the UK was very small in comparison to the first 7 . Thus it should be considered a possibility that more than one wave of influenza will occur within a few months of the emergence of a pandemic virus and a subsequent wave could be worse than the first. It is impossible to predict reliably with precision the level of excess mortality that will be experienced in the next pandemic. However, Table 2 .1 illustrates the broad range of excess mortality that it is reasonable to consider, based on various realistic combinations of case fatality rate and clinical attack rates derived from previous pandemics and epidemics. A case fatality rate of 0.37% corresponds to the aggregate rate observed in recent epidemic seasons (1989/90, 1991/92, 1993/94, 1995/96, 1996/97, 1997/98 and 1998/99) and the 1957 pandemic, although the overall case-fatality rate observed in the 1918 19 pandemic was in the region of 1 2%. A clinical attack rate of around 25% corresponds to the approximate clinical attack rate seen in all three previous pandemics of the twentieth century. Thus, a figure of at least 50,000 excess deaths is likely. Using mathematical projections, it is possible to illustrate the potential impact of the next pandemic, but these do not amount to accurate predictions. Table 2 .2 summarises the number of events that might be expected by a GP with 1000 patients on his/her list and by a PCT serving a population of 100,000 persons. Using the same assumptions, Table 2 .3 illustrates the number of events by week over an assumed 15-week (single wave) pandemic period in a typical PCT population of 100,000. Most major acute trusts receive patients from a catchment area spanning several PCTs and the figures below require pro-rata adjustment before applying to individual hospitals. Section 3. Clinical features in adults (1) Influenza is clinically defined as the presence of fever and new (or, in those with chronic lung disease, worsening) cough of acute onset in the context of influenza circulating in the community. This clinical definition may be modified once a pandemic occurs. (2) The spectrum of clinical disease associated with a pandemic strain cannot be forecast. (3) Pneumonia, either primary viral or secondary bacterial, is the commonest complication of influenza in adults. (4) Neurological complications are rare in adults. The clinical manifestations of infection by influenza viruses are diverse, ranging from asymptomatic infection to fulminant respiratory distress leading to respiratory failure and death. Furthermore, the presence of an influenza-like illness (ILI) comprising of a combination of fever, cough, sore throat, myalgia and headache is not specific for influenza infection. Other respiratory pathogens that may present with an ILI include viruses such as respiratory syncytial virus (RSV), adenovirus, rhinovirus and parainfluenza virus, as well as bacterial pathogens such as Chlamydia pneumoniae, Legionella sp., Mycoplasma pneumoniae and Streptococcus pneumoniae [14] [15] [16] . Studies that have examined the value of a clinical definition of ILI in the diagnosis of influenza infection have not always used the same clinical definition for an ILI and have included different study populations, making comparison between studies complicated. A systematic review of the literature in this area identified the threefold combination of the presence of fever, cough and acute onset to be the most predictive clinical features. The accuracy of this clinical definition was higher in persons aged 60 years and above compared to patient groups without age restrictions [positive likelihood ratio (95% CI) 5.4 (3.8 7.7) vs 2.0 (1.8 2.1)] 17 . The probability of influenza infection also increases with increasing level of fever 18, 19 . Importantly, the predictive value of clinical definitions based on an ILI increases when influenza virus is known to be circulating in the community 15, 17, 20 . In cohort studies, correlation of ILI with laboratory-confirmed influenza infection ranges from 25% to 45% while in clinical trials, rates of 70% have been consistently reported 15, [21] [22] [23] .. These findings relate to influenza infections during interpandemic periods. During a global influenza pandemic, when a pandemic strain is known to be circulating locally in an immunologically susceptible population, the presence of an ILI would be expected to be highly predictive for influenza infection. (However, the extent to which a clinical diagnosis of ILI becomes predictive during a pandemic will also be determined by the behaviour of the public. If many who would not normally present to a health professional are prompted to present, then the predictive value of a clinical diagnosis of ILI will be reduced.) The following description will relate mainly to interpandemic influenza A infections. Influenza B and C are not considered pandemic threats. Different strains may be associated with different clinical presentations and disease severity. For instance, there is evidence to suggest that the H3N2 subtype causes more severe disease than H1N1 subtype 24 . The spectrum of clinical disease associated with a new influenza A subtype (eg. a pandemic strain) cannot be determined currently and may differ from that described for interpandemic influenza. The incubation period prior to the onset of symptoms is commonly two to four days (range 1 7 days). In adults, the illness typically presents as an abrupt onset of fever accompanied by a range of other symptoms as listed in Box 3.2 [25] [26] [27] [28] [29] . Fever is the paramount symptom and may reach 41ºC although more usually it ranges between 38ºC and 40ºC. The peak occurs within 24 hours of onset and lasts typically for three days (range 1 5 days) [25] [26] [27] [28] [29] . The cough is generally dry although in up to 40% of cases it may be productive. A productive cough together with chest tightness and substernal soreness is more common in patients with underlying chronic lung disease. Myalgia affects mainly the back and limbs. Gastrointestinal symptoms such as vomiting and diarrhoea are uncommon (<10%) in adults. Abdominal pain is rare. Clinical findings include a toxic appearance in the initial stages, hot and moist skin, a flushed face, injected eyes and hyperaemic mucous membranes around the nose and pharynx. Tender cervical lymphadenopathy is found in a minority (~10%) of cases. Wheezing or lung crackles are recognised findings (~10%) more commonly noted in patients with coexisting chronic lung disease. Although the overall clinical picture of uncomplicated influenza in any specific age group is similar for different influenza A subtypes, the frequency of certain symptoms may vary. For instance, during the 'Asian' pandemic of 1957 (H2N2), headache and sore throat were frequent initial symptoms 30 . In uncomplicated infection, the illness usually resolves in seven days although cough, malaise and lassitude may persist for weeks. Influenza virus infection has been associated with worsening in the clinical condition of patients with a range of existing medical conditions, such as, heart failure, diabetes, coronary heart disease, asthma and chronic obstructive airways disease (COPD). In addition, specific complications associated with influenza infection regardless of co-existing medical conditions are recognised (Table 3 .1). Based on data from interpandemic influenza, certain persons are identified as being at high risk from influenza-related complications. Such patients are similar to the group currently recommended for influenza vaccination by the Department of Health. These include those of all ages with chronic respiratory disease including asthma, chronic heart disease, chronic renal disease, chronic liver disease, immunosuppression due to disease or treatment, or diabetes mellitus, and all those aged 65 years or older, or those in long stay residential care (see Appendix 2). In the course of a pandemic, it may emerge that the patient group at high risk of complications differs from the group currently identified. In such circumstance, details of the 'high risk' patient group will be altered according to relevant clinico-epidemiological data. The incidence of pneumonia (defined as a combination of respiratory symptoms and signs supported by chest radiographic changes consistent with infection) complicating influenza infection varies widely, from 2% to 38%, and is dependent on viral and host factors [25] [26] [27] . Pneumonia generally occurs more frequently and with greater severity in patients with pre-existing chronic cardiac and respiratory conditions. Patients who develop pneumonia may present with symptoms and signs indistinguishable from pneumonia related to other viral and bacterial pathogens. In the context of an influenza pandemic, the presence of an ILI and new or worsening dyspnoea should prompt a careful examination for the presence of complicating pneumonia. Two main types of influenza-related pneumonia are recognised: primary viral pneumonia and secondary bacterial pneumonia [25] [26] [27] [28] . Patients with primary viral pneumonia typically become breathless within the first 48 hours of onset of fever. An initially dry cough may become productive of blood-stained sputum. Cyanosis, tachypnoea, bilateral crepitations and wheeze on chest examination and leucocytosis are usual. The commonest chest radiographic abnormality is of bilateral interstitial infiltrates predominantly in the mid-zones, although focal consolidation is also well recognised. Rapid clinical deterioration with respiratory failure may ensue 31 . The mortality in hospitalised patients is high (>40%) despite maximum supportive treatment on intensive care [25] [26] [27] [28] . In the majority of fatal cases, death occurs within seven days of hospital admission. Secondary bacterial pneumonia is more common (up to four times) than primary viral pneumonia. Typically, symptoms and signs of pneumonia develop during the early convalescent period (four to five days from onset of initial symptoms). In others, symptoms of pneumonia blend in with the initial symptoms of influenza. Chest radiography usually demonstrates a lobar pattern of consolidation. Mortality rate ranges from 7% to 24% [25] [26] [27] [28] [29] 32 , although some small studies report higher mortality rates. The spectrum of pathogens implicated is similar to that observed in CAP and includes Streptococcus pneumoniae, Staphylococcus aureus, Haemophilus influenzae and Groups A, C and G b-haemolytic streptococci 27, 28, [33] [34] [35] . Different pathogens have predominated at different times. For instance, in the 1918 pandemic, H. influenzae, b-haemolytic streptococci and S. pneumoniae were the predominant pathogens isolated. In 1968, S. pneumoniae was the predominant pathogen (48%) followed by Staph. aureus (26%) and non-typeable H. influenzae (11%) 34 . Notably, Staph. aureus was identified two and a half times more frequently during the 1968 pandemic compared to pneumonia occurring in the interpandemic period 34, 36 . Secondary staphylococcal pneumonia is associated with a higher incidence of lung abscess formation (14% vs 2%) and carries a poorer prognosis compared to non-staphylococcal pneumonias (mortality 47% vs 16%) 25, 29, 32, 37 . During the 1957 pandemic, Staph. aureus was the predominant bacterial pathogen isolated in fatal cases of influenzarelated pneumonia (up to 69% of cases in some series) 25 . Bacterial and viral pneumonia can occur concurrently. In these instances, the chest radiograph may demonstrate lobar consolidation superimposed on bilateral diffuse lung infiltrates. The mortality rate in mixed viral bacterial pneumonia is high (>40%), as for primary viral pneumonia [25] [26] [27] [28] . Minor abnormalities on ECG such as ST segment deviation, T wave changes and rhythm disturbances have been described in uncomplicated influenza illness. They have been reported in up to 81% of patients hospitalised with influenza 25 . Most do not have cardiac symptoms. Myocarditis and pericarditis are occasionally encountered in severe illness 38, 39 . Post mortem evidence of necrotising myocarditis has been reported in patients without clinically significant myocarditis in the antemortem period. In contrast with myalgia affecting the back and limbs which is common on initial presentation, myositis generally develops after the subsidence of the acute upper respiratory tract symptoms. The gastrocnemius and soleus muscles are typically involved with pain and tenderness to palpation. Complete recovery usually occurs in three days. Elevation in serum creatine phosphokinase is recognised 40, 41 . Rarely, this is associated with myoglobinuria and renal failure 42, 43 . Myositis is more commonly described in children than in adults. Central nervous system (CNS) involvement in adults is uncommon. Most reports originate from Japan and occur in children 44, 45 . The main clinical syndrome is an encephalitis or encephalopathy manifesting in the form of decreased consciousness and seizures about three days (range 0 7 days) following the onset of upper respiratory tract symptoms. Focal neurological signs such as paresis, aphasia, choreoathetosis and cranial nerve palsies are less common. Cerebrospinal fluid (CSF) examination may be normal or reveal an elevation in protein or white cell count. Imaging by CT or MRI may be normal and if so, is indicative of a good prognosis and full recovery may be anticipated 46 . Young age and abnormal CT/MRI findings are associated with a poor outcome including death or recovery with severe neurological sequelae. [A fuller description is given in Section 4.2. 