key: cord-335265-kuc3v5m9
authors: Elghazawy, Hagar; Bakkach, Joaira; Zaghloul, Mohamed S; Abusanad, Atlal; Hussein, Mariam Mohamed; Alorabi, Mohamed; eldin, Nermean Bahie; Helal, Thanaa; Zaghloul, Tarek M; Venkatesulu, Bhanu Prasad; Elghazaly, Hesham; Al-Sukhun, Sana
title: Implementation of breast cancer continuum of care in low- and middle-income countries during the COVID-19 pandemic
date: 2020-07-27
journal: Future oncology
DOI: 10.2217/fon-2020-0574
sha: 
doc_id: 335265
cord_uid: kuc3v5m9

Breast cancer is the most common malignancy among women worldwide. The current COVID-19 pandemic represents an unprecedented challenge leading to care disruption, which is more severe in low- and middle-income countries (LMIC) due to existing economic obstacles. This review presents the global perspective and preparedness plans for breast cancer continuum of care amid the COVID-19 outbreak and discusses challenges faced by LMIC in implementing these strategies. Prioritization and triage of breast cancer patients in a multidisciplinary team setting are of paramount importance. Deescalation of systemic and radiation therapy can be utilized safely in selected clinical scenarios. The presence of a framework and resource-adapted recommendations exploiting available evidence-based data with judicious personalized use of current resources is essential for breast cancer care in LMIC during the COVID-19 pandemic.

in all COVID-19 patients in China; second, the recent use of anticancer therapies within 14 days of infection (including chemotherapy and radiation) was an independent predictor of death or other severe events with a hazard ratio >4; and third, a high proportion of patients acquired the infection while already in the hospital for cancer treatment (28.6%). Moreover, 19 .5% of those who died from COVID-19 in Italy had active cancer in the last 5 years, as per a report published in March 2020 [18] .

There is still a gap in knowledge of the distribution of histologic subtypes in COVID-19 cancer patients, and the specific risk for BC patients is yet to be clarified. Available data suggest that men are more susceptible to COVID-19 [19] , but women do still become infected; BC patients with multiple risk factors (e.g., diabetes, hypertension, preexisting cardiovascular diseases) are especially vulnerable to the viral infection [14] . The proportion of patients with BC ranged from 8.3% to 29% in published studies [15, 20] . In an Italian series of cancer patients infected with COVID-19 in a 1-month duration, BC patients represented five of 17 patients, of whom two were on chemotherapy, one was on adjuvant endocrine therapy and two patients were on mTOR inhibitors or an anti-Her2 agent in the metastatic setting [20] .

Interestingly, the most prevalent malignancy was BC (21%) in the international COVID-19 and Cancer Consortium registry that collected data on 928 patients with active or previous malignancy who had confirmed COVID-19 infection over a 1-month period [21] . Furthermore, worse outcomes from COVID-19 infection are increasingly being reported in patients with cancer, particularly those with older age, active cancer, metastatic disease or other comorbidities [22] . These data altogether support prompt actions toward protecting BC patients who may have more than one risk factor for COVID-19 infection or complications.

The global recommendations for BC continuum of care during COVID- 19 As the overall pandemic situation continues to evolve, BC oncologists and surgeons are forced toward deferring or deescalation strategies. International communities (e.g., NICE, NCCN, ESMO, ACS, SSO) [23] [24] [25] [26] [27] [28] [29] [30] [31] stress the importance of continuing oncology care, especially in the curative setting, while deferring other measures until the pandemic curve is flattened. Deferring cancer care as an alternative until the end of the pandemic may seriously jeopardize survival and compromise clinical outcomes in the future [30] . The possible medicolegal consequences of delaying treatment without definite widely adopted and documented guidelines add to the challenge.

Adopting the appropriate crisis management plan is of paramount importance. Such a plan should include five main components: leadership and communication, patient management, staff management, infection control and recovery plan. Dealing promptly with these components can result in the prevention of any new infection, with zero in-hospital transmission of the viral infection among oncology patients, not just during the months of the crisis, but over the subsequent years [32, 33] . Highlights of the mandatory measures are illustrated below.

• Clear communication, with written documentation for multidisciplinary team (MDT) discussions (the rationale behind every treatment) and discussion of the risks and benefits of therapy with patients and their relatives, is fundamental [23, 24] ; • Adequate disinfectants must be available at the hospital entrance and the radiotherapy facility [30] .

