key: cord-0988363-sgvewlk0 authors: Kow, Chia Siang; Sunter, Wendy; Bain, Amie; Zaidi, Syed Tabish Razi; Hasan, Syed Shahzad title: Management of Outpatient Warfarin Therapy amid COVID-19 Pandemic: A Practical Guide date: 2020-05-26 journal: Am J Cardiovasc Drugs DOI: 10.1007/s40256-020-00415-z sha: 937263ed67e1ec924cbf918d32830d7ae55e53ce doc_id: 988363 cord_uid: sgvewlk0 Many healthcare resources have been and continue to be allocated to the management of patients with COVID-19. Therefore, the ongoing care of patients receiving oral anticoagulation with warfarin is likely to be compromised amid this unprecedented crisis. This article discusses a stepwise algorithm for the management of outpatient warfarin therapy. Alternative management strategies are presented and discussed, including alternative pharmacological therapy options and self-monitoring. Our algorithm aims to help clinicians safely optimize the treatment of patients requiring anticoagulation therapy in the context of the global response to the current pandemic. Novel coronavirus disease 2019 (COVID-19) has become a household name, with over 2.2 million people worldwide testing positive and over 150,000 deaths as of 18 April 2020 [1] . The actual number of reported positive COVID-19 cases may underestimate the true burden because of significant differences in surveillance and diagnostic practices across the world [2] . Even within different parts of Europe, countries have different testing practices, with Germany undertaking widespread COVID-19 testing and the UK prioritizing testing of severe cases requiring hospitalization [3, 4] . While the attention of the medical community is rightly focused on managing patients with COVID-19, the ongoing care of chronically ill patients is likely to be compromised amid this unprecedented crisis. The universally adopted strategy of reducing social interaction to avoid the spread of COVID-19, termed social distancing, has considerable implications for the ongoing care of chronically ill patients [5, 6] . Patients living with diabetes mellitus, cardiovascular diseases, respiratory diseases, and other similar chronic conditions require periodic check-ups to ensure prevention of an acute episode of illness and the effectiveness of therapy [7] . One such patient group is those receiving oral anticoagulation with warfarin as these patients need their international normalized ratio (INR) monitored regularly [8] . Data from clinical trials show that, even in a controlled trial environment with adequate monitoring and followups and dedicated research nurses, the time in therapeutic range (TTR) values achieved were only 55-64% [9, 10] . In addition, a large retrospective cohort study of over 50,000 patients with atrial fibrillation receiving warfarin showed that only 40,570 patients had sufficient INR results to assess TTR and less than half (41%) of these patients had a TTR ≥ 65% [11] . As such, providing adequate monitoring of warfarin amid the worsening COVID-19 pandemic, where social distancing is increasingly emphasized, is an unprecedented challenge faced by anticoagulant service providers around the globe. The discussion that follows aims to facilitate the management of outpatient warfarin therapy by anticoagulation service providers amid the COVID-19 pandemic. A stepwise algorithm for the management of outpatient warfarin therapy is proposed ( Fig. 1) , which complements the following discussion. A comparison of different anticoagulant strategies is depicted in Table 1 . Warfarin is primarily initiated during hospital admission, and patients are referred to primary care for continuation and monitoring. Regardless of the setting in which warfarin is first initiated, clinicians need to assess (or reassess) the indication for warfarin as outpatient therapy. Conditions necessitating warfarin therapy include atrial fibrillation [12] , cardioembolic ischemic stroke [13] , prosthetic heart valve [14] , venous thromboembolism (deep vein thrombosis [15] and pulmonary embolism [16] ), and antiphospholipid antibody syndrome [17] . Some of these indications, such as ischemic stroke and prosthetic heart valve, require lifelong anticoagulation treatment, whereas indications such as deep vein thrombosis and pulmonary embolism may not require indefinite anticoagulation and patients should undergo careful re-evaluation of their need for ongoing warfarin therapy. Patients with prior deep vein thrombosis or pulmonary embolism who have completed 3-6 months of warfarin therapy may be considered for cessation of treatment where appropriate. Continuing anticoagulation beyond 3-6 