6.] Acute necrotising encephalopathy is a rare fulminant syndrome associated with multifocal brain lesions that is described mainly in Japan 46 . Other rare manifestations include transverse myelitis and Guillain Barré Syndrome 47,48 . Reye's syndrome, characterised by an encephalopathy, acute fatty liver, association with aspirin use and high mortality (~40%), is a special situation that is almost exclusively seen in children and adolescents 46 . Nevertheless, physicians managing adults are advised to be aware of this complication. [A fuller description is given in Section 4.2.6.1.] Other complications rarely encountered in adults with influenza A infection include toxic shock syndrome in conjunction with secondary Staph. aureus infection 49,50 and parotitis 51 . Otitis media is more commonly encountered in children than adults. Human infections have been caused by different avian influenza A viruses in the past, including H9N2, H7N7, H7N3 and H7N2. In recent years, outbreaks of human infections by a novel strain of avian influenza A (H5N1) have raised particular concerns globally regarding the risk of a human pandemic 52 . These concerns have been due in part to recognition that (a) avian influenza A (H5N1) can pass directly from birds to humans and (b) once in humans, avian influenza A (H5N1) causes severe disease with a high mortality. The full spectrum of human illness associated with avian influenza A (H5N1) infection is not completely known. Descriptions of the clinical features of influenza A (H5N1) infection in humans are based largely on case series of hospitalised patients. Subclinical infections, mild illnesses and atypical presentations of influenza A (H5N1) infections in humans have been reported, but the frequency of such infections is difficult to determine [53] [54] [55] . In hospitalised patients, an ILI similar to that associated with seasonal influenza A (H1N1 or H3N2) infection is recognised. Gastrointestinal symptoms are present in a relatively large proportion of both adult and paediatric cases, in contrast to the relatively low incidence of gastrointestinal symptoms in seasonal influenza. The majority of patients develop a severe primary viral pneumonia usually associated with lymphopenia, thrombocytopenia and deranged liver function tests. Renal failure and multiorgan failure may develop subsequently. Mortality is high. A more detailed description is given in Appendix 10. Should influenza A (H5N1) acquire efficient humanto-human transmission capabilities, it may result in an influenza pandemic. In such an event, the clinical features of human H5N1 disease may alter. (1) The commonest presenting features of influenza during an epidemic are fever, cough and rhinorrhoea. In infants, fever with non-specific symptoms or diarrhoea and vomiting is common; in older children pharyngitis and headache are frequent. (2) The clinical features of influenza in children during a pandemic cannot be forecast. (3) Children with underlying respiratory or cardiac disease, immune compromise or who are nonambulant are more likely to be severely affected. (4) The younger the child the more likely hospital admission will be needed. The clinical features of influenza presenting in a pandemic cannot be predicted as they appear to be dependent on the strain of influenza and, in some respects, the host. A new strain of influenza A responsible for an epidemic or pandemic may result in a different spectrum of clinical features than previous strains 56, 57 . Common features during previous epidemics have been described and depend on the age of the child. The studies of clinical features are hospital based and are therefore likely to reflect more severe illness. These are nevertheless informative as one of the main issues in a pandemic is which patients require hospital admission. In young children presenting to primary care in a non-pandemic influenza season there are no specific clinical features that distinguish influenza from other winter viruses 58 . Neonates may present with non-specific signs of sepsis such as pallor, floppiness, (poor peripheral circulation, poor tone), lethargy, poor feeding, episodes of apnoea 59 . Fever may be the only presenting feature. A North American study identified influenza as the most common reason for children aged 0 60 days being admitted to hospital during an epidemic with fever as the only clinical feature 60 . Fever may be the only presenting feature in this age group too. They may also be irritable and toxic and are more likely than older children to present with gastrointestinal symptoms such as diarrhoea and vomiting. Febrile convulsions, particularly repeated convulsions, are positively associated with influenza A 61 . Otitis media is also a common complication in children 62 . Admission rates for under two year olds are 12 times higher than for children aged 5 17 years 63 . The presentation does not differ significantly from adults. Common features are sudden onset of high fever, chills (76 100%), cough, headache, sore throat, fatigue (51 75%), nasal stuffiness and conjunctivitis (26 50%) . Fever tends to settle two to four days later though a dry cough and clear nasal discharge last for one to two weeks 59 . A clinical prediction model from North America for influenza in children has shown that the triad of cough, headache and pharyngitis had a sensitivity of 80% and a specificity of 78% for a positive viral culture for influenza 64 . The subjects, mean age six years, presented during an epidemic to a suburban emergency department with a febrile respiratory illness and one or more symptoms of influenza. A Finnish retrospective study of children referred to hospital from 1980 to 1999 with influenza confirmed by antigen testing reported that the median age for those with influenza A was two years. The most common features were cough, fever and rhinorrhoea 62 . These were also the commonest features reported in a Chinese study where the mean age of the subjects with influenza A was four years 65 . conditions These children 66 (Table 4 .1) and those who are not ambulant 67 experience substantial morbidity during influenza seasons, with a disproportionate number requiring inpatient care and ventilatory support. Of the 22% of (Table 4 .2) As in adults, influenza can present with either primary viral pneumonia or bacterial pneumonia most commonly caused by S. pneumoniae or Staph. aureus. There is much less published about pneumonia complicating influenza in children. An outbreak of severe pneumococcal pneumonia in children occurred in Iowa in the winter of 1995 96. This was coincident with an epidemic of influenza (H1N1). Compared with controls, patients were 12 times more likely to have Rare experienced a recent influenza-like illness. They were also more likely to have family members with the illness and to have positive serology in the convalescent period. Many of these patients required chest drainage 69 . Another study in 2002 of 202 children with proven influenza reported that 78 who had chest radiographs had either radiographic evidence of viral pneumonia or normal radiographs. No child had lobar pneumonia reported 70 . Evidence from recent outbreaks of avian influenza (H5N1) in Hong Kong and Vietnam suggests that while some children had mild disease 71 , others appeared to have multi-organ disease including acute respiratory distress syndrome (ARDS) 57 . All children who developed progressive pneumonia with ARDS died. There were no reports of bacterial pneumonia. There is no reason to believe that, apart from ARDS, pneumonia complicating influenza presents differently from community-acquired pneumonia in children 72 . The general clinical indicators for severity assessment of lower respiratory tract infection are summarised in the BTS guidelines 72 (Appendix 8). Failure to improve following 48 hours of antibiotics, or deterioration including a new, distinct spike of fever, should also be treated as severe and further complicating factors sought. The clinical course of croup caused by influenza appears to be more severe than croup caused by the more common parainfluenza virus 73 . It is more likely to be complicated by bacterial tracheitis 62 . Influenza is a well recognised cause of otitis media 74 . It is the commonest bacterial superinfection of influenza and is reported in approximately 25% of patients aged <5 years 75 . Influenza ranks second only to respiratory syncytial virus as a cause of bronchiolitis 76 . The clinical features are the same 77 . Children with influenza may present with febrile convulsions. In a community study in the Netherlands, recurrent febrile seizures were positively related to influenza A. It was recommended that children who have had a previous febrile convulsion should be immunised against influenza A 61 . These complications are described in small case series. This is defined as depressed or altered level of consciousness including lethargy and/or extreme irritability in younger children or significant change in personality or behaviour persisting beyond 24 hrs or confusion (older children). Encephalopathy usually presents as seizures within several days of the onset of fever 78 . Seizures at this point are usually the first symptom of involvement of the central nervous system. Febrile convulsions, which are more likely to be repeated with influenza than with other causes of fever, generally occur with the onset of fever. Disturbances of behaviour and neurological deficit have been reported. A rapid and severe clinical course is usual with encephalopathy and is thought to be due to brain oedema mediated by cytokines rather than by direct invasion of the brain. Steroids are therefore considered. 202 children with encephalopathy were recognised in Japan between 1997 and 2001. Death occurred in 31%, residual neurological deficit in 26% and full recovery in 43% 79 . This is a rare childhood acute encephalopathy associated with liver dysfunction. The cause is unknown but it typically follows viral illness and there is a clear association with aspirin therapy: thus an innate susceptibility coupled with aspirin taken for relief of viral symptoms. Influenza (particularly influenza B) is commonly implicated 80 . There was a dramatic fall in incidence following warnings about aspirin use in children 81 . It is possible that children on long term aspirin treatment for medical conditions may be at increased risk if they develop influenza infection. Reye's syndrome is characterised by protracted vomiting and encephalopathy in afebrile patients with minimal or absent jaundice, and hepatomegaly in 50% of patients. It comprises: • Acute non-inflammatory encephalopathy with an altered level of consciousness • Elevation of ammonia levels 24 48 hours after the onset of mental status changes (the most frequent laboratory abnormality) • Hepatic dysfunction with a liver biopsy showing fatty metamorphosis or a more than three-fold increase in alanine aminotransferase (ALT), aspartate aminotransferase (AST) Neurological symptoms usually occur 24 48 hours after the onset of vomiting. Lethargy is usually the first neurological manifestation. Diarrhoea and hyperventilation may be the first signs in children younger than two years. Other investigations: Head CT scanning may reveal cerebral oedema but results are usually normal. An electroencephalogram (EEG) may reveal slow wave activity in the early stages and flattened waves in advanced stages. Cerebrospinal fluid may or may not have increased opening pressure with white blood cells (WBCs) fewer than 9/ml 3 (usually lymphocytes). There is no specific treatment for Reye's Syndrome. Key aspects of management are correction of metabolic imbalance and reduction of intracranial pressure. Advice should be requested from a specialist in metabolic medicine. Many children have an underlying inborn error of metabolism. Mortality has fallen from 50% to less than 20% as a result of earlier diagnosis and more aggressive therapy. Acute necrotising encephalopathy (ANE): This occurs mainly in Japan where it was first described in 1995. An estimated 100 deaths per annum are related to central nervous system complications of influenza in Japan 82 . This suggests either a genetic predisposition for this complication or a variation in the strains of influenza circulating in Japan. ANE is characterised by high fever, convulsions and coma in children aged one to five years. The onset is two to four days after the respiratory symptoms, and fewer than 10% of patients survive 83 . There are no specific markers although some patients have raised liver transaminases. In many, the CSF is normal. Symmetrical multi-focal brain lesions are seen and bilateral thalamic involvement is characteristic and may be demonstrated on MRI 83 . This is defined as encephalopathy plus two of the following: fever of 38ºC or higher, seizures, focal neurological findings, WBC >5 cells/ml in CSF, EEG findings consistent with encephalitis, abnormal neuro-imaging 84 . These must be considered when a child presents with altered level of consciousness or irritability. There is good evidence of an increased risk of meningococcal disease following influenza infection 85 . During a pandemic, the focus will be on diagnosing influenza-related illness. Other neurological conditions or drug toxicity, for example, may be missed. A literature review of 316 cases of myositis 86 suggested that this was a complication mainly of schoolchildren. The calf muscles are predominantly affected. Rhabdomyolysis and renal failure are rare. These are also rare complications but have been described in children with underlying medical conditions 62 . Section 5. General management and investigations in primary care With widespread concern during a pandemic, a significantly increased demand for advice and consultation should be anticipated. There are likely to be significantly higher consultation rates for all types of respiratory tract infections including those which are normally managed well at home using over-the-counter remedies (e.g. febrile colds, sore throat with temperatures). Consequently, demand management in both the practice and the PCT will be crucial to avoid the service's capacity to triage care being overwhelmed. Guidance on demand management and health service delivery is given in the Primary Care Operational Plan (see Section 1.4) 87 . Management decisions of patients with influenza should be based primarily on: • an assessment of illness severity • identification of whether the individual is in an 'at risk' group • current advice from DOH/local public health officials based on the epidemiology of the pandemic Patients who are not considered to be at high risk and who have no features suggesting severe disease or complications may not need to be seen in face to face consultations by a primary care clinician. All patients presenting in general practice with symptoms suggestive of influenza (except perhaps those in whom urgent admission is required) should be given general advice and advice on symptomatic treatment. It is important that clinicians identify and address individual concerns and expectations, provide information about the illness, and provide information about what patients can do to help themselves and when they should seek further help. Some useful facts that can be provided to the patient are included in Box 5.1. There is little scientific evidence for most symptomatic and self-help treatment, but experience suggests that some of the following may help, and are unlikely to cause harm: • Treat fever, myalgias and headache with paracetamol or ibuprofen • Rest • Drink plenty of fluids • Avoid smoking • Consider: short course of topical decongestants, throat lozenges, saline nose drops Many infants and children will have coughs and mild fevers which may be due to other infections such as respiratory syncytial virus, especially over the winter months. These children should be managed in the usual way at home by parents with antipyretics and fluids. (Note: aspirin should not be used in children.) Management of these children is determined by disease severity (see Appendix 5). The principles of symptomatic management are similar to those for adults. Box 5.1. Information about influenza to provide to patients • Influenza is caused by a number different types of 'influenza' viruses. • The incubation period is typically one to four days and infected adults are usually contagious from the day of illness onset to five days after. Children are typically contagious for seven days, although sometimes for longer. • Fever usually declines after two to three days and normally disappears by the sixth day. • Cough, weakness and fatigue can persist for one to two weeks and up to six weeks. • Antibiotics do not benefit most people with influenza but are sometimes needed to treat secondary infections. (Important note: This information may be modified once a pandemic occurs) • Fever for four to five days and not starting to get better (or getting worse) • Started to feel better then developing high fever and feeling unwell again • If taking antiviral drugs (eg. oseltamivir), symptoms should start to improve within two days. Lack of any improvement after two days from starting antiviral drugs is an indication to re-consult. (Important note: This information may be modified once a pandemic occurs) • Children under one year of age year and those at high risk of complications (see Appendix 2) should be seen and assessed by a GP or at the A&E department. • Children over one but under seven years of age may be seen by a nurse or a GP and those aged seven years and above may be seen by a member of the community health team (e.g. community pharmacist). • All children (and parents) should be given advice on antipyretics and fluids. • Aspirin is contraindicated in children (aged under 16 years). Examples of