key: cord-0784057-0359gqea
authors: Dlangalala, Thobeka; Musekiwa, Alfred; Brits, Alecia; Maluleke, Kuhlula; Jaya, Ziningi Nobuhle; Kgarosi, Kabelo; Mashamba-Thompson, Tivani
title: Evidence of TB Services at Primary Healthcare Level during COVID-19: A Scoping Review
date: 2021-11-27
journal: Diagnostics (Basel)
DOI: 10.3390/diagnostics11122221
sha: 4aabd20d5e370f3014131a9cafa563203620cbde
doc_id: 784057
cord_uid: 0359gqea

Tuberculosis (TB) is still a major public health concern, despite the availability of preventative and curative therapies. Significant progress has been made in the past decade towards its control. However, the emergence of the novel coronavirus disease 2019 (COVID-19) has disrupted numerous essential health services, including those for TB. This scoping review maps the available evidence on TB services at the primary healthcare (PHC) level during the COVID-19 period. A comprehensive literature search was conducted in PubMed, Web of Science, Medline OVID, Medline EBSCO, and Scopus. A total of 820 articles were retrieved from the databases and 21 met the eligibility criteria and were used for data extraction. The emerging themes were the effect of the COVID-19 pandemic on TB services, patient and provider experiences, recommendations for TB services during the COVID-19 period, and the implementation of the recommendations. The review found that the mitigation strategies, as well as fear and stigma experienced at the start of the COVID-19 pandemic may have led to TB cases potentially going undetected, which may threaten TB treatment outcomes. Therefore, efforts must be directed at finding these missing cases and ensuring that PHC facilities are equipped to adequately diagnose and treat them.

Despite the availability of vaccinations and chemotherapy for prevention and treatment [1] , 10 million new cases of tuberculosis (TB) were estimated to have occurred in 2019 [2] . However, only 7.1 million of these cases were found and reported to national TB programmes, leaving a third undetected [3] . In addition, considerably more were not started on an appropriate treatment [1] . These missed cases contribute to the ongoing transmission [4] , while prolonged diagnosis and treatment initiation exacerbate disease severity and continued spread [5] . Interrupting transmission through early and accurate detection, rapid treatment initiation, and completion, preferably at the primary healthcare level (PHC), aids efforts in ending the TB epidemic [3, 6] . In 2020, COVID-19 emerged, hindering global TB control efforts [7] , and sidelining many routine TB services to accommodate the response to the COVID-19 pandemic [8, 9] . TB services suffered a sharp decline due to lockdowns. Therefore, limiting access to healthcare and a rise in fear and stigma since the advent of COVID-19 [8, 10, 11] .

Studies that predict the potential impact of the COVID-19 pandemic on TB services suggest that temporary disruptions in response to the pandemic will likely affect all aspects of the TB care cascade [12] [13] [14] . Even small disruptions to these services could have longterm consequences on TB control [12] . These will especially be felt in high burden countries where TB incidence and mortality have been predicted to increase by 6.3 and 1.4 million, respectively, between 2020 and 2025 [12] . Delays in timely diagnosis and treatment are listed as the potential drivers for these grim outcomes [12, 14] .

The World Health Organization's (WHO) End TB strategy and the sustainable development goal (SDG) 3.3 aim to end TB through timely diagnosis and treatment, treatment adherence, and preventative therapy [15, 16] . The WHO aims to eliminate the TB epidemic by 2035 and has also set short-term milestones to reduce TB deaths and incidence rates by 2020 and 2025 [3, 15] . Findings from the TB global health report showed that 2020 milestones were not achieved [3, 17] . Similarly, interim targets were set by the United Nations (UN) to diagnose and treat 40 million additional people by 2022 [7] . Although progress towards these goals has been made, it is still below the threshold that would make TB elimination attainable [3, 18] . Moreover, it is possible that the small gains made towards controlling TB were disrupted by the COVID-19 pandemic, pushing the global TB targets further into the future [7, 19] .

As the first point of contact with health services, PHC facilities can reach large proportions of the population. These facilities also promote equitable access to health services and continuity of care and are recognized as a powerful tool for achieving the health SDGs [16, 20] . Moreover, the WHO has emphasized that progress towards containing the TB epidemic can accelerate when TB control has been integrated with PHC [21] . Furthermore, high-quality PHC services are an important predictor for whether TB control strategies will realize their promise [22] .