months is not routinely considered in patients with a provoked episode of venous thromboembolism with transient risk factors (assuming the risk factor is no longer present), isolated distal deep vein thrombosis, subsegmental or incidental pulmonary embolism, or a high risk of bleeding [18] . Patients who continue warfarin therapy indefinitely for secondary prophylaxis of venous thromboembolism require reassessment of bleeding risk, since a high/very high bleeding risk may outweigh the benefits of reducing the risk of recurrence of venous thromboembolism event with warfarin therapy. Therefore, warfarin therapy may no longer be appropriate (however, re-initiation of anticoagulation may be needed once the bleeding risk becomes reasonable) [19] . Patients with atrial fibrillation for whom sinus rhythm has been restored, either spontaneously or deliberately, also require assessment of their ongoing need for warfarin therapy. Warfarin therapy is indicated up to 4 weeks after the restoration of sinus rhythm because of the high likelihood of recurrence of atrial fibrillation in the first month after reversion to sinus rhythm and the risk of transient post-cardioversion atrial stunning in the immediate peri-cardioversion period. However, continuation of long-term warfarin therapy 4 weeks post-restoration of sinus rhythm should be guided by the CHA 2 DS 2 -VASc or CHADS 2 score and consideration of the long-term bleeding risk using the HAS-BLED score [20] [21] [22] . In patients for whom warfarin therapy is appropriately indicated and the need for warfarin is ongoing, a switch to direct oral anticoagulants (DOACs), including dabigatran, rivaroxaban, apixaban, and edoxaban, should be considered. While DOACs do require periodic renal function monitoring throughout the treatment course (at least annually or when clinically indicated), monitoring is predictable and less rigorous than the INR testing required for warfarin therapy so offers convenience for both clinicians and patients amid the COVID-19 pandemic [23] . Moreover, important additional advantages of the DOACs include the lack of susceptibility to dietary interactions and markedly reduced susceptibility to drug interactions, which somewhat alleviates the need for the intensive in-clinic patient counseling required during initiation and maintenance of warfarin therapy. Anticoagulation with each of the DOACs (dabigatran, rivaroxaban, apixaban, and edoxaban) has led to similar or lower rates of both ischemic stroke and major bleeding compared with adjusted-dose warfarin (INR 2.0-3.0) in patients with nonvalvular atrial fibrillation in large randomized trials [24] . In addition, large randomized trials and meta-analyses have reported the safety and efficacy of these agents for the treatment and prevention of recurrent deep vein thrombosis and/or pulmonary embolism. Most of these trials were designed as noninferiority trials comparing DOACs and standard anticoagulation (i.e., heparin followed by warfarin) and showed comparable safety and efficacy [25] [26] [27] [28] [29] [30] [31] [32] . However, DOACs are contraindicated in patients with a prosthetic mechanical valve because of the greater risk of potentially fatal valve thrombosis [33, 34] . In addition, a switch to DOACs may be inappropriate in the following clinical situations that lack evidence or clinical experience: patients with moderate to severe mitral stenosis; antiphospholipid antibody syndrome; pregnancy, breastfeeding, or planning a pregnancy; a target INR higher than the standard range of 2.0-3.0; severe renal impairment (creatinine clearance < 15 ml/min); severe hepatic impairment; active malignancy/chemotherapy; extreme obesity (body mass index > 40 kg/m 2 or body weight > 120 kg); or concurrent interacting drugs [33] . To further illustrate, DOACs are not used in patients with significant mitral valve disease because they were excluded from the clinical trials of these newer agents so further study is needed to determine the safety and efficacy of DOAC in this setting. A review of currently available data provided reassurance for the use of DOACs in patients with a body mass index ≤ 40 kg/m 2 or body weight ≤ 120 kg, but whether clinically adequate drug concentrations can be attained with standard dosing of DOACs beyond these weight parameters remains to be determined [35] . Patient-specific circumstances such as issues of affordability may also affect the uptake of DOACs, since warfarin therapy is much cheaper than DOACs. Nevertheless, generic dabigatran is available in several countries following the expiry of dabigatran's patent