what should prompt a patient to re-consult are given in Box 5.2. Patients who are started on antiviral agents (see Section 7 for indications for antiviral use) would be expected to begin to improve within 48 hours of starting treatment. Failure to improve two days after starting an antiviral agent is an indication to re-consult. At the time of re-consultation, an alternative diagnosis should be considered as well as the occurrence of any influenzarelated complications. • Any rapid deterioration following first consultation should prompt a patient to re-consult. • Failure to improve two days after starting an antiviral agent is an indication to re-consult. • If the first consultation did not involve contact with a physician, re-consultation should preferably involve a physician, usually a GP. 5.5. What general investigations should be done in the community? • General investigations, including a chest X-ray, are not necessary for the majority of patients managed in the community. The aim of microbiological investigations early in a pandemic (UK alert levels 1, 2 and 3) will be to confirm that influenza A is circulating in the local community. Once a pandemic is established (UK alert level 4), microbiological investigations are not recommended routinely or likely to be available readily. Routine testing for bacterial pathogens is not recommended at any stage. • Where possible, early in a pandemic (UK alert levels 1, 2 and 3), nose and throat swabs, or nasopharyngeal swabs (in children), in virus transport medium should be submitted to the local laboratory. • Once a pandemic is established (UK alert level 4), microbiological investigations are not recommended. Section 6. Criteria for hospital referral 6 .1. Which adults require hospital referral? Adults with uncomplicated influenza infection usually do not require hospital referral. Patients who might require hospital admission fall into two main groups: those with worsening of a pre-existing medical condition and those with an influenza-related complication. Patients who experience a worsening or clinical deterioration of pre-existing medical problems due to influenza infection should be managed according to recommended best practice for the medical condition in question. For instance, a patient with an acute exacerbation of COPD triggered by influenza infection should be managed according to current NICE Guidelines for COPD 88 . Those with a worsening of a pre-existing condition are likely to be in a group at 'high risk' of influenzarelated respiratory complications and consequently at risk §6. Criteria for hospital referral Part 1. Clinical management in primary care Pandemic flu. Clinical management of patients with an influenza-like illness during an influenza pandemic S21 . This group should be promptly reassessed if the illness is getting worse to consider hospital referral. Pneumonia is the commonest influenza-related complication requiring hospital admission. Patients complaining of new or worsening dyspnoea should be carefully assessed for signs of pneumonia. If pneumonia is diagnosed, disease severity assessment is recommended and hospital referral made accordingly. There is no validated severity assessment tool developed specifically for influenza-related pneumonia. The CRB-65 score (Table 6 .1) is a well validated severity assessment tool developed for patients with community-acquired pneumonia (CAP) 89, 90 and recommended in the British Thoracic Society CAP Guidelines 2004 for use in the community setting 72 . It is offered as an example of an assessment tool for influenza-related pneumonia. The use of any severity assessment tool does not replace clinical judgement. A patient's social circumstances should also always be taken into account. In view of the rapid and fulminant course of primary viral pneumonia, patients with pneumonia who have bilateral chest signs (crackles) should be considered for hospital referral. Other influenza-related complications are uncommon. There are no specific recommendations relating to criteria for hospital admission or disease severity assessment in these cases. • Patients with clinically defined uncomplicated influenza infection would be expected to make a full recovery. They require good symptomatic management, access to antiviral treatment, information about the natural history, and advice as to when to re-consult. • Patients with new or worsening symptoms particularly shortness or breath or recrudescent fever not responding to treatment should be examined to assess the presence and severity of influenza-related pneumonia. • Patients with worsening of pre-existing co-morbid medical conditions should be managed according to best practice for that condition with reference to published disease-specific guidelines, if available. • In patients with influenza-related pneumonia clinically, hospital referral and assessment should be considered for patients with a CRB-65 score of 1 or 2 (particularly score 2) and urgent admission for those with CRB-65 score of 3 or more. • Patients with bilateral chest signs of pneumonia should be referred to hospital for further assessment regardless of CRB-65 score. • The CRB-65 score does not replace clinical judgment. • The antiviral treatment of choice is oseltamivir (Tamiflu TM ). This is given as a five-day course of oral tablets; 75 mg twice daily for adults. Liquid suspension is available for children from the age of one year upwards. (See Table 7 .1.) From clinical trial data accrued to date and based on seasonal, interpandemic influenza, the anticipated positive effect of antivirals in a pandemic will be: (a) a reduction of illness duration by 24 hours, and therefore more rapid mobilisation of affected individuals including essential workers (b) a possible reduction in hospitalisation of infected individuals (c) a reduction of subsequent antibiotic use by infected individuals The evidence accrued to date does not suggest there will be a reduction of overall mortality, nor does it rule it out. 7.4. Who should receive antiviral drugs? • Ideally, antiviral treatment should be offered to every patient who is over one year of age who (a) has an acute influenza-like illness (b) has fever ( 38ºC in adults, or 38.5ºC in children) and (c) presents within 48 hours of the onset of symptoms. • Exceptions: (i) Patients who are unable to mount an adequate febrile response, e.g. the immunocompromised or very elderly, may still be eligible for antiviral treatment despite the lack of documented fever. (ii) Immunosuppressed patients, including those on long-term corticosteroid therapy, may suffer more prolonged viraemia, and could possibly benefit from antiviral therapy commenced later than 48 hours after the onset of ILI. (iii) Patients who are severely ill, but who have not been hospitalised due to non-clinical reasons, may benefit from antiviral therapy commenced later than 48 hours after the onset of ILI. There is no strong evidence to support antiviral use in these exceptional situations. The commonest adverse effect of oseltamivir is nausea in about 10% of patients. This can be managed with mild anti-emetic medication. Other side-effects are listed in Appendix 9. National distribution arrangements are laid out in the UK Operational Framework for stockpiling, distributing and using antiviral drugs in the event of pandemic influenza 5 and the Primary Care Operational Plan. The drug will be made available through these arrangements to pharmacies, PCTs and/or GP surgeries. • PCTs are encouraged to plan for the delivery of antivirals to the large numbers of previously healthy persons with an ILI via community health professionals, including community pharmacists. • GPs should focus their efforts on assessment and management of those persons at high risk of complications (see Appendix 2) and patients developing complications. Section 8. Antibiotic use in primary care The use of antibiotics in adults with influenza not complicated by pneumonia is determined by (a) the presence of any co-morbid illnesses and (b) the timing of first consultation with respect to the onset of symptoms. Features of an acute bronchitis, with cough, retrosternal discomfort, wheeze and sputum production are an integral part of the influenzal illness. In previously well individuals who do not have pneumonia or new focal chest signs, antibiotics are not indicated. If the patient is seen later in the course of the illness and the illness is worsening, for instance with recrudescent fever or increasing breathlessness, a worsening bacterial bronchitis §8. Antibiotic use in primary care Part 1. Clinical management in primary care Pandemic flu. Clinical management of patients with an influenza-like illness during an influenza pandemic S23 or developing pneumonia is possible and the use of antibiotics should be considered. In selected patients, a delayed antibiotic prescription may be offered at first consultation. The antibiotic prescription should come with clear instructions that the antibiotics should be used if the illness is not starting to settle after two days or if there is worsening of symptoms. The potential advantage of this approach of delayed antibiotic prescription is to minimise rates of reconsultation 91 . There are no robust data regarding the effect of such an approach on the incidence of influenzarelated complications. Those at high risk of influenza-related complications because of (a) chronic obstructive pulmonary disease (COPD) and/or (b) other severe co-morbid diseases should be strongly considered for antibiotics at first consultation. If, having started antibiotics, patients do not begin to improve over the next 48 hours of antibiotic treatment (or if they get worse) they should be advised to re-contact their GP for assessment of pneumonia and its severity (see Sections 3 and 6). Antibiotics should cover the likely bacterial pathogens including S. pneumoniae, H. influenzae, M. catarrhalis and Staph. aureus. The preferred first choice of antibiotic for nonpneumonic bronchial infections, including those patients with COPD, should include an effective oral b-lactamase stable agent such as a tetracycline (e.g. doxycycline) or co-amoxiclav. A macrolide (e.g. erythromycin or clarithromycin) is an alternative for those intolerant of the preferred first choices, whilst remembering the possibility of antimicrobial resistance. Clarithromycin has better activity against H. influenzae than azithromycin. Further details regarding the principles of antibiotic use including antibiotic resistance patterns are given in Section 14. • Patients without severe pre-existing illnesses and who have uncomplicated influenza, or simple bronchitis, do not routinely require antibiotics. • Patients without severe pre-existing illnesses who are seen later in the course of illness and who have developed significant worsening of symptoms (particularly recrudescent fever or increasing breathlessness) should be considered for antibiotics. • Patients with COPD and/or other severe pre-existing illnesses, and who are therefore at high risk of influenzarelated complications, should be strongly considered for antibiotics at first consultation. • Most patients can be adequately treated with a week's course of oral antibiotics. • The preferred choice of antibiotic needs also to cover infection with Staph. aureus for example either doxycycline or co-amoxiclav (see Table 8 .2). • A macrolide (e.g. erythromycin or clarithromycin) is an alternative choice in certain circumstances. The principles of antibiotic selection for patients with influenza-related pneumonia who can be managed in the community are similar to those for the management of sporadic community-acquired pneumonia in general except that adequate cover for Staph. aureus, in addition to cover for S. pneumoniae, should be included in any empirical regimen. For this reason a tetracycline, such as doxycycline or oral co-amoxiclav, is the preferred regimen (Table 8 .2). A macrolide (e.g. erythromycin or clarithromycin) is an alternative for those intolerant of the preferred first choices. Macrolide (erythromycin 500 mg qds PO or clarithromycin 500 mg bd b PO) a An alternative regimen is provided for those intolerant of or hypersensitive to the preferred regimen. b Clarithromycin may be substituted for those with gastrointestinal intolerance to oral erythromycin and also has the benefit of twice daily dosage and better cover against H. influenzae. Abbreviations: od, once daily; bd, twice; tds, 3 times; qds, 4 times. Secondary bacterial infections particularly pneumonia and otitis media are common in children with influenza. S. pneumoniae, Staph. aureus and H. influenzae are the most common pathogens encountered during influenza outbreaks. • Children in any one of the following groups should be treated with an antibiotic that will provide cover against S. pneumoniae, Staph. aureus and H. influenzae: (1) Those at risk of complications of influenza (see Appendix 2). (2) Those with one or more of the following adverse features: (a) breathing difficulties (b) severe earache (c) vomiting for more than 24 hours (d) drowsiness. Part 2. Clinical management of adults referred to hospital Section 9. Severity assessment of adults referred to hospital 9.1. What severity assessment strategy is recommended for patients referred to hospital with influenzarelated pneumonia? There is no validated severity assessment tool developed specifically for influenza-related pneumonia. The CURB-65 severity assessment tool as described in the BTS CAP Guidelines 2004 is recommended for the stratification of hospitalised patients with influenza-related pneumonia into disease severity groups 72 (Table 9 .1). In addition, the presence of diffuse bilateral lung infiltrates on chest radiography consistent with primary viral pneumonia is an adverse prognostic feature. Such patients should be treated as for severe pneumonia. In all instances, clinical judgement is essential when assessing disease severity. • Patients with bilateral lung infiltrates on chest radiography consistent with primary viral pneumonia should be managed as having severe pneumonia regardless of CURB-65 score. • In hospital, patients with influenza-related pneumonia who have a CURB-65 score of 3 or more are at high risk of death and should be managed as having severe pneumonia. • Patients who have a CURB-65 score of 2 are at increased risk of death. They should be considered for short stay inpatient treatment or hospital-supervised outpatient treatment. This decision is a matter of clinical judgement. • Patients who have a CURB-65 score of 0 or 1 are at low risk of death. They can be treated as having non-severe pneumonia and may be suitable for home treatment. 