• Advise cancer patients to use face masks outside their homes, especially in health facilities and if having chest symptoms (cough, sneezing), and employ frequent hand washing protocols [30, 31, 34, 35] ; • Arrange waiting areas to keep a distance of 1-2 m between patients [119] ;

• Use telemedicine and online consultation services if possible [36] ; • Consider calling outpatients by telephone 1 day before their appointments to screen for COVID-19 symptoms and history of contacting COVID-19-positive patients [37] ; • Triage and screen. All patients scheduled for hospital visits should be screened for signs of COVID-19; suspected patients should be isolated, evaluated thoroughly and referred to specialized COVID-19 caring centers [37] ; • 'No visitors' policy unless there is a particular need [37] ; • Consider the COVID-19 screening test for patients who need hospitalization [38] and before every chemotherapy cycle [39] ;

• Consider possible causes other than COVID-19 in patients with new onset of respiratory symptoms [40] , such as influenza, bacterial pneumonia, treatment-related side effects (e.g., atelectasis, pulmonary embolism, pneumonitis) or tumor progression (e.g., lymphangitis carcinomatosis); • Cautiously assess new lung infiltrates on radiographic imaging. It may be difficult to distinguish pneumonitis secondary to antineoplastic agents (e.g., mTOR inhibitors or checkpoint inhibitors) from disease progression or viral infection. In this case, therapy should be withheld until COVID-19 infection is excluded [40] ; • Once the patient is suspected to have COVID-19 based on symptoms or history of contact with a known positive individual, a cancer treatment break is recommended till cleared by a negative test result [39] ; • It is still unknown when cancer treatment can be safely resumed after COVID-19 infection, given the unknown effects of further manipulation of the patient's immune system quickly after the viral infection and the undocumented reinfection rates. Withholding cancer treatment until COVID-19 symptoms have resolved for at least 72 h with a negative viral load test, and considering a second consecutive negative test within 48 h, is the accepted approach by many authors [23, 40, 41] ; • Limit hospital visits for elderly cancer patients unless urgently needed. Higher case fatality rates with increasing age (overall case fatality rate of 2%, rising to 15% for age ≥80 years) and with comorbidities (11% for cardiovascular disease, 7% for diabetes, 6% for chronic respiratory disease) have been reported [42] .

• Healthcare workers are at high risk of being infected with the virus; at least 2629 were infected, of whom 8.3% died, since the onset of the outbreak in Italy [43] ; • Use extensive infection control measures and personal protective equipment when dealing with infected patients [44, 45] ; • Reduce direct communication by using cyberspace capacities to communicate with each other and the patients, and perform virtual MDT meetings [37] ; • Divide BC teams (surgeons, medical and radiation oncologists, technicians) into tandem operation teams (ideally 50% on-site, 50% off-site) to reduce risk of exposure to infection with ideally regular alternation every 2 weeks (to overcome the incubation period of the 14-day half-life of SARS-CoV-2) [30] ; • Supply pathologists who perform fine-needle aspiration of breast lesions with enhanced biosafety precautions (i.e., procedure room with adequate ventilation, hand hygiene, wearing personal protective equipment including surgical mask, eye protection and gown) if possible, because they may be at increased risk for exposure to infected droplets [46] ; • Extend the infusion unit and radiation therapy working hours from early morning to late evening, to accommodate any delayed patients with appropriate distancing and isolation [32] ; • Support the presence of organizations that can provide oncological home care, applying 'double triage' protocol to ensure the continuity of care and protect healthcare professionals from the exposure to infection [47] ; • Allocate older healthcare workers and those with comorbidities to off-site duties, if possible [42] .

Triaging BC patients by MDT is of utmost importance, keeping workload balance between different disciplines [24] . BC patients should be prioritized into three priority levels (1, 2 and 3) according to the urgency of their cancer care [24] [25] [26] [27] [48] [49] [50] :

• Priority 1: patients with immediately life-threatening conditions or symptoms requiring urgent treatment, even if limited resources, with the aim of preservation of life or symptomatic relief; • Priority 2: patients who do not require immediate treatment but should start during the pandemic, providing that a short delay (≤3 months) would not impact the overall outcome. Most BC patients are in this priority group but further stratification is needed; • Priority 3: patients whose treatment can be safely deferred until the pandemic peak ends (delay for more than 3 months) with no substantial impact on the long-term outcome.

Factors that must be taken into consideration when adapting these priority levels are the individual risk of COVID-19 infection according to age and comorbidities, the hospital capacity, the severity of the COVID-19 pandemic in each country, the stage of the malignancy along with its biology and risk of progression affecting the survival [24, 28, 38] .

Screening, imaging & workup Priority 1 • Breast imaging for urgent situations such as acute breast abscess or evaluation of severe postoperative complications [24, 50] ; • BC diagnosis during pregnancy [25] .

• Breast diagnostic imaging for suspicious breast symptoms, biopsies for BIRADS 4-5 (Breast Imaging-Reporting and Data System) lesions and breast MRI for the extent of disease evaluation or prechemotherapy assessment [24, 25, 50] ; • Evaluation of symptomatic metastatic relapse, while metastatic BC patients can be followed clinically (symptomoriented and by examination) [24, 25] .