protection. Also, nonadherent patients are unsuitable candidates for DOACs as the short half-lives of DOACs can easily leave the patient inadequately anticoagulated compared with warfarin therapy, and cost issues. c Only for patients with venous thromboembolism. Consider personal preference, renal function, suitability for injection, and cost issues. d Consider suitability for self-managed and/or self-monitored INR, a requirement for training prior to self-managed and/or self-monitored INR, local resources, and cost issues a lack of routine monitoring means assessing adherence can be difficult [36, 37] . The product-specific package inserts for warfarin and DOACs differ slightly, but generally we think it is reasonable to discontinue warfarin and initiate any of the DOACs immediately when the INR is ≤ 2.0 [38] . However, some sources maintain that, when switching from warfarin to DOACs, rivaroxaban and edoxaban can be initiated when INR is < 3.0 and < 2.5, respectively, upon discontinuation of warfarin [39] . Another alternative would be to start the DOAC immediately or, ideally, the next day when the INR is 2.0-2.5 [40] . However, we would emphasize that patients should only be switched from warfarin to a DOAC by clinicians with experience in managing anticoagulation. In some settings, especially those with low resources, the supply of DOACs would be limited amid the COVID-19 pandemic. Therefore, we recommend prioritizing patients with poor control of INR, as this cohort will likely require more frequent INR checks (and so more frequent healthcare contact) to stabilize anticoagulation control. For patients with venous thromboembolism with adequate renal function but in whom DOACs are contraindicated or where evidence for the use of DOACs is not established, and INR monitoring with warfarin therapy is unpractical due to COVID-19-related movement restrictions, lowmolecular-weight heparins (LMWHs) or fondaparinux are the only alternative measure. Commercially available LMWHs include enoxaparin, dalteparin, tinzaparin, bemiparin, and nadroparin. LMWHs and fondaparinux have a better correlation between dose and anticoagulant response, permitting administration of a fixed weightbased dose without close laboratory monitoring [41] . Though the need for daily subcutaneous injections may make them an undesirable option from the patient's perspective, adequate counseling and appropriate training for patients or caregivers on the correct injection technique may overcome the initial anxiety. Patients or their caregivers should be able to demonstrate the correct injecting technique after receiving appropriate training. Pharmacists involved in dispensing LMWHs should particularly ensure the most appropriate syringe size is selected for the patient, and each patient should be provided with sharps containers for the correct disposal of used syringes. Fondaparinux is supplied in prefilled syringes, so selection of syringe size is not an issue, but patients should still be provided with sharps containers. LMWHs and fondaparinux can be administered subcutaneously in weight-based dosing for the treatment of porcine-derived heparin may be a concern for Muslim patients; 1-month supply is difficult to handle Fondaparinux: lack of clinical experience in breastfeeding patients venous thromboembolism [15, 18, 42] , including patients with concomitant cancer [43] requiring full anticoagulation for ≥ 3 months. Prescribing clinicians must assess complete blood count and renal function (and serum potassium for LMWHs) before initiating LMWHs or fondaparinux and during therapy when clinically indicated. Patients should also be weighed at treatment initiation to calculate the correct dose. Nevertheless, data are sparse on whether patients with extreme obesity should be given weight-based or fixed LMWH doses, but pharmacodynamic data in patients weighing > 100 kg suggest that patients weighing ≤ 160 kg may receive a full calculated weight-based dose of LMWHs [44] . Conversely, the anticoagulation effect of fondaparinux is uncertain in patients with body mass index > 35 kg/m 2 [45] . Beyond these weight parameters, patients should be maintained on warfarin as their anti-Xa levels should be closely monitored to ensure effective anticoagulation, which renders the reason for switching to LMWHs or fondaparinux redundant [44] . Patients receiving LMWHs should receive appropriate education and counseling to ensure they are aware of the early symptoms of thrombocytopenia (unexplained thrombosis, necrotic skin lesions at injection sites) because LMWHs are infrequently associated with heparin-induced