9.2. When should transfer to a high dependency unit (HDU) or intensive care unit (ICU) be considered? The indications for transfer to HDU or ICU are no different in patients with influenza infection compared to other patients. Most patients who might require HDU/ICU care will have influenza-related pneumonia or a severe exacerbation of underlying comorbid illness, e.g. exacerbation of COPD. In a pandemic situation when HDU/ICU beds may not be readily available, prioritisation of patients on an individual basis matched against available resources will be expected. • Patients with primary viral pneumonia or a CURB-65 score of 4 or 5 should be considered for HDU/ICU transfer. • General indications for HDU/ICU transfer include: (1) persisting hypoxia with PaO 2 < 8 kPa despite maximal oxygen administration (2) progressive hypercapnia (3) severe acidosis (pH < 7.26) (4) septic shock • Patients with influenza admitted to an intensive care unit should be managed by specialists with appropriate training in intensive care, respiratory medicine and/or infectious diseases. In acute uncomplicated influenza the chest X-ray is usually normal. When primary viral pneumonia occurs as a complication, particularly in elderly adults the chest X-ray often shows multiple infiltrates or consolidation. Cavitations or pleural changes suggest bacterial superinfection. In combined viral-bacterial pneumonia, the clinical features typically appear later than primary viral pneumonia and the chest X-ray often shows cavitation or pleural effusions. Secondary bacterial pneumonia usually occurs after apparent improvement from the viral infection; the chest X-ray may show consolidation. • A chest X-ray should be obtained during assessment of a suspected case of influenza seen in the hospital setting (accident and emergency department or acute admissions ward). • In those patients who are subsequently followed up in a hospital outpatient clinic or by a general practitioner a repeat chest X-ray should be obtained at around six weeks if respiratory symptoms or signs persist or where there is a higher risk of underlying malignancy (especially smokers and those over 50 years of age). • Further investigations including a CT thoracic scan, and bronchoscopy should be considered if the chest X-ray remains abnormal at follow up 72 . In those patients with illness severe enough to present to secondary care the following tests may be useful: Full blood count: a leucocytosis with left shift may occur in those with primary viral pneumonia, mixed viralbacterial pneumonia or secondary bacterial pneumonia. (Lymphopenia has been noted in human cases of severe avian H5N1 influenza.) Urea and electrolytes may reveal evidence of hypo or hypernatraemia or renal impairment. Liver function tests are usually normal. Creatine kinase (CK) may be elevated in those with severe myalgia. C-reactive protein (CRP) is unlikely to be helpful except where superimposed bacterial infection is suspected 72 . However, the diagnostic value of CRP in lower respiratory tract infections remains controversial 92 . • The following blood tests should be obtained in patients admitted to hospital: (1) full blood count; (2) urea, creatinine and electrolytes; (3) liver function tests; (4) creatine kinase (if myositis is suspected). • In patients with suspected secondary bacterial infection, the C-reactive protein (CRP) level may aid diagnosis. In acute uncomplicated influenza larger airway function remains normal. However, there is often an increase in bronchial reactivity which may persist for many weeks after resolution of the infection 93 . Lung function tests are unnecessary in most patients. Section 11. Microbiological investigations for adults in hospital 11 .1. Introduction The guidelines provided below are based on the assumption that when cases are first occurring in the UK as part of a global pandemic, it will be possible to perform full microbiological investigations in all new cases of influenzalike illness and influenza-related pneumonia. As case numbers rise, possibly to pandemic levels, full or indeed any microbiological investigation will become increasingly difficult. Thus, data on the relative frequency of different bacterial causes of influenza-related pneumonia and their antimicrobial susceptibilities amongst investigated cases gathered earlier in the pandemic should be available to guide and refine empirical antimicrobial therapy choices for cases occurring later in the pandemic. The most likely pathogens implicated in influenzarelated pneumonia are Streptococcus pneumoniae, Staphylococcus aureus, Haemophilus influenzae and to a lesser extent b-haemolytic streptococci (see Section 3.3). In the early phases (UK alert levels 1, 2 and 3 see Appendix 1) of a pandemic, microbiological diagnostic approaches should focus on confirming influenza as the primary illness, defining bacterial causes of influenza-related pneumonia, and optimizing both specific (for individual patients) and general (for populations) antimicrobial treatment recommendations. In later pandemic phases (UK alert level 4) with the much higher caseloads anticipated, microbiological investigation should be focused on patients with severe influenza-related pneumonia unresponsive to empirical antimicrobial therapy. Actual and practical local level transition to less intense microbiological investigation may occur at UK alert level 3 in some regions as the number of local cases is likely to vary between regions. §11. Microbiological investigations for adults in hospital Part 2. Clinical management of adults referred to hospital Pandemic flu. Clinical management of patients with an influenza-like illness during an influenza pandemic S27 It will be necessary to perform full microbiological investigations on all hospitalised cases, including patients with severe and non-severe influenza-related pneumonia, in order to: confirm influenza as the primary infection, optimize treatment options for the patients investigated and define the most common bacterial causes of influenzarelated pneumonia and their antimicrobial susceptibility patterns. The latter data will help to inform empirical antimicrobial therapy of subsequent cases for which microbiological investigation may not be undertaken fully, or at all. In influenza, rapid virological tests, viral culture and PCR of respiratory samples will yield positive results between one and seven days after illness onset. However, if presentation is more than seven days after the onset of influenzalike illness then such sampling and testing is unhelpful. Instead, serum samples for serological testing for evidence of recent influenza infection are recommended. Specific detailed microbiological guidance for taking and handling specimens from individuals at risk of avian influenza prepared by Prof Maria Zambon of Health Protection Agency (HPA) Centre for Infections is available at: www.hpa.org.uk/infections/topics_az/avianinfluenza/ guidance/microbiological_guidance.htm Bacteriological investigations are only recommended in patients with influenza-related pneumonia. Legionella pneumophila infection is not normally associated with influenza-related pneumonia. Despite this, Legionella urine antigen tests should be performed on severe CAP cases in the early stages of an outbreak/incident in order to confirm Legionella infection is not the reason for a local increase in pneumonia admissions. These recommendations are modified from those contained in the British Thoracic Society Community Acquired Pneumonia (BTS CAP) Guidelines 2001 [Thorax 2001;56(Suppl iv), see Sections 5.7, 5.8 and 5.9 (pp. iv23 iv28)] and the 2004 Update (see pages 4 5), both available at: www.brit-thoracic.org.uk/ iqs/bts_#guidelines_pneumonia_html. Sputum investigative efforts must be focused on quality samples (i.e. those from patients who are able to expectorate purulent samples, and have not received prior antibiotic treatment) and not dissipated on large numbers of poor quality samples. It is important to acknowledge that the criteria for quality samples may only be met for a minority of admissions. Laboratories should offer a reliable Sputum Gram stain for appropriate samples, as on occasions this can give immediate indication of likely pathogens. The most likely influenzarelated pneumonia pathogens are S. pneumoniae, Staph. aureus and H. influenzae, all of which may present a characteristic appearance on Gram stain of purulent sputum. Laboratories performing sputum Gram stains should adhere to strict and locally agreed criteria for interpretation and reporting of results. A. Virology all patients: • Nose and throat swabs in virus transport medium should be collected from all patients and submitted to the local laboratory. The relevant laboratory should be notified of the suspected diagnosis and there should be close liaison over sample collection, handling and transport. • Rapid testing by direct immunofluorescence or rapid EIA test, virus culture and/or PCR should be undertaken according to local availability and/or referred to an appropriate laboratory • During UK alert level 1, when the UK is on high alert for the first cases of pandemic influenza, suspected cases are likely to be investigated by local Health Protection Teams from the Health Protection Agency and its partner organisations in the devolved administrations. • During UK alert levels 1 and 2, clinicians dealing with suspected cases of pandemic influenza should ensure that the local Health Protection Team is informed and involved from the outset. • The Health Protection Agency and its partner organisations in the devolved administrations have established a network of more than 20 laboratories across the UK which have been proficiency tested in molecular diagnosis of influenza A/H5N1. Access to this service should be via local Health Protection Teams. • If presentation is more than seven days after onset of illness, an 'acute' serum (5 10 ml clotted blood) should be collected and a 'convalescent' sample (5 10 ml clotted blood) obtained after an interval of not less than seven days. The two sera should be examined serologically for evidence of recent influenza infection. B. Bacteriology patients with influenza-related pneumonia: • The following bacteriological tests should be performed: (1) Blood culture (preferably before antibiotic treatment is commenced) (2) Pneumococcal urine antigen (20 ml urine sample). agents. Acute serum should be collected and a 'convalescent' sample obtained after an interval not less than seven days (both 5 10 ml clotted blood) and the two sera stored for subsequent testing. Once a pandemic is established, virological investigations are not recommended routinely and in a pandemic situation may not be readily available. The diagnosis of influenza will be based on clinical findings. If influenza-related pneumonia is present, the degree of microbiological investigation will be directed by disease severity and the presence of co-morbidities. In influenza-related pneumonia, examination of sputum should be considered for patients who do not respond to empirical antibiotic therapy. This will be particularly relevant if Staph. aureus is identified as a common influenza-related pneumonia pathogen during the early phase of the pandemic as, in contrast to S. pneumoniae and H. influenzae, antimicrobial susceptibilities of this organism are less predictable and empirical choices more speculative. A. Virology not routinely recommended. B. Bacteriology patients with influenza-related pneumonia: (I) Non-severe pneumonia (CURB-65 Score 0, 1 or 2) • Sputum samples should be sent for Gram stain culture and antimicrobial susceptibility tests in patients who do not respond to empirical antibiotic therapy. (II) Severe pneumonia (CURB-65 Score 3, 4 or 5) • Specific investigations should include: (1) Blood culture, preferably before antibiotic treatment is commenced. (2) Pneumococcal urine antigen (20 ml urine). (3) Sputum Gram stain, culture and antimicrobial susceptibility tests on samples obtained from patients who: (i) are able to expectorate purulent samples, and (ii) have not received prior antibiotic treatment. Sputum specimens should be transported rapidly to the laboratory. (4) Paired serological examination for influenza/ other agents. 'Acute' serum should be collected and a 'convalescent' sample obtained after an interval not less than seven days (both 5 10 ml clotted blood) and the two sera stored for subsequent testing. (5) Tracheal or endotracheal aspirate samples, if available, should be sent for Gram stain, culture and antimicrobial susceptibility testing. Section 12. General management of adults admitted to hospital 12 Initial management will depend on the assessment of the reason for admission, the presence of complications, and the impact of the influenza on any pre-existing disease, or psychosocial factors. For instance, some elderly patients may require admission for social reasons. In broad terms, the most likely clinical reasons for admission will be (in order of frequency): • Lower respiratory tract complications: Non pneumonic bacterial exacerbation of chronic lung disease such as COPD (possibly with a mixed viral infection) Secondary bacterial pneumonia Mixed bacterial and viral pneumonia Primary viral pneumonia • Cardiac complications: Exacerbation of pre-existing cardiac disease with cardiac failure and/or arrhythmia Primary myocarditis • Other complications: Exacerbation of other pre-existing disease, such as diabetes mellitus Neurological complications Rhabdomyolysis Severe sinusitis The initial management is likely to most usually involve that of respiratory and cardiac complications, especially pneumonia and these are discussed below. Management of other less common primary influenzal complications (such as rhabdomyolysis, encephalopathy) is not covered. All influenza patients admitted to hospital with abnormal cardiorespiratory symptoms and signs, including influenzarelated pneumonia, should have a chest radiograph and an electrocardiogram and should have oxygenation assessed by pulse oximetry, preferably whilst breathing air (see Section 10). Those with SaO 2 < 92% should have arterial blood gas measurements, as should all patients with features of severe illness. Knowledge of the inspired oxygen concentration is essential to the interpretation of blood gas measurements and should be clearly recorded with the blood gas result. Continuous oxygen therapy is indicated for those patients with PaO 2 < 8 kPa, hypotension with systolic BP <100 mmHg, metabolic acidosis with bicarbonate <18 mmol/l or respiratory distress with respiratory rate >30/min 94 . The aim of oxygen therapy should be to maintain PaO 2 at >8 kPa or SaO 2 > 92%. Unless complicated by severe chronic obstructive pulmonary disease with ventilatory failure, high concentrations of oxygen of 35% or greater are indicated and can be safely used. High concentration oxygen therapy given to patients with pre-existing chronic obstructive pulmonary disease §12. General management of adults admitted to hospital Part 2. Clinical management of adults referred to hospital Pandemic flu. Clinical management of patients with an influenza-like illness during an influenza pandemic S29 who may have CO 2 retention can reduce hypoxic drive and increase ventilation-perfusion mismatching. In such patients initial treatment with low oxygen concentrations (24 28%) should be progressively increased on the basis of repeated arterial blood gas measurements, the aim being to keep SaO 2 > 90% without causing a fall in arterial pH below 7.35, in line with the management strategy recommended in the NICE COPD Guidelines 95 . Non-invasive ventilation (NIV) may be of value in patients with COPD who are in acute hypercapnic respiratory failure 72,96 . The use of NIV in patients with respiratory failure due to severe pneumonia but without co-existing COPD has not been shown to influence mortality 72,96 . Nevertheless, during an influenza pandemic when Critical Care Level 3 beds 97 are in high demand, NIV may be of value as a bridge to invasive ventilation in specific circumstances. In all instances, the risks of infection due to the dissemination of respiratory droplets related to the use of NIV must be taken into account when deciding on management strategies. Respiratory and/or critical care units experienced in the use of NIV are best placed to ensure the appropriate infection control measures are adopted and observed at all times, including the use of Personal Protection Equipment (PPE) (see UK Infection Control Guidance for Pandemic Influenza) 3 . All patients should be assessed for volume depletion and may require IV fluids. The potential for influenza to cause cardiac decompensation, either through exacerbation of pre-existing cardiac disease or from a primary myocarditis, should be borne in mind, with any complicating heart failure and arrhythmias being managed in the usual way. Physiotherapy may be of benefit in selected patients with excess bronchial secretions, particularly those with concurrent chronic obstructive pulmonary disease. In cases of severe illness requiring prolonged hospital admission, increased nutritional support whether enteral, parenteral or via naso-gastric feeding should be arranged. • Hypoxic patients should receive appropriate oxygen therapy with monitoring of oxygen saturations and inspired oxygen concentration with the aim to maintain PaO 2 > 8 kPa and SaO 2 > 92%. High concentrations of oxygen can safely be given in uncomplicated pneumonia. • Oxygen therapy in patients with pre-existing COPD complicated by ventilatory failure should be guided by repeated arterial blood gas measurements. Non-invasive ventilation may be helpful. • In patients without pre-existing COPD who develop respiratory failure, NIV may be of value as a bridge to invasive ventilation in specific circumstances when Critical Care Level 3 beds are in high demand. Respiratory and/or critical care units experienced in the use of NIV are best placed to ensure the appropriate infection control measures are adopted at all times. • Patients should be assessed for cardiac complications and also volume depletion and their need for additional intravenous fluids. • Nutritional support should be given in severe or prolonged illness. 