key: cord-0018180-9hy5sl60 authors: Heimonen, Jessica; McCulloch, Denise J.; O'Hanlon, Jessica; Kim, Ashley E.; Emanuels, Anne; Wilcox, Naomi; Brandstetter, Elisabeth; Stewart, Mark; McCune, David; Fry, Scott; Parsons, Sean; Hughes, James P.; Jackson, Michael L.; Uyeki, Timothy M.; Boeckh, Michael; Starita, Lea M.; Bedford, Trevor; Englund, Janet A.; Chu, Helen Y. title: A remote household‐based approach to influenza self‐testing and antiviral treatment date: 2021-05-03 journal: Influenza Other Respir Viruses DOI: 10.1111/irv.12859 sha: c94b3dfda6b180b5b9ae62d39e1820a8ca68d275 doc_id: 18180 cord_uid: 9hy5sl60 BACKGROUND: Households represent important settings for transmission of influenza and other respiratory viruses. Current influenza diagnosis and treatment relies upon patient visits to healthcare facilities, which may lead to under‐diagnosis and treatment delays. This study aimed to assess the feasibility of an at‐home approach to influenza diagnosis and treatment via home testing, telehealth care, and rapid antiviral home delivery. METHODS: We conducted a pilot interventional study of remote influenza diagnosis and treatment in Seattle‐area households with children during the 2019‐2020 influenza season using pre‐positioned nasal swabs and home influenza tests. Home monitoring for respiratory symptoms occurred weekly; if symptoms were reported within 48 hours of onset, participants collected mid‐nasal swabs and used a rapid home‐based influenza immunoassay. An additional home‐collected swab was returned to a laboratory for confirmatory influenza RT‐PCR testing. Baloxavir antiviral treatment was prescribed and delivered to symptomatic and age‐eligible participants, following a telehealth encounter. RESULTS: 124 households comprising 481 individuals self‐monitored for respiratory symptoms, with 58 home tests administered. 12 home tests were positive for influenza, of which eight were true positives confirmed by RT‐PCR. The sensitivity and specificity of the home influenza test were 72.7% and 96.2%, respectively. There were eight home deliveries of baloxavir, with 7 (87.5%) occurring within 3 hours of prescription and all within 48 hours of symptom onset. CONCLUSIONS: We demonstrate the feasibility of self‐testing combined with rapid home delivery of influenza antiviral treatment. This approach may be an important control strategy for influenza epidemics and pandemics. In the United States, influenza is typically diagnosed during an inperson healthcare visit and if antiviral treatment is prescribed, a subsequent visit to a pharmacy is required. This multi-step process may lead to delays in receipt of antivirals and potentially exposes other individuals in clinics and pharmacies to influenza. Since antiviral therapy is most effective when started within 48 hours of symptom onset, reducing delays to treatment initiation may improve outcomes in treated persons. [1] [2] [3] Baloxavir is an oral FDAapproved antiviral for early treatment of uncomplicated influenza in individuals aged 12 years and older. The long half-life of baloxavir allows a single treatment dose in contrast to five twice-daily doses of oseltamivir. Moreover, baloxavir treatment is associated with shorter duration of influenza virus detection compared with oseltamivir or placebo. 4 Households, particularly those with young children, play a key role in seasonal influenza epidemics because the frequency and intensity of contacts among household members are greater than in the broader community. 5 Prior studies have shown that young children are important contributors to the introduction and transmission of influenza in households. 6, 7 Therefore, households represent an important setting to study influenza intervention strategies. Home-based influenza testing and rapid treatment with homedelivered antivirals have not been evaluated in clinical trials. Home diagnosis of respiratory infections via self-testing or telemedicine services has the potential for widespread use, particularly during a pandemic where periods of social distancing and restricted movement occur. Similarly, home-based initiation of antiviral therapy may decrease time from symptom onset to initiation of therapy and could improve outcomes compared with current management practices. Advances in telemedicine services (telehealth), rapid delivery services, and the ongoing development of home-based influenza assays may make this a feasible strategy to employ. Here, we report the results of a pilot study examining the feasibility of a test-and-treat method for influenza in households with children, including the use of home influenza testing, telehealth, and rapid antiviral delivery. We conducted a prospective interventional study to assess the feasibility of a home-based approach to diagnosis and treatment of influenza in households with children. This study was conducted in the Seattle metropolitan area as part of the Seattle Flu Study. 8 The recruitment process and eligibility criteria were previously described. 