thrombocytopenia, with a meta-analysis reporting a rate of 1.2% in patients with venous thromboembolism [46] . Similar to DOACs, some considerations to be considered in the decision-making process is that maintaining patients on LMWHs or fondaparinux costs more than maintaining patients on warfarin (per unit price: fondaparinux > enoxaparin > warfarin), and supply of these parenteral anticoagulants may be limited during the COVID-19 pandemic, thus necessitating patient prioritization criteria. Self-management and/or self-monitoring of INR among patients with warfarin therapy who could not be switched to either a DOAC or LMWH could be promoted to ease the INR monitoring workload across the healthcare system and to observe social distancing or lockdown amid the COVID-19 pandemic. Self-management involves patients self-testing their INR, with subsequent dose adjustment/ maintenance according to a predetermined dose-INR schedule. Self-monitoring requires patients to call their respective clinic for appropriate dose adjustment or maintenance advice after INR self-testing. These self-management approaches could be particularly useful in residential aged-care facilities or nursing homes in which several patients may require INR testing. Barriers to INR testing in these settings, such as difficulties in having pathology providers visit were noted even before the COVID-19 pandemic [47] . Many patients residing in aged-care facilities who are prescribed warfarin spend a considerable proportion of their time outside of the therapeutic range [48] . Small portable devices or coagulometers are available for patients to self-test their INR. When accompanied by appropriate education and training, along with consistent quality control, most patients, including older adults, can effectively and safely adjust their anticoagulant dosing [49] [50] [51] [52] [53] [54] [55] [56] . The INR values obtained with these devices generally correlate well with laboratory measurements [57] . A 2016 review of randomized controlled trials comparing the effects and the clinical outcomes of self-monitoring or self-management of INR with standard monitoring and care, including personal physicians and anticoagulation hospitals or clinics, reported that self-testing and self-management of INR for patients receiving vitamin K antagonists (VKA) are valuable and effective strategies for INR control [58] . Despite an unclear relationship between INR control and clinical effects, these self-management strategies provide better control of the anticoagulant effect, improve the quality of life for patients and their families, and represent an appealing solution in terms of cost effectiveness. A 2016 meta-analysis of randomized trials compared the clinical outcomes of standard INR monitoring to self-monitoring and/or self-management in 8950 individuals [59] . Compared with standard monitoring, those who used selfmonitoring and/or self-adjusted dosing had the following clinical outcomes over a follow-up period of 3-57 months: significantly fewer thromboembolic events (relative risk [RR] 0.58; 95% confidence interval [CI] 0.45-0.75), no difference in major or minor bleeding events (RR 0.95; 95% CI 0.8-1.12 and RR 0.97; 95% CI 0.67-1.41, respectively), and a nonsignificant trend toward reduced mortality (RR 0.85; 95% CI 0.71-1.01). Similarly, the burden on domiciliary pathology services could be eased amid the COVID-19 pandemic if all patients requiring warfarin therapy in a particular aged-care facility could self-monitor their INRs with the assistance of nursing staff who could also record their INR values and adjust the warfarin dose upon communication with the physician, electronically or according to a predetermined dose-INR schedule. A proof-of-concept study that implemented aged-care facility-based INR testing with electronic communication to general practitioners among residents receiving warfarin in Australia noted improved anticoagulation control for most of the residents receiving warfarin and general satisfaction from the general practitioners, nursing staff, and patients [60] . Careful selection of patients suitable for self-management and/or self-monitoring by clinicians is of utmost importance to avoid therapeutic misadventure. Such patients or caregivers should be sufficiently orientated and have the mental capacity to deal with self-management approaches, have the manual dexterity and physical ability to operate the coagulometer and components, have eyesight adequate to see the display screen, be contactable by phone and/or email, as preferred, and be adherent to anticoagulant therapy [61] . Before