12.3. What monitoring should be conducted during a hospital stay? Pulse, blood pressure, respiratory rate, temperature, oxygen saturation (with a recording of the inspired oxygen concentration at the same time) and mental status should be measured initially at least twice daily. This is most conveniently performed using an Early Warning Score (EWS) chart, which all ward staff should be familiar with. Those with severe illness, requiring continuous oxygen or cardiovascular support, should be monitored more frequently. Failure to improve clinically within 48 hours should result in a full clinical reassessment and failure to improve over 4 days is an indication to repeat the chest radiograph. • Temperature, respiratory rate, pulse, blood pressure, mental status, oxygen saturation and inspired oxygen concentration should be monitored and recorded initially at least twice daily and more frequently in those with severe illness or requiring regular oxygen therapy. • An Early Warning Score system is a convenient way to perform this. • In addition to a full clinical reassessment, a chest radiograph should be repeated in patients who are not progressing satisfactorily. There will be considerable pressure to discharge patients early during a pandemic. The type and availability of out-of-hospital facilities will dictate hospital discharge decisions. Some guidance regarding simple parameters to review when considering hospital discharge can be obtained from a recent US prospective, multi-centre, observational cohort study of 680 patients admitted to hospital with CAP 98 , and is offered as advice for all patients admitted with influenza-related respiratory complications. • Patients should be reviewed before 24 hours of discharge home. Those with two or more of the following unstable clinical factors should be considered for continued hospital management: (1) temperature > 37.8ºC, (2) heart rate >100/min, (3) respiratory rate >24/min, (4) systolic blood pressure <90 mmHg, (5) oxygen saturation <90%, (6) inability to maintain oral intake, It is usual practice to arrange 'routine' hospital clinic follow up and repeat the chest radiograph at around six weeks after discharge for acute respiratory illness such as pneumonia. However, there is no evidence on which to base a recommendation regarding the value of this practice in patients who have otherwise recovered satisfactorily. It is also not known whether there is any value in arranging clinical follow up in a hospital clinic rather than with the patient's general practitioner. During an influenza pandemic situation, it is likely that only patients who developed complications or who had significant worsening of their underlying disease will be offered clinical review at one or other venue. At discharge, patients should be offered access to information about their take-home medication, smoking and lifestyle advice as appropriate, potential future complications and action to take in the event of a relapse of symptoms. • Follow-up clinical review should be considered for all patients who suffered significant complications or who had significant worsening of their underlying disease, either with their general practitioner or in a hospital clinic. • At discharge or at follow up, patients should be offered access to information about their illness, take-home medication and any follow-up arrangements. • It is the responsibility of the hospital team to arrange the follow-up plan with the patient and the general practitioner. Section 13. Use of antivirals in hospitalised adults 13 .1. What drugs should be used for antiviral treatment during a pandemic? Oseltamivir (neuraminidase inhibitor) will be the mainstay for therapy in the pandemic. The M2 inhibitors, amantadine and rimantadine, are unsuitable for use for treatment due to the rapid emergence of resistance together with sideeffects. From clinical trial data accrued to date and based on seasonal, interpandemic influenza, the anticipated positive effect of antivirals in a pandemic will be: (a) a reduction of illness duration by 24 hours, and therefore more rapid mobilisation of affected individuals including essential workers; (b) a possible reduction in hospitalisation of infected individuals; (c) a reduction of subsequent antibiotic use by infected individuals. There is insufficient evidence accrued to date to determine the effect of antivirals, if any, on overall mortality. Therefore the major utility of antivirals will be to maintain the essential workforce, and reduce hospitalisation and antibiotic treatment of complications. (neuraminidase inhibitors) during a pandemic? • Individuals should only be considered for treatment with neuraminidase inhibitors if they have all of the following: (1) an acute influenza-like illness (2) fever (>38ºC) and (3) been symptomatic for two days or less • Treatment schedule: adults: oseltamivir 75 mg every 12 hours for 5 days. Dose to be reduced by 50% if creatinine clearance is less than 30 ml/minute. • Exceptions: (i) Patients who are unable to mount an adequate febrile response, e.g. the immunocompromised or very elderly, make still be eligible despite lack of documented fever. (ii) Hospitalised patients who are severely ill, particularly if also immunocompromised, may benefit from antiviral treatment started more than 48 hours from disease onset. This advice reflects the lack of robust evidence to guide the use of antivirals in these exceptional circumstances and places a high value on the potential benefits of antiviral therapy. Drugs available for treatment and prevention of infection by influenza are summarised in Table 13 .1. There are four drugs available, the older agents amantadine and rimantadine and the neuraminidase inhibitors oseltamivir and zanamivir. Older agents: The older agents, amantadine and rimantadine (rimantadine is not currently licensed in the UK), are related substances that act by blocking the ion-channel function of the influenza virus M2 protein. This protein, although a minor surface constituent of the influenza virus particles, is essential for virus replication. These agents are only active against influenza Type A. Amantadine is not recommended by NICE for treatment and/or prophylaxis of interpandemic influenza, so in the absence of national stockpiling, supplies of amantadine can be expected to be very low. H5 viruses in South East Asia are resistant to amantadine, so this agent may play no role at all depending on the nature of the pandemic strain. Two neuraminidase inhibitors so far have been developed to the level of entry into the formulary: Zanamivir is a modification of Neu5Ac2en, a dehydrated neuraminic acid derivative. Oseltamivir is a similar molecule except it has a cyclohexene ring and replaces a polyglycerol moiety with lipophilic sidechains. Oseltamivir can be taken by mouth, whereas zanamivir must be inhaled, using a diskhaler device. An intravenous formulation of zanamivir has been developed but its efficacy has not been established. This may be relevant for the management of ventilator cases. Both drugs are active against influenza Type A as well as Type B viruses. Older agents. Both amantadine and rimantadine are effective for the treatment of Type A influenza virus infection if treatment is begun within 48 hours of the onset of illness 99 . Historical data show that they can shorten the illness by approximately one day but their efficacy in preventing complications, hospitalisations, or deaths has never been established. Although these drugs are effective, their use in clinical influenza treatment has been limited as a result of their proclivity to induce viral resistance, and their side-effect profile. Several large clinical trials have demonstrated the utility of zanamivir and oseltamivir in treatment of adults with influenza in the community ( Virtually all studies on the efficacy of neuraminidase inhibitors to reduce complications have been conducted with oseltamivir, and this drug has been shown to have some effect on outcomes other than time to recovery. In a meta-analysis of adults and adolescents with a virologically proven influenza illness, oseltamivir treatment reduced overall antibiotic use for any reason by 26 105 . So far, the neuraminidase inhibitors have not been extensively investigated in patients who are at the highest risk of serious complications of influenza. Such patients include the elderly and those with serious cardiopulmonary illness, such as chronic obstructive pulmonary disease. The neuraminidase inhibitors have not been associated with a reduction in mortality, but the clinical trials conducted so far have not been appropriate to measure this. It is not known for certain whether the neuraminidase inhibitors will be effective in pandemic influenza because their use has only been assessed in inter-pandemic influenza, where the virulence is moderate and there is some degree of host immunity. The antiviral activity is likely to be adequate; in vitro, all neuraminidase inhibitors have been demonstrated to have a broad spectrum of activity against multiple avian influenza viruses 106 . The older agents, rimantadine and amantadine, were studied in both the 1968 Hong Kong pandemic and again when H1N1 influenza appeared in a pandemic in 1977. Their efficacy has been reviewed by Hayden 99 . When the older agents were given for four to eight week periods as prophylaxis in a community setting, their protective efficacy against influenza illness averaged 70% compared with placebo. This compares with 80 90% efficacy observed with the same agents in studies during the interpandemic period. When amantadine or rimantadine are used to treat patients, resistant viruses emerge rapidly and approximately 30% of treated children or adults will shed resistant variants starting two to five days after the onset of treatment 104 . The resistant viruses shed from these patients retain full virulence, infectivity and transmission potential. When contacts of cases treated with amantadine or rimantadine are given post-exposure prophylaxis with these older agents, the reduction in secondary cases is minimal 107 . In contrast, the frequency of emergence of resistance during treatment with the neuraminidase inhibitors is reported to be low. However, during studies of experimentally induced influenza A/H1N1 infection in healthy adults, 4% of participants shed viruses with a histidine to tyrosine substitution at position 274 within the binding site of oseltamivir 108 . In these cases the volunteers had increased influenza viral load within the nasopharynx but there was no deterioration of symptoms. So far, there have been no proven instances of transmission of oseltamivir or zanamivir-resistant variants in field clinical trials, but the experience is relatively small currently. Sequence analysis of H5N1 human isolates from North Vietnam have revealed virus with a 274 Y (resistant) sequence. Although the isolate was not fully resistant, its IC50 for oseltamivir was shifted upwards and it is therefore less susceptible to oseltamivir than other H5N1 isolates that had been tested from the region. The patient from whom the virus was isolated was concurrently being treated with oseltamivir. Both amantadine and rimantadine can cause nausea and vomiting in a small percentage of individuals receiving them (Table 13 .1). Unfortunately amantadine is also associated with very unpleasant central nervous system side-effects including anxiety, depression, insomnia and hallucinations. The side-effects are dose-related and do resolve with discontinuation of the drug. In the case of the neuraminidase inhibitors, both drugs appear relatively safe. Zanamivir has very few side-effects, but can result in bronchospasm which might be potentially serious in patients with asthma. Oseltamivir requires dose-reduction in patients with low creatinine clearance (<30 ml/min). Nausea occurs in 5 15% of oseltamivir recipients but is seldom severe enough to lead to drug discontinuation (see Table 13 .3). Antimicrobial chemotherapy will be indicated primarily for respiratory complications due to secondary bacterial infections, principally influenza-related pneumonia. The majority of patients with exacerbations of chronic obstructive pulmonary disease (COPD) and other chronic lung conditions due to secondary bacterial infections, such as bronchiectasis, will also require antimicrobial chemotherapy, as will some patients with severe sinusitis. Few pneumonias and lower respiratory tract infections are defined microbiologically at initial assessment and hence most prescribing is empirical. In broad terms the antimicrobial management of these patients should follow the guidance offered in relevant national guidelines for the management of community-acquired pneumonia and COPD, but modified in the light of the different range of pathogenic bacteria that may be implicated, specifically Staph. aureus infection. In the minority of cases, the aetiology may be determined after hospital admission, thereby permitting modification of the initial empirical regimen. Although the pathogens responsible for communityacquired pneumonia are diverse, in the case of bacterial pneumonia complicating influenza the principal pathogens which should be covered by any initial empirical antimicrobial therapy include S. pneumoniae, H. influenzae and Staph. aureus. The latter is said to be more common with combined viral bacterial pneumonia, as some strains of staphylococci have synergistic effect with the virus. Gram-negative enteric bacillary infection is also sometimes seen. Exacerbations of COPD will be largely associated with S. pneumoniae, H. influenzae, and Moraxella catarrhalis. Severity assessment and the association of pre-existing co-morbid disease is essential in predicting prognosis and in turn determines management, choice of antibiotic therapy and its method of administration (see Section 9). During an influenza pandemic this will be principally related to concerns about the local pattern of antimicrobial resistance of Staph. aureus, and assessing the possibility of methicillin-resistant S. aureus (MRSA) being present locally. Clinicians should be kept closely informed of any local shift in antimicrobial resistance patterns, both