• Postponing BC screening for the asymptomatic population. It can be rescheduled after the pandemic with no probable adverse impact on survival [24, 25, 37, 41, 50, 51] . However, symptomatic patients need to be referred for evaluation; • Evaluation of BIRADS 3 lesions can be postponed [24, 25, 50] ; • Metastatic workup in early-stage asymptomatic BC patients [24, 25] ; • Bone density evaluation when using aromatase inhibitors [24, 25] .

The uncertainty regarding when the pandemic will end is one of the main challenges of delaying the definitive surgery [38] .

• BC surgery complications (e.g., bleeding, breast abscess) or reconstruction complications, such as ischemia [24] [25] [26] [27] [28] 50 ];

• Patients who completed neoadjuvant chemotherapy-based treatment with accepted delay of surgery (≤8 weeks post-chemotherapy) have no impairment of BC outcomes [24, 27, 28] ; • Upfront surgery is preferred in the following conditions:

• cT1 N0, triple negative BC (TNBC) and HER2-overexpressing (HER2+) patients [26, 27] ;

• Patients who showed tumor progression during neoadjuvant treatment should be referred for surgery if the tumor is resectable [24, [26] [27] [28] ; • Resectable BC categories that receive neoadjuvant therapy according to standard approach (TNBC, HER2+ tumors and ≥cT2 or N+ Estrogen Receptors positive (ER+)/HER2− tumors) can be directed for upfront surgery if the pandemic is not in an escalatory phase with currently available hospital resources that are likely to be occupied in the next weeks/months [26, 28, 50] ; • Immediate reconstruction with implant or tissue expanders can be performed only if hospital resources permit or if toilet mastectomy is required in a fungating tumors to close the skin [24, 50] ; • BC surgery during pregnancy (multidisciplinary treatment should be individualized according to stage and biology) [25, 28] ; • Breast angiosarcoma and malignant phyllodes tumors [27] .

• Low-risk BCs (e.g., stage I-II, ER+/PR+, HER2−, low-grade, low-proliferative index) have lower priority because they can be considered for starting preoperative endocrine therapy and for deferring surgery until it becomes possible [24, 25, 28] . 

• Excision of benign lesions and duct excision (fibroadenomas, atypia, papillomas) [24] [25] [26] [27] 50 ];

• Surgery for ER+ ductal carcinoma in situ (DCIS), considering ER− DCIS as a higher priority for surgery (priority 2) [24, 25, 27, 28] ; • Autologous breast reconstruction surgeries should be deferred [24] [25] [26] [27] ;

• Reexcision surgery [24] [25] [26] [27] ;

• Prophylactic surgery for asymptomatic high-risk patients [24] [25] [26] [27] 50] .

Tailored recommendations for systemic therapy in BC patients during the COVID-19 pandemic according to treatment setting and BC biology are shown in Table 1A & 1B. Priority 1

• Patients with oncological emergencies requiring immediate treatment (e.g., febrile neutropenia, intractable pain, pleural effusion) [24] ; • Neoadjuvant therapy is already considered as the standard of care for non-metastatic ≥ cT2 N0 TNBC, HER2+ BC and inflammatory BC based on the higher rates of clinical and pathological tumor response showing durable tumor control before surgery [24, 25, 28, 50, 52] ; • Standard adjuvant systemic therapy for TNBC and Her2+ BC [24, 25, 28, 50] ; • Continuation of adjuvant capecitabine treatment in TNBC patients and ado-trastuzumab emtansine (T-DM1) in HER2+ BC patients (in case of residual disease in post-neoadjuvant setting) [25, 28] ; • Completion of standard adjuvant endocrine therapy [24, 25, 28, 50] .

• Early introduction of systemic therapy for metastatic BC, more likely to improve outcomes [25, 28] ;

• Patients with ER+, HER2− tumors can defer surgery and receive neoadjuvant endocrine therapy for 6-12 months without clinical compromise [24, 25, 28] .

• Later metastatic lines of therapy less likely to improve outcomes [25, 50] ;

• Anti-resorptive bone-targeted therapy (zoledronic acid and denosumab) could be withheld in the adjuvant and metastatic setting or used with a 3-month interval, except when strictly needed for hypercalcemia [ 

Evidence suggests that COVID-19 is spread by droplets with an incubation period of 1-14 days [48] ; some researchers have raised concerns that SARS-CoV-2 particles might remain viable for up to 72 h, which has implications for most radiation activity and equipment [53] . As long as sufficient protective gear is available, surgical masks should be worn [54] and staff should quickly disinfect after every patient (handwashing, breast boards), without interfering with the planned schedule. When possible, hypofractionated regimens should be strongly considered [24, 28, 48, 50] and care should be taken that BC patients receiving adjuvant radiotherapy (RT) who present with chest symptoms (cough, dyspnea) should be promptly evaluated. Tailored recommendations for RT techniques in BC patients during the COVID-19 pandemic are shown in Table 2 . [24, 50, 81] ; • Invasive disease with low-risk genomic profile: consider omission of WBRT cautiously; trials are ongoing (e.g., LUMINA, IDEA, PRECISION) [48] ; • Boost: omit the boost in invasive disease (except for patient ≤40 years of age or with positive margin) [82] [83] [84] and in situ (except for positive margin and where reexcision is not possible) [24] ; there is no survival benefit except for high-risk disease. If given, the boost should be planned simultaneously or as integrated [62] . • After mastectomy:

• T1-2 N+: consider omission of RT cautiously; trials are ongoing (NSABP B-51, RTOG 1304) [ • Palliation:

• Postoperative for pathological fracture: omit RT as there is limited evidence supporting benefit [85] .

• Currently, there is no evidence to support prophylactic antiviral therapy use for COVID-19 in either the general population or immunosuppressed patients [40, 86] ; • Given the controversial immune-modulatory effect of corticosteroids, their use should be limited, as appropriate.

However, some researchers have reported that corticosteroids might be beneficial if utilized in the early acute phase of infection [25, 87] ; • Despite some reports raising concerns about the influence of NSAIDs [88] and angiotensin-converting enzyme inhibitors [89] on the risk and severity of COVID-19, there is no high-level evidence to support avoiding them. A single study which investigated NSAIDs showed that indomethacin had antiviral activity [90] . Patients already using angiotensin-converting enzyme inhibitors should continue to receive them, as recommended by many societies [91] [92] [93] ; • Prophylaxis against neutropenic fever should be considered at a lower threshold of the expected risk (e.g., >10%), with closer monitoring of neutrophil count for at-risk patients [41] ; • Consider using granulocyte colony-stimulating factor (G-CSF) cautiously. There are limited data implicating G-CSF in accelerating the cytokine storm in COVID-19 patients. This was shown in a case series of three cancer patients on active systemic therapy and infected with SARS-CoV-2 (including one BC patient on chemotherapy). All patients developed rising neutrophil/lymphocyte ratio and suffered respiratory decline at 72 h after G-CSF administration [94] ; • Explain to the patients the common side effects of G-CSF (flu-like symptoms: generalized bone pain, mild fever), to reduce the risks of confusion with COVID-19 symptoms and added stress on the patients and caregivers [37] ; • Patients on chemotherapy presenting with fever (+/-respiratory symptoms) should be managed immediately as having neutropenic fever, because it is life-threatening, in parallel with suspecting COVID-19 as appropriate [23] ; • Strongly consider empiric oral antibiotics for patients with neutropenic fever who are clinically stable [41] ; • Consider extra support for the patients' mental health, due to the added stress, anxiety and social isolation measures resulting from the COVID-19 pandemic that may overwhelm cancer patients already loaded by psychological stress from cancer management [40] .

Postpone any clinic visit that can be deferred without risk for the patient's clinical outcome, including surveillance after completing the adjuvant chemotherapy, endocrine therapy, or follow-up of asymptomatic metastatic patients [40, 41] .

Continuation of treatment in the context of a clinical trial should be individualized provided that the benefits to the patient outweigh the risks, with a possible adaptation of procedures if this can be done without affecting patient safety and study conduct [25] . Unfortunately, the COVID-19 pandemic consequences have not only changed patients' treatment plans and the pace of clinical trials but also affected the whole oncology community, limiting traveling, causing conference cancellations and hindering opportunities for research and education collaboration [38, 95] . Thus every effort to enhance online meetings, teleconferences and updating the BC team regarding COVID-19 or BC news should be encouraged.

Several published data have suggested that patients with comorbidities, including cancer, are at higher risk of complications and death from COVID-19 [3, [15] [16] [17] [18] . As a result and in an unfortunate attempt to prevent overwhelming healthcare systems, cancer patients may be assigned 'do not resuscitate' orders by default [96] . Such an approach is not justified even in the context of limited resources. Each cancer patient has an individual risk determined by the malignancy stage, biology, prognosis and the patient's values, and all these factors have to be integrated to make the appropriate decision. Therefore an updated advance directives discussion that balances the benefits and risks of invasive and intensive care in case of infection is essential. Preferably, it should be conducted by the treating oncology team to avoid under or over treatment [97] . On the other hand, family members in LMIC often have a more active role in the patient's management plan and treatment decisions than the patient herself, which complicates the informed consent process and the concept of autonomy [98] .

An interplay of several factors will determine the speed of spread of the COVID-19 pandemic, its doubling time and long-term duration. These factors include the mean duration of infectivity of a person, the isolation measures and lockdown status of affected countries, and emerging immunity [99, 100] . At this moment, it cannot be predicted when the COVID-19 outbreak will end. However, based on evidence from previous pandemics, complete eradication of a pathogen after its emergence is rarely achieved and further waves of the disease are seen [99] . The process of approving a vaccine or effective antiviral therapy will take time (at least 12-18 months), so it is unlikely to be available soon [100] . Modeling studies predict that the COVID-19 pandemic may take months to peak, indicating that healthcare systems may remain under strain for many months [101] . Therefore planning for the care of patients with cancer in the era of COVID-19 should be a priority.