patients or their caregivers commence self-management and/or self-monitoring of INR, the anticoagulant service provider must first ensure they receive counseling to ensure an acceptable basic knowledge of warfarin, are trained in the use of the coagulometer, and are deemed competent by the trainer [62] . At initiation of self-INR testing, a venous sample or a professional point-of-care coagulometer should be used to compare results from the patient's coagulometer for at least the first two weekly INR readings to ensure the accuracy and reliability of results and allow an assessment of the patient's ability to self-monitor. While we foresee challenges in terms of training patients and undertaking quality assurance checks, in addition to purchasing equipment and providing test strips, INR self-monitoring should be considered for patients/caregivers who are capable of undergoing the required tasks to minimize INR monitoring workload across the healthcare system amid the COVID-19 pandemic. The usual in-clinic monitoring of INR should be maintained for patients unable to self-monitor INR to avoid compromising the quality and safety of warfarin therapy. Outpatient INR monitoring may be performed at a laboratory or with a point-of-care device [63] . Patients initiating warfarin therapy require frequent measurements (at least two to three times per week) in accordance with institutional protocols [64] . In addition, patients with an INR value outside the therapeutic range or with frequent dose adjustments or changes in clinical status require more frequent monitoring until the dose can be stabilized (at least once weekly) [65] . Once the anticoagulant effect and dose requirements of warfarin have been stabilized for at least 1-2 weeks, the INR can be monitored less frequently, at intervals in the range of every 2-4 weeks [64, 65] . However, there may be a subpopulation of patients in whom the interval between INR testing can be further extended. Thrombosis UK guidelines suggest extending the interval between INR testing to ≥ 8 weeks in patients whose anticoagulation is stable on warfarin with a TTR of > 60% and to 10 weeks in patients achieving a TTR of > 80% [66] . Generally, the major guidelines recommend that the interval between INR testing should not extend beyond 12 weeks, but flexibility could be allowed to monitor less frequently than every 12 weeks in the most stable patients, similar to those in clinical trial populations, during the COVID-19 pandemic, especially for patients in self-isolation because of possible COVID-19 exposure [67] [68] [69] . However, INR testing intervals should be extended cautiously in carefully selected patients because a prospective study reported that a large proportion of patients with previously stable INRs were unable to maintain stable INRs during extended-interval follow-up (every 12 weeks) [70] . Several strategies can be employed amid the COVID-19 pandemic to minimize contact time with patients requiring INR monitoring and to ease the burden on the healthcare system that may be congested with patients with COVID-19. Patients who have COVID-19 symptoms before or upon arrival should be advised not to attend for monitoring. In addition, a drive-through INR testing model may be possible, but the efficacy of this model is yet to be investigated. On the other hand, provision of point-of-care INR testing devices to anticoagulation service providers to facilitate point-of-care testing may reduce workload, for example, by reducing the need to transport blood samples to laboratories. Nevertheless, they should be adequately protected by personal protective equipment (e.g., face masks, gowns, gloves), with workstations disinfected after every patient. Patients newly initiated or established on long-term warfarin therapy should first undergo assessment of the ongoing need for warfarin therapy and discontinue if warfarin therapy is otherwise not or no longer indicated. Patients for whom warfarin therapy is indicated may attempt a switch to a DOAC in the absence of contraindications to DOACs and patient-specific circumstances precluding their use. LMWHs and fondaparinux are alternatives if a switch to DOACs is not possible. Self-management and/or self-monitoring of INR should be offered to patients receiving warfarin therapy where both DOACs and LMWHs/fondaparinux are not appropriate or inaccessible. Lastly, patients receiving warfarin who are unable to perform self-monitoring of INR should undergo the usual in-clinic INR monitoring, with consideration of extending the interval between INR testing among suitable patients. For patients