at the start and during a pandemic. Staphylococcus aureus is widely resistant to penicillin 109 and an increasing number are now methicillin-resistant (MRSA); when occurring in the community this generally reflects hospitalisation within the recent past or residence within a nursing home 110 . Hence, b-lactamase unstable penicillins (penicillin G, aminopenicillins) and, in the case of MRSA, isoxazolyl penicillins (flucloxacillin, cloxacillin) and cephalosporins, are inappropriate for such infections. The true incidence of resistance among pathogens in the community is difficult to estimate since most laboratory samples come from selected populations. With this limitation in mind, the presence of b-lactamase production among H. influenzae varies geographically but ranges from 2% to 17% 111, 112 in various parts of the UK. M. catarrhalis has a high rate of b-lactamase production. Antibiotic resistance among S. pneumoniae is of concern world wide, owing to the dominance of this organism as a cause of community-acquired pneumonia and because penicillin and macrolide resistance are frequently linked 112, 113 . However, to date it is not a common enough problem in the UK to influence initial antimicrobial management decisions. Recent data provided by the HPA of antimicrobial sensitivities of respiratory pathogens isolated from blood and respiratory samples during the last three to four years (Robert George, personal communication) found macrolide resistance amongst about 10 14% methicillinsensitive Staphylococcus aureus (MSSA) isolates and 12 19% of S. pneumoniae. Macrolides, apart from clarithromycin, have poor in vivo activity against H. influenzae. By contrast, tetracycline resistance was around 5 8% for S. pneumoniae, 3% for H. influenzae and 2 8% for MSSA. Fluoroquinolones have activity against methicillinsensitive Staphylococcus aureus (MSSA), with MIC 90 figures of 1.0 mg/l for ciprofloxacin, 0.5 mg/l for levofloxacin and 0.12 mg/l for moxifloxacin 114 . Modern fluoroquinolones (oral moxifloxacin and oral and IV levofloxacin currently licensed in the UK) are therefore a possible choice for secondary bacterial infections following influenza where MSSA is a likely pathogen. A recent pharmacokinetic and pharmacodynamic in vitro study indicated that moxifloxacin 400 mg od had advantages over ciprofloxacin 500 mg bd or levofloxacin 500 mg od in antimicrobial effects against Staph. aureus 115 . The quinolones, levofloxacin or moxifloxacin, also provide cover against S. pneumoniae and H. influenzae. MRSA is an unlikely pathogen in the UK in the context of community-acquired respiratory bacterial infection following influenza, and fluoroquinolones are not sufficiently active against MRSA. There are no robust research studies available to provide evidence-based guidance on the best empirical choice of antimicrobial therapy for bacterial complications of influenza. For these reasons the recommendations for treatment have been made on the basis of assessing a matrix of laboratory, clinical, pharmacokinetic and safety data, interpreted in an informed manner and taking account of other published guidelines 116 . In those with chronic lung disease, particularly COPD, bacterial exacerbation will be the commonest cause of admission. It is likely that all such patients sufficiently ill to require hospital admission with an exacerbation will require antibiotics. Management of their underlying Macrolide (erythromycin 500 mg qds PO or clarithromycin 500 mg bd b PO) or Fluoroquinolone with enhanced pneumococcal activity (e.g. levofloxacin 500 mg od PO or moxifloxacin 400 mg od PO c ) If IV needed: Co-amoxiclav 1.2 g tds IV or cefuroxime 1.5 g tds IV or cefotaxime 1 g tds IV Macrolide (erythromycin 500 mg qds IV or clarithromycin 500 mg bd b IV) or Levofloxacin 500 mg od IV c 3. Hospital-treated, severe pneumonia Co-amoxiclav 1.2 g tds IV or cefuroxime 1.5 g tds IV or cefotaxime 1 g tds IV plus Macrolide (erythromycin 500 mg qds IV or clarithromycin 500 mg bd b IV) Fluoroquinolone with some enhanced pneumococcal activity (e.g. levofloxacin 500 mg bd IV, PO c plus, either Macrolide (erythromycin 500 mg qds IV or clarithromycin 500 mg bd b IV) or b-lactamase stable antibiotic (co-amoxiclav 1.2 g tds IV or cefuroxime 1.5 g tds IV or cefotaxime 1 g tds IV) a An alternative regimen is provided for those intolerant of or hypersensitive to the preferred regimen. b Clarithromycin may be substituted for those with gastrointestinal intolerance to oral erythromycin and also has the benefit of twice daily dosage and better cover against H. influenzae. c Levofloxacin and moxifloxacin are the only currently UK-licensed fluoroquinolones with enhanced activity against S. pneumoniae, in addition to cover for Staph. aureus. Levofloxacin comes in an oral and a parenteral formulation and is licensed for severe pneumonia. Moxifloxacin comes in an oral formulation only in the UK and is not licensed for severe pneumonia. In the future, other fluoroquinolones such as gemifloxacin and gatifloxacin are likely to extend this choice, when licensed in the UK. Abbreviations: od, once daily; bd, twice; tds, 3 times; qds, 4 times: IV, intravenous; PO, oral. Switch from parenteral drug to the equivalent oral preparation should be made as soon as clinically appropriate, in the absence of microbiologically confirmed infection. In the case of the parenteral cephalosporins, the oral switch to co-amoxiclav 625 mg tds is recommended rather than to oral cephalosporins. condition, such as COPD, should follow standard guidelines, including the use of corticosteroids if indicated. Antibiotics should cover the likely bacterial pathogens, including S. pneumoniae, H. influenzae, M. catarrhalis and Staph. aureus. Oral therapy should be sufficient for those without adverse severity features and who are able to take oral medication. The preferred first choice of antibiotic for nonpneumonic bronchial infections should include an effective oral b-lactamase stable agent such as co-amoxiclav, or a tetracycline, such as doxycycline. A macrolide is an alternative for those intolerant of the preferred first choices, whilst remembering the possibility of antimicrobial resistance. Clarithromycin has better activity against H. influenzae than azithromycin. A newer-generation fluroquinolone (e.g. levofloxacin or moxifloxacin) with enhanced activity against S. pneumoniae is an alternative choice if there is increased likelihood of resistance or local issues that dictate such a choice. • Previously well adults with acute bronchitis complicating influenza, in the absence of pneumonia, do not routinely require antibiotics. • Antibiotics should be considered in those previously well adults who develop worsening symptoms (recrudescent fever or increasing dyspnoea). • Patients at high risk of complications or secondary infection (Appendix 2) should be considered for antibiotics in the presence of lower respiratory features. • Most patients can be adequately treated with oral antibiotics. • The preferred choice includes co-amoxiclav or a tetracycline. • A macrolide such as clarithromycin (or erythromycin) or a fluoroquinolone active against S. pneumoniae and Staph. aureus is an alternative choice in certain circumstances. Patients will be suffering from primary viral pneumonia, or combined viral bacterial pneumonia, or secondary bacterial pneumonia. The features of each of these are covered in Section 3. All patients with pneumonic involvement should receive antibiotics. The principles of antibiotic selection for nonsevere influenza-related pneumonia is similar to those for the management of sporadic community-acquired pneumonia in general 72 , except that adequate cover for Staph. aureus should be included in any empirical regimen. It is also not felt necessary to routinely provide cover for atypical pathogens (Mycoplasma pneumoniae, Chlamydia sp., Coxiella burnetti, Legionella sp.) during a pandemic as the large majority of patients will be hospitalised as a direct result of influenza and its complications caused by bacterial infection. For these reasons oral co-amoxiclav or a tetracycline such as doxycycline is the preferred regimen (Table 14 .1). When oral therapy is inappropriate, parenteral coamoxiclav or a second-or third-generation cephalosporin is offered as an alternative. Based on in-vitro data, the activity of selected cephalosporins against MSSA in the UK in descending rank order is cefuroxime (MIC90 1 2 mg/l) > cefotaxime (MIC90 2 mg/l) > ceftriaxone (MIC90 16 mg/l) [Robert George, personal communication]. Only cefuroxime and cefotaxime are recommended as cephalosporins offering adequate MSSA cover within an empirical regimen. A macrolide or one or the new fluoroquinolones are identified as alternatives in hospitalised patients, in specific circumstances. These include those intolerant of penicillins or where local microbiological surveillance suggests they are better choices. At the time of completing these guidelines, only levofloxacin and moxifloxacin are licensed and available in the UK for pneumonia. Flucloxacillin is not recommended as part of an empirical regimen because its activity against a narrow spectrum of pathogens (predominantly Staph. aureus) would require it to be used in combination with more than one other antibiotic. It is offered as the antibiotic of choice in confirmed methicillin-sensitive Staph. aureus (MSSA) infection. Regardless of the regimen selected it is critical that the antibiotics be administered promptly (within four hours of admission), and in the case of the patient with severe pneumonia without delay, by the admitting doctor in the admissions ward or by the general practitioner if delays are expected in the hospital admission process. Delays in administration of antibiotics are related adversely to mortality in some studies, particularly when managing elderly patients 117, 118 . Following initial assessment and empirical therapy, progress should be monitored carefully. The route and choice of antibiotic treatment will require adjustment, either by stepping up and broadening the spectrum of microbiological activity in the light of clinical deterioration or as a result of positive microbiological information, or stepping down with improvement as discussed below. • Most patients can be adequately treated with oral antibiotics. • Oral therapy with co-amoxiclav or a tetracycline is preferred. • When oral therapy is contra-indicated, recommended parenteral choices include intravenous co-amoxiclav, or a second or third generation cephalosporin (cefuroxime or cefotaxime respectively). • A macrolide (erythromycin or clarithromycin) or a fluoroquinolone active against S. pneumoniae and Staph. aureus is an alternative regimen for those intolerant of penicillins. Currently levofloxacin and moxifloxacin are the only recommended fluoroquinolones licensed in the UK. • Antibiotics should be administered within four hours of admission. Mortality is greatly increased in those with severe pneumonia (Section 9). The illness may progress before microbiological information is available. Preferred and alternative initial treatment regimens are summarised in Table 14 .1. The recommendation of broadspectrum b-lactam regimens plus a macrolide in those with severe influenza-related pneumonia is based on the following rationale: (a) While S. pneumoniae and Staph. aureus remain the predominant pathogens, Gram-negative enteric bacilli, although uncommon, carry a high mortality 119 . (b) The recommended empirical regimen will offer double cover for the likely pathogens implicated in influenzarelated pneumonia and there is some evidence to indicate that combination therapy is associated with better outcomes in severe pneumonia 120 . (c) Although there is no evidence of an increased incidence of infection by atypical pathogens in influenzarelated pneumonia, in severe pneumonia it is felt necessary to include cover for atypical pathogens, particularly Legionella sp. as it may not be possible at the outset to distinguish between patients with sporadic severe community-acquired pneumonia in whom Legionella infection is important, and influenzarelated pneumonia. Parenteral administration of antibiotic is recommended in those with severe community-acquired pneumonia regardless of the patient's ability or otherwise to take oral medication. This is to ensure prompt, high blood and lung concentrations of antibiotic. A fluoroquinolone is offered as an alternative, despite limited data on their use in severe pneumonia 121 . At the time of writing, levofloxacin is the only licensed and available agent in the UK for severe pneumonia. It is marketed in parenteral and oral formulations. However, until more clinical experience is available we recommend combining it with another agent active against S. pneumoniae and Staph. aureus such as a broad-spectrum b-lactam or macrolide when managing severe influenzarelated pneumonia. • Patients with severe pneumonia should be treated immediately after diagnosis with parenteral antibiotics. • An intravenous combination of a broad-spectrum b-lactamase stable antibiotic such as co-amoxiclav or a second-(e.g. cefuroxime) or third-(e.g. cefotaxime) generation cephalosporin together with a macrolide (clarithromycin or erythromycin) is preferred. • An alternative regimen includes a fluoroquinolone with enhanced activity against pneumococci together with a broad-spectrum b-lactamase stable antibiotic or a macrolide. Currently levofloxacin is the only such fluoroquinolone licenced in the UK. • Patients who have been in hospital within the last few months have a higher chance of carrying MRSA as opposed to patients who have not been hospitalised recently. Therefore due consideration should be given to the possibility of MRSA if they are known or suspected to have a staphylococcal pneumonia and/or are not responding to empirical therapy. 14.7. When should the IV route be changed to oral? There can be no rigid recommendation concerning the timing of transfer to oral therapy and further studies of this area are needed 122 . Any decision must be individualised on the basis of assessing all factors, including the absence of any contraindications to oral administration, the availability of any microbiological information regarding aetiology of the infection and clear evidence that the patient is responding to initial therapy. The recommended guideline is that oral therapy be considered in a patient who has shown clear evidence of improvement and whose temperature has resolved for a period of 24 hours. • Patients treated initially with parenteral antibiotics should be transferred to an oral regimen as soon as clinical improvement occurs and the temperature has been normal for 24 hours, providing there is no contraindication to the oral route. 14.8. For how long should antibiotics be given? Until there are more precise methods to reliably identify microbiological and clinical end-points, the duration of therapy will remain subject to clinical judgement and custom. For these reasons the duration of therapy will vary by individual patient, disease severity and speed of resolution. • For most patients admitted to hospital with nonsevere and uncomplicated pneumonia, seven days of appropriate antibiotics is recommended. • For those with severe, microbiologically undefined pneumonia, ten days treatment is proposed. This should be extended to 14 21 days where S. aureus or Gramnegative enteric bacilli pneumonia is suspected or confirmed. 