9 Briefly, households of ≥ 3 individuals sleeping in the home for ≥ 4 days per week, with at least one child aged three months to 17 years, and containing ≥ 2 baloxavir age-eligible individuals, were eligible to participate. Recruitment was conducted via web-based advertisements and social media. Households were consented, and all data were captured using a remote, electronic platform in Project REDCap (Research Electronic Data Capture). 10 All informed consent conferences took place via phone, and written consent or assent was provided by all household members. At enrollment, one household member was designated the lead contact and provided demographic and baseline health information about all household members. All enrolled households were asked to complete a weekly survey regarding the presence or absence of acute respiratory infection (ARI) symptoms. ARI was defined as new or worsening acute cough or the presence of two or more respiratory symptoms (Table A1) Following dispensing, baloxavir was delivered to the household via a rapid courier service (Delivery Express) scheduled remotely by the study team ( Figure 1A ). One week after swab collection, ill participants were asked to complete a follow-up questionnaire reporting illness outcomes, the usability of the home test, and hypothetical illness behavioral changes with and without the use of the home influenza test. On February 7, 2020, there was a modification to the study design due to a required protocol change that prohibited the return of the influenza home test results to participants and telehealth providers based on Washington State Medical Test Site Licensure law regarding non-FDA-cleared research tests performed at home without real-time clinical laboratory testing confirmation. This protocol change impacted the primary outcome of the study; thus, the data presented here reflect the study period up until February 7, 2020, only. This study is registered on ClinicalTrials.gov (NCT04141930) and was approved by the UW Institutional Review Board. baloxavir, Ellume, households, influenza, testing, treatment The rapid home-based influenza immunoassay was developed, produced, and manufactured by Ellume (Ellume). This antigen detection test uses a combination of bioluminescence and Bluetooth technology, where users self-collect a mid-nasal swab and then use devicespecific equipment to add their sample to an analyzer. The analyzer conducts the rapid assay, testing against influenza A and influenza B virus targets, and then sends the result to a participant's smartphone using Bluetooth. Home-collected nasal specimens were placed in universal transport media (UTM) (Becton, Dickinson and Company) in accordance with International Air Transport Association (IATA) guidelines and transported to the laboratory at ambient temperature generally within 48-72 hours of collection where samples were aliquoted at room temperature and stored at 4°C prior to testing. Samples were extracted (Magnapure 96) and tested for respiratory pathogens, including influenza virus types and influenza A subtypes, by TaqMan RT-PCR (Thermo Fisher) on a QuantStudio 12 (Applied Biosystems) (Table A2 ). Positive and negative controls were included in each extraction and RT-PCR run. All samples were tested for Rnase P, a human cellular marker, and Rnase P relative cycle threshold (Crt) values were used to evaluate sample quality. Analyses were restricted to enrolled households that completed at least one symptom log prior to February 7, 2020. The illness results presented here are confined to specimens that were collected and received in the laboratory by February 7, 2020. Participant-level demographic information is reported by RT-PCR-confirmed influenza F I G U R E 1 (A) Study design overview including household-level and participant-level study flow of the test-and-treat strategy from December 23, 2019, to February 7, 2020. (B) Total number of households and participants completing study procedure steps based on households initiating symptom monitoring prior to February 7, 2020 status. Chronic respiratory disease was defined as a history of asthma or reactive airway disease, COPD or emphysema, or chronic bronchitis. Other chronic diseases such as diabetes, heart failure, or cancer were defined as non-respiratory chronic disease. Participantreported home influenza test usability, hypothetical behavioral changes when ill with and without the use of the home influenza test, and the sensitivity, specificity, and Cohen's kappa coefficient (κ) were calculated; concordance measures compared the influenza home test with the TaqMan assay, where the TaqMan assay represented the gold standard. A p-value <0.05 was considered statistically significant. All analyses were conducted using SAS software version 9.4. From November 2019 to February 7, 2020, 150 households enrolled in the study; 124 households completed one or more weekly symptom logs, resulting in 481 unique individuals selfmonitoring for respiratory symptoms ( Figure 1B) . Overall, the study participants