being switched to a new anticoagulant or who will be undergoing self-monitoring of INR, standard therapeutic patient education should be provided, and consideration can be given to tele-education amid the COVID-19 pandemic if local resources are available and patients are receptive to such communication method. The need to observe social distancing or lockdown rules should not affect the quality and safety of anticoagulant therapy. Therefore, we strongly urge clinicians to ensure patients receiving warfarin therapy are appropriately managed despite the COVID-19 crisis. Hospital admission because of major bleeding or thromboembolic events due to warfarin mismanagement would expose patients to additional healthcare interventions and increase their potential for acquiring COVID-19. Funding No external funding was used in the preparation of this manuscript. Conflict of interest Chia Siang Kow, Wendy Sunter, Amie Bain, Syed Tabish Razi Zaidi, and Syed Shahzad Hasan declare that they have no potential conflicts of interest that might be relevant to the contents of this manuscript. An interactive web-based dashboard to track COVID-19 in real-time COVID-19: lessons from SARS and MERS Coronavirus: What can the UK learn from Germany on testing? BBC News Guidance -Priorities for SARS-CoV-2 (COVID-19) testing The effect of control strategies to reduce social mixing on outcomes of the COVID-19 epidemic in Wuhan, China: a modelling study How poorer countries are scrambling to prevent a coronavirus disaster Preventing cancer, cardiovascular disease, and diabetes: a common agenda for theAmerican Cancer Society, the American Diabetes Association, and the American Heart Association The international normalized ratio (INR) for monitoring warfarin therapy: reliability and relation to other monitoring methods Dabigatran versus warfarin in patients with atrial fibrillation Rivaroxaban versus warfarin in nonvalvular atrial fibrillation Time in therapeutic range and stability over time for warfarin users in clinical practice: a retrospective cohort study using linked routinely collected health data in Alberta, Canada Antithrombotic therapy for atrial fibrillation: CHEST guideline and expert panel report Guidelines for the prevention of stroke in patients with stroke and transient ischemic attack: a guideline for healthcare professionals from the American Heart Association/American Stroke Association AHA/ACC Focused Update of the 2014 AHA/ACC guideline for the management of patients with valvular heart disease: a report of the American College of Cardiology/American Heart Association Task Force on Clinical Practice Guidelines Antithrombotic therapy for VTE disease: Antithrombotic Therapy and Prevention of Thrombosis ESC Guidelines for the diagnosis and management of acute pulmonary embolism developed in collaboration with the British Committee for Standards in Haematology. Guidelines on the investigation and management of antiphospholipid syndrome Antithrombotic Therapy for VTE Disease: CHEST Guideline and Expert Panel Report [published correction appears in Chest Treatment of venous thromboembolism AHA/ACC/HRS Focused Update of the 2014 AHA/ACC/HRS Guideline for the Management of Patients With Atrial Fibrillation: A Report of the American College of Cardiology/American Heart Association Task Force on Clinical Practice Guidelines and the Heart Rhythm Society Exclusion of atrial thrombus by transesophageal echocardiography does not preclude embolism after cardioversion of atrial fibrillation. A multicenter study. Circulation Spontaneous conversion of patients with atrial fibrillation scheduled for electrical cardioversion: an ACUTE trial ancillary study Clinical pharmacokinetics and pharmacodynamics of direct oral anticoagulants in patients with renal failure Comparison of the efficacy and safety of new oral anticoagulants with warfarin in patients with atrial fibrillation: a meta-analysis of randomized trials Oral direct thrombin inhibitors or oral factor Xa inhibitors for the treatment of pulmonary embolism Comparative safety of direct oral anticoagulants and warfarin in venous thromboembolism: multicentre, population based, observational study Oral rivaroxaban for symptomatic venous thromboembolism Oral rivaroxaban for the treatment of symptomatic pulmonary embolism Oral apixaban for the treatment of acute venous thromboembolism Edoxaban versus warfarin for the treatment of symptomatic venous thromboembolism Dabigatran versus warfarin in the treatment of acute venous thromboembolism Treatment of acute venous thromboembolism with dabigatran or warfarin and pooled analysis