Despite the emergence of other public health priorities, such as the COVID-19 pandemic, uninterrupted TB services at the PHC level are crucial for reaching TB targets. Given the novelty of the COVID-19 pandemic, its effects on TB services at the PHC level remain unclear and require further exploration. Therefore, this scoping review mapped evidence on TB services at the PHC level during the COVID-19 pandemic. This evidence will be used to develop the primary research in order to address and improve TB services at the PHC level during the COVID-19 pandemic.

Herein, we conducted a scoping review to map the available evidence on TB services during the COVID-19 era. This scoping review is conducted as part of a larger study that aims to develop a novel approach for improving TB diagnostic services during the pandemic in primary healthcare clinics in high disease burdened settings. A scoping review protocol was registered on the open science framework (OSF) under the title, "Evidence of TB services at primary healthcare level during COVID-19: A scoping review protocol", where it can be accessed via this link: https://osf.io/pq3ba, 15 October 2021. The scoping review was guided by the Arksey and O'Malley framework [23] , Levac et al. [24] , and the Joanna Briggs Institute 2020 guidelines [25] . The findings of the study were reported according to the Preferred Reporting Items for systematic reviews and meta-analyses extension for scoping reviews (PRISMA-ScR) checklist, Table A1 [26] .

Step 1: Identifying the research question The main research question was: What evidence exists on TB services at the PHC level during the COVID-19 pandemic?

We assessed the eligibility of the research question for a scoping review study by applying the population, concept, and context (PCC) framework, developed by the Joanna Briggs Institute [25] , see Table 1 . Table 1 . PCC framework to determine the eligibility of the research question and guide the selection of studies on TB services during the COVID-19 pandemic.

Population Primary healthcare providers-healthcare practitioners providing TB services, which are the first point of contact between people in a community and the healthcare system.

TB services-the processes involved in finding, diagnosing, treating, and preventing TB, which leads to cases being notified to national health systems.

COVID-19 era-the time since COVID-19 emerged, from January 2020 to date.

Step 2: Identifying relevant studies We conducted an advanced search using the following five academic databases: PubMed, Web of Science, Medline OVID, Medline EBSCO, and Scopus. Studies were identified using the following keywords and Medical Subject Heading (MeSH) terms: "TB diagnostics", "Health Service" "TB testing" "COVID-19", "SARS-CoV-2", "COVID-19 Pandemic", "COVID-19 era", and "Primary healthcare". A combination of Medical Subject Headings (MeSH) and free word texts of the keywords were used when conducting the searches. WHO and Stop TB partnership websites were accessed for reports and the reference lists of all the included studies were consulted for additional literature. The comprehensive database search was conducted by an experienced librarian to ensure that the best search strategies were used for each database.

Publications that adhere to the following criteria were included: Publications from before 2020.

Step 3: Selecting studies The studies were selected in three phases. First, the principal investigator screened the titles of each article using the eligibility criteria as a guide. Eligible articles were exported to an EndNote20 library where duplicates were identified and removed. In the second phase, two independent reviewers screened the abstracts of the included articles using a screening tool based on inclusion and exclusion criteria. The screening tool was piloted and adjusted using 10 articles before the screening process was conducted. The reviewers discussed any discrepancies that arose until they reached a consensus on the articles to select. In the third phase, the two reviewers screened the full texts of the relevant articles using a screening tool guided by the eligibility criteria. Before use, the screening tool was piloted by both screeners, and changes were made accordingly. Discrepancies during full-text screening were resolved by a third reviewer. The level of agreement between the two reviewers was calculated using the Kappa statistic.

Step 4: Charting the data An electronic data charting form containing variables relevant to the research question was developed. Two independent reviewers then piloted the data extraction tool using 10 of the included studies. The necessary changes were applied according to the feedback given by the reviewers. Data were extracted from the included studies based on the following categories: Author, aim, type of publication, country, type of TB service, and primary healthcare provider.