were mostly healthy individuals, with 85.7% of the population reporting no chronic health conditions (Table 1) . Most individuals were insured, and 79.4% reported receiving the seasonal influenza vaccine. The study population predominately consisted of white individuals aged 18 to 49 years (44.7%) or 5 to 17 years (37.4%). Among participants experiencing respiratory symptoms, 58 influenza home tests were used during the test-and-treat phase of the study, yielding 12 positive results. Home influenza test results were compared with RT-PCR results from the confirmatory nasal swabs ( Among participants experiencing ARI, there were 11 telehealth visits (Table 4 ). In total, there were eight baloxavir home deliveries. The median delivery time was 1.62 hours; 87.5% of home deliveries occurred within 3 hours from the time of baloxavir prescription. Twenty-five percent of deliveries occurred within 24 hours of symptom onset, 37.5% occurred within 30 hours of symptom onset, and 37.5% occurred 30 to 48 hours after symptom onset. There were 58 nasal swabs collected concurrently with the home influenza test at the time of illness. These were returned to the laboratory for RT-PCR and yielded 11 (19.0%) influenza-positive cases from 11 individuals (seven influenza B and four influenza A) ( Figure 1B) . Among influenza cases, four were baloxavir ineligible due to age or medical history and seven were eligible, but three of these seven baloxavireligible influenza cases were not treated. Two of these three ( To our knowledge, this is the first report of a remote, householdbased approach to influenza diagnosis and treatment in which no Ellume-positive influenza A 3 a 0 3 Ellume-negative influenza A 1 54 55 face-to-face contact with a healthcare provider or pharmacist was required. In this pilot study, participants successfully self-monitored for the onset of respiratory symptoms, self-conducted a rapid home influenza test, remotely discussed their illness with a healthcare provider, and received prompt delivery of a prescribed antiviral medication when indicated. Participants were adherent to study procedures, with 124 (82.7%) of households participating in weekly respiratory surveillance and 58 individuals successfully completing home influenza tests. The vast majority of participants reported that the home influenza test and app were easy to use and that the results were easy to understand. The results of rapid home influenza testing were largely concordant with RT-PCR. Concordance was higher for influenza A than influenza B. Notably, the test-and-treat strategy encompassed only a part of the 2019-2020 influenza season. In particular, cases of influenza B predominantly occurred prior to influenza A cases, which is unusual but consistent with other results published for the 2019-2020 influenza season. 11 Thus, the measures of concordance for influenza B may be skewed due to the timeline of when the test-andtreat strategy started. Home influenza test results may have assisted telehealth providers in making an accurate influenza diagnosis. Previous studies have demonstrated that influenza diagnosis based on a provider review of symptoms has low sensitivity 12, 13 ; adding a sensitive home-based test has the potential to significantly improve influenza diagnostic accuracy. A small number of influenza-positive participants received baloxavir, yet our results suggest a home-delivery approach is feasible, particularly because all eight individuals received drug within 48 hours of symptom onset, and 87.5% of home deliveries arrived within 3 hours from the time of prescription. Four influenza-negative individuals received baloxavir therapy, although no adverse effects were observed and no major differences were seen among baloxavirtreated and baloxavir-untreated groups. Our remote approach to home testing and treatment of influenza may be an important future control strategy, particularly during a severe epidemic or pandemic, 14 Further studies are needed to assess the feasibility of this homebased influenza test and rapid home antiviral delivery strategy in larger or more remote populations. The moderate sensitivity of the rapid home influenza test coupled with successful antiviral home delivery suggests that the implementation of intervention or control strategies in households with children could be feasible and may be particularly useful when circumstances dictate restricted movement or social distancing. Further studies on this topic would help to understand the usefulness of these strategies in more remote or diverse populations. While the strategy for early diagnosis and treatment of influenza was studied, it has the potential to be applied to other respiratory viruses that cause epidemics and pandemics as home-based diagnostic and treatment options become available. No material from other sources is included. The findings and conclusions in this report are those of the authors and do not necessarily represent the official position of the Centers for Disease Control