14.9. Failure of initial empirical therapy In those patients who fail to respond to initial empirical therapy, several possibilities need to be considered, the first of which is whether the correct diagnosis has been made. Radiographic review is recommended for the community-and hospital-managed patient. This may also indicate complications of pneumonia such as pleural effusion/empyema, lung abscess or worsening pneumonic shadowing, which will be more common in the presence of staphylococcal infection. The initial empirical antibiotic regimen may need to be reassessed. However, compliance with, and adequate absorption of an oral regimen should first be considered. Microbiological data should be reviewed and further specimens examined, with a view to excluding Staph. aureus and Gram-negative bacillary infection. In the hospital-managed, non-severely ill patient, changing to a new fluoroquinolone such as levofloxacin provides a second alternative. In the severely ill patient already receiving a b-lactam/ clarithromycin regimen, it is recommended that further staphylococcal cover is added to include cover for MRSA 123 . In addition, urgent referral to a respiratory physician should be made for clinical assessment including the possible need for bronchoscopic sampling. Other rapid MRSA diagnostic techniques are in the evaluation stage. • For those with non-severe pneumonia in hospital on combination therapy, changing to a fluoroquinolone with effective pneumococcal and staphylococcal cover is an option. • Adding further antibiotics effective against MRSA is an option for those with severe pneumonia not responding to combination antibiotic therapy. Specific pathogen-directed antibiotic therapy 14.10 . What are the optimum antibiotic choices when specific pathogens have been identified? When a pathogen has been identified, specific therapy as summarised in Table 14 .2 is proposed. In transferring patients from empirical to pathogen-targeted therapy, the regimen and route of administration will be determined by the continued need for parenteral therapy and known drug intolerance. These recommendations are again based on a synthesis of information, which includes in vitro activity of the drugs, appropriate pharmacokinetics and clinical evidence of efficacy gleaned from a variety of studies. The choice of agent may be modified following the availability of sensitivity testing or following consultation with a specialist in microbiology, infectious disease or respiratory medicine. Close liaison with the local microbiology service will be essential during a pandemic. Currently S. pneumoniae highly resistant to penicillin (MIC 4 mg/l) is uncommon in the UK. However, it is important that the situation is monitored and in future §14. Use of antibiotics in hospitalised adults Part 2. Clinical management of adults referred to hospital Pandemic flu. Clinical management of patients with an influenza-like illness during an influenza pandemic S37 either ciprofloxacin 400 mg bd IV or piperacillin 4 g tds IV ± gentamicin or tobramycin (dose monitoring) higher doses of penicillins or alternative regimens may need to be considered. Staphylooccus aureus is an uncommon cause of sporadic community-acquired pneumonia in the UK, but will assume much greater potential importance during a pandemic. Most community isolates are methicillin-sensitive although the recent increase in MRSA in hospitalised patients may result in subsequent readmission with an MRSA infection, secondary to influenza. Options for methicillin-sensitive and -resistant infections are based on parenteral administration in view of the serious nature of staphylococcal pneumonia. • If a specific pathogen has been identified, the antibiotic recommendations are summarised in Children with high fever (>38.5ºC) and cough or influenzalike symptoms will be seen by a community health professional (a nurse or doctor if under seven years of age). If there are no features that put them at high risk of complications they should be treated with oseltamivir, and given advice on antipyretics and fluids. Children under one year of age and those at risk of complications (Appendix 2) should be seen by a GP. Children may be considered at increased risk of complications if they have: Cough and fever (or influenza-like illness) and temperature >38.5ºC and either (i) chronic co-morbid disease (see Appendix 2) or (ii) one of the following features • Breathing difficulties • Severe earache • Vomiting > 24 hours • Drowsiness These patients should be offered an antibiotic as well as oseltamivir (in those over one year of age) and advice on antipyretics and fluids. Children under one year of age with none of the above features should be treated with antipyretics and fluids with a low threshold for antibiotics if they become more unwell. The most severely ill children should be referred for assessment for admission. In a pandemic situation, paediatric high dependency and intensive care beds are likely to fill quickly and will be insufficient to meet demand. Children will have to be triaged by the senior paediatrician on duty in consultation with tertiary specialists in respiratory medicine, paediatric intensive care or paediatric infectious diseases. Triage will be on the basis of the severity of the child's (a) acute and (b) co-existing disease and the likelihood of the child achieving full recovery. Where admission is not possible §16. General investigations for children in hospital Part 3. Clinical management of children referred to hospital Pandemic flu. Clinical management of patients with an influenza-like illness during an influenza pandemic S39 the tertiary specialists will provide advice and support on management to the general paediatrician. In the H5N1 cases reported from Vietnam 125 all seven children had WBC < 4.0 (mean 2.44) and 6/7 had a lymphopenia <1.0 (mean 0.66). Six of the seven children died. In contrast, only two of the seven children reported from Hong Kong died but they were both leukopenic and lymphopenic. The survivors had a mean WBC of 12.44 and lymphocyte count of 3.11 126 . Four of five cases reported from Thailand were lymphopenic 127 . In influenza A thrombocytopenia (<100) is found in 5 7% 71, 84 . Thrombocytopenia was found in four out of seven cases of H5N1 infection in Vietnamese children 125 . Liver transaminases are raised in 27% of influenza A patients 124 and were raised in six out of six of those measured in the Hong Kong H5N1 outbreak 126 and five out of six in those measured in Vietnam 125 . C-Reactive Protein (CRP) is unhelpful in influenza with values <10 in 55% 84 ; <20 in 72% 62 and >80 in only 5% 62 . The CD4/CD8 ratio was inverted in the two children and three adults in whom it was measured in the Vietnam outbreak (mean 0.7; range 0.59 1.08). Two of these patients survived 125 . • A full blood count with differential, urea, creatinine and electrolytes and liver enzymes and a blood culture should be done in all severely ill children. One of the largest studies of the value of chest radiography was undertaken in children aged between two months and five years with community-acquired pneumonia managed as outpatients with time to recovery as the main outcome 128 . Chest radiography did not affect the clinical outcome in these children with acute lower respiratory infection. This lack of effect was independent of clinicians' experience. There are no clinically identifiable subgroups of children within the WHO case definition of pneumonia who are likely to benefit from a chest radiograph. The authors concluded that routine use of chest radiography was not beneficial in ambulatory children aged over two months with acute lower respiratory tract infection (LRTI). Clinicians basing the diagnosis of lower respiratory infections in young infants on radiographic diagnosis should be aware that there is variation in intraobserver and interobserver agreement among radiologists on the radiographic features used for diagnosis. There is also variation in how specific radiological features are used in interpreting the radiograph. A recent study on standardization of CXR interpretation in paediatric pneumonia illustrates the importance of standardised training 129 . The cardinal finding of consolidation for the diagnosis of pneumonia appears to be highly reliable 130 and reasonably specific for bacterial pneumonia (74% of 27 patients with alveolar shadowing had bacterial proven pneumonia) 131 but overall chest radiography is too insensitive to be useful in differentiating between patients with bacterial pneumonia and those whose pneumonia is nonbacterial 132, 133 . In the context of an influenza pandemic, a CXR will not distinguish viral pneumonia from viral illness with bacterial superinfection, and all children with signs of pneumonia should be treated with antibiotics. • A CXR should be performed in children who are hypoxic, have severe illness or who are deteriorating despite treatment. Oxygen saturation (SaO 2 ) measurements provide a noninvasive estimate of arterial oxygenation. Pulse oximetry will be a key tool in assessment and management and it is essential that it is used correctly and that users are aware of the possibility of artefactually low readings. The oximeter appears easy to use and requires no calibration. However, it requires a pulsatile signal from the patient. It is also highly subject to motion artefacts. To obtain a reliable reading: (1) The child should be still and quiet. (2) When using paediatric wrap around probes, the emitting and receiving diodes need to be carefully opposed. (3) A good pulse signal (plethysmograph) should be obtained. (4) Once a signal is obtained, the saturation reading should be watched over at least 30 seconds and a value recorded once an adequate stable trace is obtained. • Pulse oximetry should be performed in every child being assessed for admission to hospital with pneumonia. To be read in conjunction with the corresponding section for adults (Section 11 in Part 2). As with adults, the extent of virological and microbiological investigations undertaken in children should vary according to the stage of the pandemic and additionally according to the severity of an individual case. It should be noted however, that the clinical features of influenza in children are less characteristic than in adults (see Section 4) and the need for special diagnostic tests is therefore greater 62, 134, 135 The utility of rapid influenza tests has been demonstrated in studies where rapid knowledge of a diagnosis of influenza (within ten minutes) has been shown to have an impact on clinicians' behaviour with respect to antibiotic use, performance of other tests and admission to hospital 136, 137 . It may be imagined that in a pandemic situation such a test could result in earlier use of antiviral therapy and a more rational approach to hospital admission and to prophylaxis of contacts. However, using a molecular reference standard, one test was shown to have low sensitivity (44%) but high specificity (97%) suggesting that its role might better be to 'rule in' influenza rather than 'ruling it out' 138 . Similar conclusions have been made with other commercial rapid tests 139, 140 . As a reflection of this, rapid antigen tests were positive in only two of six patients with avian influenza A (H5N1) 125 . The need for bacteriological tests in cases of influenza with pneumonia is also logical and the range of pathogens similar to adults 36,69,141-145 except that Legionella infection is extremely unlikely to occur in a previously healthy child and Legionella-specific antigen testing is therefore unnecessary. The urinary pneumococcal antigen tests in children may lack both sensitivity and specificity and should be interpreted with care 146, 147 . Sputum collection in children is also unreliable although in older children (e.g. over 12 years of age) it may be possible and should be handled as indicated for adults. A. Virology all children: During an influenza pandemic children are likely to be admitted to hospital because of the severity of their disease and its complications or because of the impact of influenza on pre-existing disorders such as cardiac, respiratory or neurological disease. Management of preexisting disorders is outside this guideline. • The most common reason for admission is likely to be: (1) Lower respiratory tract disease with either a viral or bacterial or mixed pneumonia. • Other reasons for admission include: (2) Severe gastroenteritis (3) Cardiac disease viral myocarditis (4) Encephalitis Children should be triaged to ward or HDU/PICU after severity assessment (Section 15). An influenza pandemic is likely to occur in the winter months when other winter viruses responsible for paediatric morbidity and hospital admission are circulating (such as RSV and adenovirus). Particularly in the early stages of a pandemic (UK alert levels 1 3) it will be important to use rapid virological tests in an attempt to cohort influenzapositive and RSV-positive infants separately and to separate from other patients (see UK Infection Control Guidance for Pandemic Influenza) 3 . Hypoxic infants and children may not appear cyanosed. Agitation may be an indication of hypoxia. Patients whose oxygen saturation is less than 92% while breathing air should be treated with oxygen given by nasal cannulae, head box, or face mask to maintain oxygen saturation above 92%. Nasal cannulae do not deliver a FiO 2 more than around 40% even at flow rates of 2 l/min in infants and 4 l/min in older children. Alternative methods of delivering higher concentrations of humidified oxygen such as a head box or a Venturi face mask may be necessary. If SaO 2 > 92% cannot be maintained with an FiO 2 of 60% then additional support such as CPAP, BiPAP or intubation and ventilation should be considered. • Patients whose oxygen saturation is 92% or less while breathing air should be treated with oxygen given by nasal cannulae, head box, or face mask to maintain oxygen saturation above 92%. Children who are unable to maintain their fluid intake due to breathlessness, fatigue or gastroenteritis need fluid therapy. Where possible additional fluid should be by the enteral route, and where nasogastric tube feeds are used, the smallest tube should be passed down the smallest nostril to minimize effects on respiratory status. Severely ill children may need intravenous fluids, and if the child is in oxygen therapy intravenous fluids should be given at 80% basal levels (to avoid complications of inappropriate ADH secretion) and serum electrolytes should be monitored. The monitoring will depend on the child's condition. Severely ill children will need continuous monitoring of heart rate, respiratory rate, oxygen saturation and neurological status. All children on oxygen therapy should have four-hourly monitoring including oxygen saturation. Chest physiotherapy is not beneficial in previously healthy children with pneumonia. Children with underlying conditions such as cystic fibrosis or neuromuscular weakness will benefit from intensive physiotherapy. Children with influenza are generally pyrexial and may have some pain, including headache, chest pain, arthralgia, abdominal pain, and earache from associated otitis media. Pleural pain may interfere with depth of breathing and may impair the ability to cough. Antipyretics and analgesics can be used to keep the child comfortable and to help coughing. 