The impact of the outbreak on oncology services varies across different countries, depending on the local situation of health systems and their adopted measures to withstand the pandemic. In Italy, despite its status as a HIC, all healthcare systems and cancer patients were faced with drastic changes in the organizational processes once the government extended the 'red zone' to the whole nation [31] . Likewise, African oncology professionals (where African countries are LMIC, except one [8] ) face the challenge of protecting patients and the workforce against infection, with more critical decisions needed to decrease the negative impact of the crisis on patients' outcomes [102] . Their challenge is exacerbated by having more locally advanced diseases, limited resources to support COVID-19 infection control and logistic issues [103] .

Another critical point is that symptoms of COVID-19 infection (fever, cough, fatigue, shortness of breath, muscle pain, headache, chest pain and diarrhea) largely overlap with symptoms seen after chemotherapy or targeted therapy. Thus the COVID-19 pandemic has added extra challenges to oncologists' daily clinical decisions [19] because they need more workforce and time to evaluate individual patients' symptoms adequately.

During this crisis, BC care delivery poses a major challenge for patients from the perspective of weighing the competing risks of death from BC versus their vulnerability for COVID-19 infection as immuno-compromised patients. Evidence shows that postponing treatment adversely affects cancer care outcomes; in one study, a 4week delay in the adjuvant chemotherapy for BC was associated with inferior survival, especially for TNBC [104] . Another study including 11,175 BC patients evaluated the impact of delayed treatment on survival, with a median follow-up of 7.9 years. Delayed first treatment (>90 vs ≤30 days post diagnosis) was associated with worse overall survival in patients with non-metastatic BC (hazard ratio: 2.25) and metastatic BC (hazard ratio: 2). Moreover, delayed adjuvant treatment (>90 vs 31-60 days post surgery) was associated with worse survival in patients with non-metastatic BC (hazard ratio: 1.50) [105] . Delay in treatment can be acceptable in HIC, albeit reluctantly, but is not accepted in LMIC given the risk of progression in BC cases that are already in the advanced stages at presentation (60-80% of cases in LMIC) [106] , coupled with the limited treatment capacities in LMIC [107] . The advanced stages of BC demand more resources for management than earlier stages, including radiotherapy equipment, more lines of systemic therapy, more clinic visits, palliative care services and psychological support. Compounding the problem in LMIC is the younger age of BC presentation than in HIC, with resultant poorer prognosis, which has ramifications on social and fertility aspects [106] .

All the above factors -including the uncertainty of the pandemic's duration, the strain on resources during the pandemic and the impact of BC treatment delay on survival, along with the known BC situation in LMICmandate the implementation of resource-stratified guidelines as previously suggested by Breast Global Health Initiative [7] . Core, limited and enhanced levels of service should be appropriately contextualized or adapted [108] , to match the resources of every country. LMIC can mitigate the drastic effects of the pandemic on the survival and oncological outcomes of BC patients by using this stepwise approach. On the other hand, scarce resources during a pandemic should be allocated respecting the four fundamental ethical values proposed by Emanuel et al. [109] . These values are: maximizing benefits, treating people equally, providing instrumental value (priority to those who save others) and giving priority to the worst off (giving priority either to the sickest or to younger patients who will have lived the shortest lives if they die untreated). Clinicians should be mindful of misusing age as an arbitrary criterion, disfavoring elderly patients with COVID-19 in resource allocation decisions where there is healthcare shortage. According to the American Geriatrics Society, factors that are predictive of mortality include frailty and severe comorbidities (likely to result in death over a short period of time, such as <6 months), rather than chronological age alone [110] .

Not all the recommended measures to face the COVID-19 pandemic globally place extra demands on LMIC. Wearing cloth masks in public and saving surgical masks to be used within the health facilities [39, 40] is considered convenient to LMIC. Also, educational materials and programs directed to cancer patients, promoting proper hygiene and infection prevention measures, are feasible.

The financial toxicity of cancer treatments is a recognized issue globally. However, LMIC can overcome the unaffordability of some costly cancer therapies with limited access by enhancing the availability of biosimilars [111] . Trastuzumab plays a pivotal role in BC treatment in both early and metastatic stages. In 2019, WHO included the biosimilars of trastuzumab in its essential medicines list, integrating the previous inclusion of the biosimilars of erythropoietin agents and filgrastim [112] . Currently, there are six approved trastuzumab biosimilars, which have shown equivalent efficacy to trastuzumab [113] . The wide distribution and utilization of such biosimilars in LMIC should be encouraged and not misperceived as merely cheaper options for poorer countries [111] .