and Prevention. The peer review history for this article is available at https://publo ns.com/publo n/10.1111/irv.12859. MLJ has received research support from Sanofi Pasteur. M.B. receives research support and serves as a consultant for Ansun Biopharma, Gilead Sciences, Janssen, and Vir Biotechnology; and serves as a consultant to GlaxoSmithKline, ReViral, ADMA, Pulmocide, and Moderna. All other authors Conceptualization (supporting); Data curation (lead); Formal analysis (lead) Writingoriginal draft (lead) Writing-review & editing (lead) Conceptualization (supporting); Investigation (supporting) Methodology (supporting) Supervision (supporting) Writing-original draft (supporting) Jessica O'Hanlon: Investigation (equal) Ashley E. Kim: Investigation (supporting) Anne Emanuels: Data curation (supporting) Project administration (supporting); Writing-review & editing (supporting). Naomi Wilcox: Data curation (supporting) Resources (supporting) Software (supporting) Validation (supporting) Elisabeth Brandstetter: Conceptualization (supporting) Funding acquisition (supporting) Methodology (supporting); Project administration (supporting) Writing-review & editing (supporting) Resources (equal) Software (supporting) Validation (supporting) Writing-review & editing (supporting). David McCune: Investigation (equal) Resources (equal) Software (supporting) Writing-review & editing (supporting) Investigation (equal) Resources (equal) Software (equal) Writing-review & editing (supporting) Methodology (supporting); Resources (equal) James P. Hughes: Conceptualization (supporting); Formal analysis (supporting) Software (equal) Supervision (equal) Writing-original draft (supporting) Writing-review & editing (supporting). Michael L. Jackson: Conceptualization (supporting) Formal analysis (supporting); Funding acquisition (supporting) Investigation (supporting) Writing-review & editing (supporting). Timothy M. Uyeki: Conceptualization (supporting); Data curation (supporting) Investigation (supporting) Michael Boeckh: Conceptualization (equal); Formal analysis (supporting); Funding acquisition (equal) Supervision (supporting) Writing-review & editing (supporting). Lea M. Starita: Conceptualization (supporting); Data curation (equal); Formal analysis (supporting); Funding acquisition (equal); Investigation (equal) Trevor Bedford: Conceptualization (supporting); Data curation (supporting) Investigation (equal) Resources (equal) Software (equal) Janet A. Englund: Conceptualization (equal); Data curation (supporting) Funding acquisition (equal); Investigation (equal) Resources (equal) Supervision (equal) Writing-original draft (supporting) Conceptualization (lead); Data curation (supporting) Funding acquisition (lead); Investigation (equal) Resources (equal) Supervision (lead) Visualization (equal); Writing-original draft (supporting) Writing-review & editing (supporting) All participants provided informed consent prior to enrollment Efficacy and safety of the oral neuraminidase inhibitor oseltamivir in treating acute influenza: a randomized controlled trial. US Oral Neuraminidase Study Group Oseltamivir treatment for influenza in adults: a meta-analysis of randomised controlled trials Efficacy and safety of oseltamivir in children: systematic review and individual patient data meta-analysis of randomized controlled trials Baloxavir marboxil for uncomplicated influenza in adults and adolescents A bayesian MCMC approach to study transmission of influenza: application to household longitudinal data Risk factors of influenza transmission in households Analysis of influenza transmission in the households of primary and junior high school students during the 2012-2013 influenza season in Odate The seattle flu study: a community-based study of influenza Remote household observation for non-influenza respiratory viral illnesses in Research electronic data capture (REDCap)-a metadata-driven methodology and workflow process for providing translational research informatics support Interim Estimates of 2019-2020 Seasonal Influenza Vaccine Effectiveness-United States Clinical Diagnosis of Influenza in the Emergency Department Performance characteristics of clinical diagnosis, a clinical decision rule, and a rapid influenza test in the detection of influenza infection in a community sample of adults Strategies for pandemic and seasonal influenza vaccination of schoolchildren in the United States A remote household-based approach to influenza self-testing and antiviral treatment The data that support the findings of this study are available from the corresponding author upon reasonable request. List of symptoms used to determine for eligibility for nasal swab collection. Acute cough or two or more concurrent qualifying symptoms was considered an acute illness episode b A qualifying symptom that is sufficient on its own for study eligibility for individuals of any age.c Not a qualifying symptom for study eligibility.d A qualifying symptom for study eligibility for individuals <18 years of age.