New oral anticoagulants: their advantages and disadvantages compared with vitamin K antagonists in the prevention and treatment of patients with thromboembolic events Dabigatran versus warfarin in patients with mechanical heart valves Direct oral anticoagulants in extremely obese patients: OK to use? Profiles of direct oral anticoagulants and clinical usage-dosage and dose regimen differences Vitamin K antagonists: relative strengths and weaknesses vs. direct oral anticoagulants for stroke prevention in patients with atrial fibrillation A practice tool for the new oral anticoagulants Practical considerations for the nonvitamin K antagonist oral anticoagulants Updated European Heart Rhythm Association Practical Guide on the use of nonvitamin K antagonist anticoagulants in patients with non-valvular atrial fibrillation Low-molecular-weight heparins: an overview of their pharmacodynamics, pharmacokinetics and metabolism in humans SSC of the ISTH. Duration of anticoagulant therapy after a first episode of an unprovoked pulmonary embolus or deep vein thrombosis: guidance from the SSC of the ISTH Venous thromboembolism prophylaxis and treatment in patients with cancer: ASCO clinical practice guideline update Lowmolecular-weight heparins in renal impairment and obesity: available evidence and clinical practice recommendations across medical and surgical settings Effect of obesity on outcomes after fondaparinux, enoxaparin, or heparin treatment for acute venous thromboembolism in the Matisse trials No difference in risk for thrombocytopenia during treatment of pulmonary embolism and deep venous thrombosis with either low-molecular-weight heparin or unfractionated heparin: a metaanalysis Quality of anticoagulation and use of warfarin-interacting medications in long-term care: a chart review Atrial fibrillation and stroke prevention with warfarin in the long-term care setting Systematic review of studies of self-management of oral anticoagulation Patient self-testing is a reliable and acceptable alternative to laboratory INR monitoring Self management of oral anticoagulation: randomised trial Self-management of oral anticoagulation reduces major outcomes in the elderly. A randomized controlled trial Randomized controlled trial of supervised patient self-testing of warfarin therapy using an internetbased expert system Impact of a pharmacistled warfarin self-management program on quality of life and anticoagulation control: a randomized trial Accuracy of the point-of-care coagulometer CoaguChek XS in the hands of patients Cohort study of Anticoagulation Self-Monitoring (CASM): a prospective study of its effectiveness in the community Comparison of the INR Values measured by CoaguChek XS Coagulometer and conventional laboratory methods in patients on VKA Therapy International normalized ratio self-testing and self-management: improving patient outcomes. Vasc Health Risk Manag Self-monitoring and self-management of oral anticoagulation Improving the management of warfarin in aged-care facilities utilising innovative technology: a proof-of-concept study International Self-Monitoring Association for Oral Anticoagulation. Guidelines for implementation of patient self-testing and patient self-management of oral anticoagulation. International consensus guidelines prepared by International Self-Monitoring Association for Oral Anticoagulation Patient self-testing and self-management of oral anticoagulation with vitamin K antagonists: guidance from the British Committee for Standards in Haematology Prospective comparison of point-of-care device and standard analyzer for monitoring of international normalized ratio in outpatient oral anticoagulant clinic Pharmacology and management of the vitamin K antagonists: American College of Chest Physicians Evidence-Based Clinical Practice Guidelines (8th Edition) Reexamining the recommended follow-up interval after obtaining an in-range international normalized ratio value: results from the Veterans Affairs study to improve anticoagulation Available at: https ://throm bosis uk.org/downl oads/Antic oagul ation %20dur ing%20Cov id-19 BSH Haemostasis and Thrombosis Task Force. INR testing for out-patients on warfarin during COVID-19 restrictions Evidence-based management of anticoagulant therapy: Antithrombotic Therapy and Prevention of Thrombosis, 9th ed: American College of Chest Physicians Evidence-Based Clinical Practice Guidelines American Society of Hematology 2018 guidelines for management of venous thromboembolism: optimal management of anticoagulation therapy Feasibility of extendedinterval follow-up for patients receiving Warfarin