18.9. When can children be safely discharged from hospital? In a pandemic situation there will be great pressure on hospital beds. All children should be assessed for discharge at least twice daily. Children should not remain in hospital if they are receiving therapy that could be given in the community. In previously healthy children suitable discharge criteria would be: (1) child is clearly improving (2) child is physiologically stable (3) child can tolerate oral feeds (4) respiratory rate is <40/min (<50/min in infants) (5) awake oxygen saturation is >92% on air. Most children will make an uneventful recovery and not require follow up. Those with a prolonged illness may be followed up by their general practitioner. Only children with severe disease and/or at high risk of sequelae need hospital follow up. Children with lobar collapse should have a follow-up CXR. Follow-up CXRs after acute uncomplicated pneumonia are of no value where the patient is asymptomatic 148, 149 . To be read in conjunction with the corresponding section for adults (Section 13 in Part 2) Five antiviral agents are theoretically available for the therapy of influenza in children: the M2 ion channel inhibitors amantadine and rimantadine (both administered orally and for influenza A only), the neuraminidase inhibitors oseltamivir (administered orally) and zanamavir (administered through an inhaler), and ribavirin (aerosolised). The limitations of amantadine and rimantadine are detailed in Section 13, particularly in the context of a pandemic where resistance may already be present 150 . Both have been shown to be effective in the treatment of influenza A in children 151 . Concerns exist about the development of resistance during therapy for both agents 151, 152 . A household study showed that treatment and prophylaxis with rimantadine resulted in rapid selection and transmission of drug resistant virus 153 . In a double-blind randomised, placebo controlled study, 217 children (1 12 years of age) received oseltamivir with a resultant reduction in the median duration of illness, incidence of otitis media as a complication of influenza (12% vs 21%) and the need for antibiotic prescriptions in those with influenza (68 of 217, 31% vs 97 of 235, 41%; p = 0.03) compared to placebo 103 . The most common sideeffect was vomiting (5.8%). A systematic review and meta-analyses published in 2003, which included studies up to December 2001, included only two studies of zanamivir and one study of oseltamivir 103 in which these drugs were administered for treatment of influenza A or B in children under 12 years of age 154 . The reduction in the median time to alleviation of symptoms for influenza-positive children when compared with placebo was 1.0 day (95% CI: 0.4 1.6) for zanamivir and 1.5 days (0.8 2.2) for oseltamivir. Across all ages a 29% (10 44%) relative reduction in complications requiring antibiotics was observed for zanamivir, and for children specifically a 35% relative reduction was observed for oseltamivir. This was updated through to December 2002 in a Cochrane review 155 . Using its search criteria it identified two trials of oseltamivir (one in healthy children 103 and one in children with asthma which was later published 156 and only one with zanamivir. Its conclusions were therefore the same with respect to median illness duration in healthy children. A significant reduction in complications (otitis media) was noted for oseltamivir while a trend to benefit was seen for zanamivir 155 . Vomiting was significantly more common among oseltamivir recipients than placebo recipients (15% vs. 9%). The review noted that there may be a difference in efficacy according to serotype, with oseltamivir showing a significant reduction in time to resolution for influenza A (34%) but not B (8.5%) 155 . With respect to children with asthma there was a trend to reduction in time to freedom from illness for oseltamivir recipients but this did not reach statistical significance. Oseltamivir appeared to result in a more rapid improvement in pulmonary function, and was well tolerated in children with asthma 155, 156 . The Cochrane review concluded that oseltamivir was the preferred drug as it has shown a benefit with regard to secondary complications. It also concluded that there was no evidence of benefit in at-risk children (i.e. asthma). From the perspective of pandemic use however, it should be noted that there was no evidence of harm in this group. With regard to dosing of oseltamivir, pharmacokinetic studies have suggested that young children clear the drug faster than older children, adolescents and adults and therefore need higher doses 157, 158 . The major practical issue with regard to zanamivir is its mode of administration limiting its use to children over the age of five years (FDA guidance: over seven years of age) 155 . The development of resistance to oseltamivir in children may be more common than appreciated and more common than seen in adults. In one study resistance mutations were documented in 18% of 50 children 158 . This has implications for widespread use in a pandemic situation. One particular issue with regard to paediatric use of oseltamivir is the apparent age limitation on its license (i.e. not for children under one year of age). This is particularly important because during epidemic years, of all children with influenza, it is children under six months of age who are most likely to be hospitalised 159 . The basis for this exclusion appears to be that rat data have shown high mortality in infant rats at seven days of age when given a dose of 1000 mg/kg together with high brain levels of oseltamivir, assumed to reflect the immature blood brain barrier at this age. This is reflected in product literature and an FDA alert although there are no published data. As a result, there are few human data in this age group as it was felt that it would be difficult to monitor CNS toxicity in this age group. However, because of a fear of encephalopathy due to influenza in young children, Japanese paediatricians §19. Use of antivirals in hospitalised children Part 3. Clinical management of children referred to hospital Pandemic flu. Clinical management of patients with an influenza-like illness during an influenza pandemic S43 have been using it in infants and data on 102 consecutive infants from Japan revealed no encephalopathy or mortality in recipients 160 . A second Japanese report where 47 children under one year were treated (4 mg/kg/day) showed similar efficacy for fever to a group of older children and no serious adverse effects 161 . There are no data on the effectiveness of oseltamivir if given more than two days from onset of illness. It is likely to be less effective and in particular to have little or no effect after five to six days of illness unless the child is immunosuppressed. Giving oseltamivir to sick hospitalised patients is theoretically likely to decrease their infectivity and so may be useful but there are no data to support this. In a double blind placebo controlled study children hospitalized with influenza who had been ill for 48 hours or less and who had a temperature of 37.8ºC or more were randomised to receive either ribavirin or placebo. Sixtytwo patients (35 in the placebo group, 27 in the ribavirin group) had a confirmed diagnosis of influenza. The time to reduction of temperature to 38.3ºC or less for the ribavirin group was 8.9 hours compared with 22.6 hours for the placebo group (p = 0.04). There were no other differences detected between groups 162 . There have been no further published studies in the 11 years since this report, thus ribavirin cannot be recommended at this time. • In the setting of a pandemic, children in the community should only be considered for treatment with antivirals if they have all of the following: (1) an acute influenza-like illness (2) fever (>38.5ºC) and (3) been symptomatic for two days or less. • Oseltamivir is the antiviral agent of choice. • Treatment schedule for children over one year: Body weight 15 kg, i.e. <3 years: 30 mg every 12 h Body weight >15 23 kg, i.e. 3 7 years:45 mg every 12 h Body weight 24 kg, i.e. >7 years: 75 mg every 12 h • In children who are severely ill in hospital oseltamivir may be used if the child has been symptomatic for less than six days. • Oseltamivir may be considered for the treatment of infants under one year of age, especially those with severe influenza. This would need to be done following appropriate discussion with the parents highlighting the concerns from the animal data and the relative paucity of human data in this age group. Section 20. Use of antibiotics in hospitalised children 20 .1. Who should get antibiotics? Secondary bacterial infections, particularly pneumonia and otitis media, are common in children with influenza. A case control study during an outbreak of severe pneumococcal pneumonia demonstrated that patients with severe pneumonia were 12 times more likely to have had an influenza-like illness and four times more likely to have positive influenza serology than controls 69 . Infections with Staph. aureus and H. influenzae are also more common during influenza outbreaks. A randomized controlled trial of antibiotics in 85 children aged four months to 11 years presenting with influenzalike symptoms during an influenza epidemic showed a decreased incidence of pneumonia in the antibiotictreated group (2.4% vs 16.3%, p = 0.031) 163 . There was no change in duration of fever or incidence of acute otitis media. Interestingly only one out of seven of the cases of pneumonia in the placebo group was thought to be bacterial. The authors postulated that as bacterial proteases facilitate propogation and pathogenesis of influenza in a mouse model, decreasing bacterial numbers and hence protease levels in the lung may decrease viral pneumonia. Another randomized trial of cephalosporins vs macrolides in 365 Japanese children with influenza-like symptoms showed faster alleviation of fever (3.8±1.4 vs 4.3±1.4 days, p = 0.006) in the macrolide group and a decrease in number with CXR evidence of pneumonia (2 vs 13 cases, p = 0.002; 14/15 had interstitial changes) 164 . The authors postulate that anti-inflammatory effects of macrolides may be responsible. • Children who (a) are at risk of complications of influenza or (b) have disease severe enough to merit hospital admission during an influenza pandemic should be treated with an antibiotic that will provide cover against S. pneumoniae, Staph. aureus and H. influenzae. The antibiotics of choice must cover the likely pathogens as above. Rarely a blood culture or pleural tap will provide the pathogen. The antibiotics should then be specifically tailored, e.g. IV benzylpenicillin or oral amoxicillin for S. pneumoniae and flucloxacillin or clindamycin for Staph. aureus. Part 3. Clinical management of children referred to hospital §20. Use of antibiotics in hospitalised children S44 Provisional guidelines from BIS/BTS/HPA in collaboration with the Department of Health, Version 11 (2 October 2006) A recent randomized controlled trial of the equivalence of oral amoxicillin vs IV benzylpenicillin in 252 children admitted to hospital with community-acquired pneumonia showed no difference in duration of illness or complications 165 . Oral antibiotics should be given provided oral fluids are tolerated. 20.5. Antibiotic choice for severe or complicated pneumonia? Children who are severely ill with pneumonia complicating influenza should have a second agent which provides good cover for gram positive organisms added to the regime (e.g. clarithromycin or cefuroxime) and the drugs should be given intravenously to ensure high serum and tissue antibiotic levels. Section 21. Acknowledgements, committee members and affiliations 21 Chronic obstructive pulmonary disease (COPD) including chronic bronchitis and emphysema, and such conditions as bronchiectasis, cystic fibrosis, interstitial lung fibrosis, pneumoconiosis and bronchopulmonary dysplasia (BPD). Asthma requiring continuous or repeated use of inhaled or systemic steroids or with previous exacerbations requiring hospital admission. Children who have previously been admitted to hospital for lower respiratory tract disease. Chronic heart disease Congenital heart disease, hypertension with cardiac complications, chronic heart failure and individuals requiring regular medication and/or follow-up for ischaemic heart disease. Chronic renal disease Nephrotic syndrome, chronic renal failure, renal transplantation. Chronic liver disease Cirrhosis, inflammatory bowel disease Diabetes and chronic metabolic disorders Diabetes mellitus requiring insulin or oral hypoglycaemic drugs. Immunosuppression and malignancy Due to disease or treatment: Asplenia or splenic dysfunction, HIV infection at all stages, malignancy. Patients undergoing chemotherapy leading to immunosuppression. Individuals on or likely to be on systemic steroids for more than a month at a dose equivalent to prednisolone at 20 mg or more per day (any age) or for children under 20 kg a dose of 1 mg or more per kg per day. Long-stay residential care homes residents This does not include prisons, young offender institutions, university halls of residence. Others Doctors retain discretion in identifying additional individual patients who they recognise as at high risk of serious complications should they develop influenza; for example patients with haemoglobinopathies, neurological diseases with muscle weakness, cerebral palsy or children on long-term aspirin who are at increased risk of Reye's syndrome. a The high-risk groups described in this Appendix are largely based on data from interpandemic influenza. During the course of a pandemic, the definition of 'high-risk groups' may differ. If so, details of the 'high-risk' patient group will be altered according to relevant clinico-epidemiological data. Users are strongly advised to refer to the latest version of these guidelines at all times. Treat as severe pneumonia Antibiotics not indicated <8.5 kg -7.5 mg/kg b.d. A Winter's Tale: coming to terms with winter respiratory illnesses. 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(ii) Severely ill and immunosuppressed patients, including those on long-term corticosteroid therapy, may benefit from antiviral therapy commenced later than 48 hours after the onset of ILI. (iii) Severely ill children <1 year old. (Parents must be informed that oseltamivir is not licensed for children <1 year old.) The first recorded instance of human infection by avian influenza H5N1 occurred in May 1997 in Hong Kong. The first patient was a 3-year old child who presented initially with symptoms of fever, sore throat and abdominal pain. He later developed Reye's syndrome, ARDS, multi-organ failure and eventually died 166 . A total of 18 persons were subsequently infected before the outbreak ended in December 1997 126, 167 . Half the patients were aged 18 years and below and only two were aged over 50 years. Abdominal symptoms, such as diarrhoea, vomiting and abdominal pain, were described in ten (56%) patients. Eleven (61%) had a severe illness characterised by pneumonia occurring within 14 days of symptom onset, lymphopenia, deranged liver function tests and a high mortality [six (55%) of 11 patients with pneumonia]. Secondary bacterial infections were not identified as the cause of the pneumonias.The most recent human outbreak of influenza A (H5N1) infection began in December 2003. The clinical features of hospitalised patients infected by the re-emergent avian influenza A (H5N1) in 2004 were similar to those described in patients in 1997 (Table A10 .1). Children and young adults were the main groups affected. Gastrointestinal symptoms were common. The presence of lymphopenia and deranged liver function tests was again associated with a poorer prognosis 125 .Since December 2003, over 150 cases had been reported to the WHO 168 . The mortality rate among hospitalised patients has been generally high (>40%). Death has occurred an average of ten days after the onset of illness and most patients have died of progressive respiratory failure.There has been a review of avian influenza A (H5N1) infection in humans up until September 2005 55 . Updated information can be found at www.who.int/csr/disease/avian_influenza/en/.