The distribution of radiotherapy facilities in Africa and Latin America is poor. In Africa, one unit treats approximately 2.47 million patients in LMIC, compared to 0.8 million patients in upper middle-income countries and about 29 countries in these regions lack radiotherapy units altogether [8, 114] . This mandates governmental and policymakers' concerted efforts in planning for the long term.

Uncertainty surrounds the future of the COVID-19 pandemic. Several speculations have emerged, including the possibility of manifesting second and third waves, complete eradication with vaccination, diminished viral virulence and the development of herd immunity [99, 100, 115] . Evidence is still evolving around these theories without a solid conclusion, and several vaccine trials are ongoing [100] . The future course of the pandemic will be revealed as time passes. Until then, important lessons must be learnt, to prepare for any next pandemic or events that may lead to cancer care disruption.

Quality cancer care is often inaccessible, not only in LMIC but also in rural or remote areas of HIC [116] . Measures that support remote access to cancer care, such as virtual clinics and online ordering of medication refills with off-campus means of delivery, have to be integrated into the care delivery model. The use of teleoncology has to be expanded in LMIC, and other applications of medical telecommunications -including pathology, radiology and virtual MDT -have to be utilized to enhance the quality of clinical cancer care [117] . Improving local internet services to cope with the increased utilization of telehealth is also important. Likewise, oncology education and knowledge dissemination can be continued virtually. Recognized annual oncology conferences like ASCO, ESMO breast, and AACR have been conducted virtually, with massive online attendance. Such an occasion gave a more accessible and feasible way to attend major conferences without increasing expenses and travel burdens. This has to continue to boost the participation of oncology professionals from LMIC, even after the pandemic resolves.

Many cancer patients have faced delays in diagnosis and treatment, while some have received alternative treatments instead of the guideline standards. The outcomes for those with such interruption and modification have to be addressed scientifically. Closer monitoring and earlier intervention may balance the consequences of the deviation from the standards of care during the pandemic. Funding and resource allocation for scientific research to address this issue is recommended in the future. We encourage international and local cancer societies to endorse specific guidelines for cancer treatment in times of crisis or disaster such as the COVID-19 pandemic, to be updated periodically, with the training of medical staff on such situations to be ready for the future.

Although strained resources are a common challenge in LMIC and are further stressed by the pandemic situation, there will be a better understanding of the prioritization of cancer treatment and better allocation of the available healthcare resources, especially in LMIC. Future strategic plans to reduce redundancy and bureaucracy in healthcare systems are highly needed. The need to develop resilience and flexibility to adapt alternative strategies is a lesson that should have been learnt from the pandemic situation, motivating the development of future plans to face the upcoming challenges, whether related to this pandemic or different ones.

Moreover, the current pandemic has further highlighted the urgent need to create an advance directive with establishing triage committees. Advance care and planning discussions should occur before patients are in crisis, with the aim of identifying people who do not wish to receive intensive care, including mechanical ventilation [110] .

Finally, detailed BC registries are of ultimate importance to assess every country's disease burden, which will guide disease prioritization and allocation of resources for BC care [118] , along with longitudinal registries for BC patients to capture COVID-19 infection behavior.

The present review aims to assist BC oncology professionals and stakeholders in LMIC by using compiled data to generate a framework matching the local resources and needs. Applying MDTs to prioritize BC patients efficiently and discuss individual patients' management plans is recommended. Also, individual LMIC should provide specific resource-stratified guidelines and recommendations for the ethical dilemmas that can be faced while treating BC patients infected with COVID-19, based on local cultural, legal and religious backgrounds.

We highlight the importance of directing focused efforts and financial support for implementing resource-stratified guidelines to plan BC care in LMIC during the COVID-19 pandemic. Deliberate attention should be given to BC patients, especially those with comorbidities or metastatic disease and those receiving active treatment.

• The world has been facing unprecedented healthcare challenges caused by COVID-19, which are more aggravated in low-and middle-income countries (LMIC). • Breast cancer (BC) in LMIC is characterized by late presentation, worse survival and younger age groups, along with limited resources obscuring the delivery of quality cancer care. • During this crisis, BC care delivery poses a major challenge for patients from the perspective of weighing the competing risks of death from BC versus their vulnerability for COVID-19 infection as immuno-compromised patients.

• Accumulating evidence shows that cancer patients, particularly those with older age, active cancer, metastatic disease and those with other comorbidities, are at higher risk of infection and worse outcome of COVID-19.

• Adopting the appropriate crisis management plan can result in the prevention of any new infection, with zero in-hospital transmission of the viral infection among oncology patients, not just during the months of the crisis. Triage & prioritization • Triaging BC patients by MDT is of utmost importance, keeping workload balanced between different disciplines.

• BC patients should be prioritized into three priority levels (1, 2 and 3) according to the urgency of BC care.

• Deescalation of systemic and radiation therapy can be utilized safely in selected clinical BC scenarios.

• An advance directives discussion that balances benefits versus risk of invasive and intensive care in the case of infection is essential. • It cannot be predicted when the COVID-19 outbreak will end. However, other waves of the disease are expected, which complicates the clinical decisions required for BC care.

• The BC continuum of care in LMIC during the pandemic mandates the implementation of resource-stratified guidelines as previously suggested by Breast Global Health Initiative. • Core, limited and enhanced levels of service should be appropriately contextualized or adapted to match the resources of every country, to mitigate the drastic effects of COVID-19 on the oncological outcomes of BC. • Integrating telecommunications to allow timely access to cancer care and establishing the required infrastructures are fundamental prerequisites during the pandemic. • Continuing virtual oncology education and sharing knowledge through online participation in major oncology congresses will boost the participation of oncology professionals from LMIC, even after the pandemic resolves. • Funding for scientific research to identify the future consequences of the pandemic on cancer care in general, and breast cancer specifically, are highly recommended. 

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COVID-19 Patient Care Information

Cancer, COVID-19 and the precautionary principle: prioritizing treatment during a global pandemic

When health professionals look death in the eye: the mental health of professionals who deal daily with the 2019 coronavirus outbreak

At the epicenter of the Covid-19 pandemic and humanitarian crises in Italy: changing perspectives on preparation and mitigation

Substantial undocumented infection facilitates the rapid dissemination of novel coronavirus (SARS-CoV2)

Biosafety in the preparation and processing of cytology specimens with potential coronavirus (COVID-19) infection: perspectives from Taiwan: cytopathological biosafety of COVID-19

Home care for cancer patients during COVID-19 pandemic: the double triage protocol

COVID-19: global radiation oncology's targeted response for pandemic preparedness

NHS Clinical guide for the management of non coronavirus patients requiring acute treatment

American College of Surgeons. Recommendations for Prioritization, Treatment and Triage of Breast Cancer Patients During the COVID-19 Pandemic: Executive Summary

ASBrS and ACR Joint Statement on Breast Screening Exams During the COVID-19 Pandemic

COVID-19: Elective Case Triage Guidelines for Surgical Care

Aerosol and surface stability of SARS-CoV-2 as compared with SARS-CoV-1. N. Eng

World Health Organization (WHO), Technical guidance on COVID-19

Accelerated partial breast irradiation using intensity-modulated radiotherapy versus whole breast irradiation: 5-year survival analysis of a phase 3 randomised controlled trial

Reduced mortality with partial-breast irradiation for early breast cancer: a meta-analysis of randomized trials

Acute skin toxicity associated with a 1-week schedule of whole breast radiotherapy compared with a standard 3-week regimen delivered in the UK FAST-Forward Trial

First results of the randomised UK FAST Trial of radiotherapy hypofractionation for treatment of early breast cancer (CRUKE/04/015)

FAST Phase III RCT of Radiotherapy Hypofractionation for Treatment of Early Breast Cancer: 10-Year Results (CRUKE/04/015)

Long-term primary results of accelerated partial breast irradiation after breast-conserving surgery for early-stage breast cancer: a randomised, phase 3, equivalence trial

Risk-adapted targeted intraoperative radiotherapy versus whole-breast radiotherapy for breast cancer: 5-year results for local control and overall survival from the TARGIT-A randomised trial

International guidelines on radiation therapy for breast cancer during the COVID-19 pandemic

The UK Standardisation of Breast Radiotherapy (START) trials of radiotherapy hypofractionation for treatment of early breast cancer: 10-year follow-up results of two randomised controlled trials

Long-term results of hypofractionated radiation therapy for breast cancer

OC-0595: FAST-Forward phase 3 RCT of 1-week hypofractionated breast radiotherapy:3-year normal tissue effects

Development of postoperative radiotherapy for breast cancer: UK consensus statements -a model of patient, clinical and commissioner engagement?

Hypofractionated versus conventional fractionated postmastectomy radiotherapy for patients with high-risk breast cancer: a randomised, non-inferiority, open-label, phase 3 trial

Adjuvant radiotherapy and chemotherapy in node-positive premenopausal women with breast cancer

The UK HeartSpare Study (Stage II): multicentre evaluation of a voluntary breath-hold technique in patients receiving breast radiotherapy

Dexamethasone and supportive care with or without whole brain radiotherapy in treating patients with non-small cell lung cancer with brain metastases unsuitable for resection or stereotactic radiotherapy (QUARTZ): results from a phase 3, non-inferiority, randomised trial

The palliation of brain metastases: final results of the first two studies by the radiation therapy oncology group

Single vs multiple fraction palliative radiation therapy for bone metastases: cumulative meta-analysis

Effect of single-fraction vs multifraction radiotherapy on ambulatory status among patients with spinal canal compression from metastatic cancer: The SCORAD randomized clinical trial

Non-inferiority randomised phase 3 trial comparing two radiation schedules (single vs. five fractions) in malignant spinal cord compression

Palliative radiotherapy trials for bone metastases: a systematic review

Symptom palliation of hypofractionated radiotherapy for patients with incurable inflammatory breast cancer

Clinical impact of adjuvant radiation therapy delay after neoadjuvant chemotherapy in locally advanced breast cancer

Intervals longer than 20 weeks from breast-conserving surgery to radiation therapy are associated with inferior outcome for women with early-stage breast cancer who are not receiving chemotherapy

The benefit of adjuvant radiotherapy after breast conserving surgery in older patients with low risk breast cancer-a meta-analysis of randomized trials

Breast-conserving surgery with or without irradiation in women aged 65 years or older with early breast cancer (PRIME II): a randomised controlled trial

Overview of the randomized trials of radiotherapy in ductal carcinoma in situ of the breast

Impact of pathological characteristics on local relapse after breast-conserving therapy: a subgroup analysis of the EORTC Boost Versus No Boost Trial

The impact of chest wall boost on reconstruction complications and local control in patients treated for breast cancer

Whole-breast irradiation with or without a boost for patients treated with breast-conserving surgery for early breast cancer: 20-year follow-up of a randomised phase 3 trial

Lack of clinical evidence for postoperative radiotherapy after surgical fixation of impending or actual pathologic fractures in the long bones in patients with cancer; a systematic review

Cancer care delivery challenges amidst Coronavirus Disease -19 (COVID-19) outbreak: specific precautions for cancer patients and cancer care providers to prevent spread. Asian Pac

COVID-19 and treatment with NSAIDs and corticosteroids: should we be limiting their use in the clinical setting?

Federal Agency for Medicines and Health Products (FAMHP)

Are patients with hypertension and diabetes mellitus at increased risk for COVID-19 infection?

Indomethacin has a potent antiviral activity against SARS coronavirus

The Renal Association. UK position statement on COVID-19 and ACE Inhibitor/Angiotensin Receptor Blocker use

Position Statement of the ESC Council on Hypertension on ACE-Inhibitors and Angiotensin Receptor Blockers

HFSA/ACC/AHAstatement addresses concerns re: using RAAS antagonists in COVID-19

Granulocyte-colony stimulating factor in COVID-19: is it stimulating more than just the bone marrow?

COVID-19: global consequences for oncology

Coronavirus: GP surgery apology over 'do not resuscitate

The importance of addressing advance care planning and decisions about do-not-resuscitate orders during novel Coronavirus 2019 (COVID-19)

Perspectives from South and east Asia on clinical and research ethics: a literature review

First-wave COVID-19 transmissibility and severity in China outside Hubei after control measures, and second-wave scenario planning: a modelling impact assessment

The SARS-CoV-2 vaccine pipeline: an overview

Report 9: impact of non-pharmaceutical interventions (NPIs) to reduce COVID19 mortality and healthcare demand

Preparedness for COVID-19 in the oncology community in Africa

Breast cancer disparities among women in low-and middle-income countries

Survival and time to initiation of adjuvant chemotherapy among breast cancer patients: a systematic review and meta-analysis

Impact of delayed treatment in women diagnosed with breast cancer: a population-based study

Breast cancer in low-and middle-income countries: an emerging and challenging epidemic

Guideline implementation for breast healthcare in low-income and middle-income countries: overview of the Breast Health Global Initiative Global Summit

To adopt, to adapt, or to contextualise? The big question in clinical practice guideline development

Fair allocation of scarce medical resources in the time of COVID-19

AGS Position Statement: Resource Allocation Strategies and Age-Related Considerations in the COVID-19 Era and Beyond

How can biosimilars change the trajectory of breast cancer therapy?

WHO Technical Report Series The Selection and Use of Essential Medicines. Report of the WHO Expert Committee on Selection and Use of Essential Medicines, 2019 (including the 21st WHO Model List of Essential Medicines and the 7th WHO Model List of Essential Medicines for Children

Biosimilars for breast cancer: a review of HER2-targeted antibodies in the United States

Radiotherapy in Cancer Care: Facing the Global Challenge

Herd immunity: understanding COVID-19

The effects of socioeconomic status on health in rural and urban America

Teleoncology: current and future applications for improving cancer care globally

Breast cancer in low-and middle-income countries: why we need pathology capability to solve this challenge

COVID-19). Prevent getting sick

Implementation of breast cancer care in low-& middle-income countries during the pandemic Review

The authors have no relevant affiliations or financial involvement with any organization or entity with a financial interest in or financial conflict with the subject matter or materials discussed in the manuscript. This includes employment, consultancies, honoraria, stock ownership or options, expert testimony, grants or patents received or pending, or royalties.No writing assistance was utilized in the production of this manuscript.