We determined the methodological quality of the included studies using the Mixed Methods Appraisal Tool (MMAT) V.2018 software [27] . The particular study design used in each article was appraised, following stipulations by the MMAT guidelines. Once the scores for each study were calculated as a percentage, they were given a specific rank. Studies equal to or below 50% were ranked as low quality, those between 51-75% were deemed average quality, and those ranging from 76-100% were given a high-quality score.

We employed the thematic analysis to extract relevant evidence to answer our research questions and presented a narrative summary that centered on the emerging themes. The themes that arose most from the included studies were as follows: The consequences of the COVID-19 pandemic on TB services, comparison of TB services before and after the COVID-19 pandemic, patient experiences of TB services during COVID-19, and recommendations for TB services at PHCs during COVID-19.

The selection and exclusion of studies are depicted in the PRISMA-ScR flow chart ( Figure 1 ). Initially, we retrieved 819 articles, 702 from database searches and 117 from Google. Following title screening, we excluded 594 ineligible articles. The 225 remaining articles were imported to Endnote 20. The results retrieved from each database are listed in Table 2 . After removing 120 duplicates, 105 articles were eligible for abstract screening. A total of 54 articles were excluded after abstract screening and 51 were eligible for full-text screening. We excluded 30 articles after full-text screening. All of the articles reported findings from the pandemic and articles were excluded if they reported TB services outside of PHC (17), did not mention healthcare setting (9) , and combined data on TB services from both PHC and higher healthcare settings (3). In total, 21 articles met the eligibility criteria and were used for data extraction. The responses of the reviewers had a 54.64% agreement versus a 73.77% expected agreement by chance, which equates to a moderate agreement (Kappa statistic = 0.4218, p-value < 0.05). The discrepancies from the full-text screening were resolved by a third screener.

The characteristics of the included articles are detailed in Table 3 . The studies presented evidence on TB services at the PHC level during the COVID-19 era. The findings were conveyed in a variety of formats including letters, editorials, expert opinion, reports, webinars, feature articles, news articles, and traditional research articles. In terms of countries, the included articles were from Portugal [28] , Ethiopia [29] , Japan [30] , China [9] , Malawi [31] , the United States of America [32] , Pakistan [33, 34] , Nigeria [35] [36] [37] , India [38] [39] [40] , South Africa [41] [42] [43] , one provided recommendations for high burdened settings [44] , one presented evidence from LMIC [45] , and one study was addressed to all the countries [46] . The primary healthcare settings ranged from clinics, outpatient departments, general practitioner's practices, PHC centers, and pharmacies. ) AND TITLE-ABS-KEY ("primary health care" OR "primary AND healthcare" OR "primary AND care" OR"Health Services")) 5 7 June 2021 Medline OVID (((MH "COVID-19")) OR "covid-19" OR ((MH "SARS-CoV-2")) OR "sars-cov-2") AND (((MH "Tuberculosis+")) OR "tuberculosis") AND (((MH "Primary Health Care")) OR ("primary health care") OR ((MH "Health Services+")) OR ("health services") OR ("primary health")) 223 7 June 2021 Medline EBSCO (((MH "COVID-19")) OR "covid-19" OR ((MH "SARS-CoV-2")) OR "sars-cov-2") AND (((MH "Tuberculosis+")) OR "tuberculosis") AND (((MH "Primary Health Care")) OR ("primary health care") OR ((MH "Health Services+")) OR ("health services") OR ("primary health")) 189 7 June 2021 Scopus (TITLE-ABS-KEY (tuberculosis OR tb) AND TITLE-ABS-KEY (sars-cov-2 OR covid-19 OR covid OR coronavirus OR "corona AND virus") AND TITLE-ABS-KEY ("primary health care" OR "primary AND healthcare" OR "primary AND care" OR "Health Services")) 81

Only four articles were primary studies presenting empirical evidence and were subject to a methodological quality assessment using the 2018 version of the MMAT tool [27] . The scores ranged from 40-75%. Two studies scored 60% [9, 32] and another scored 40% [47] and 70% [35] . Results that scored lower than 51% were considered low quality, 51-75% were of average quality, and high quality if they fell between 76-100%.

The themes that emerged from the included studies were, consequences of COVID-19 pandemic on TB services, patient and provider experiences, recommendations and adaptations for TB services during the COVID-19 era, and implementing the recommendations for TB services, respectively. Of the 21 included studies, 10 reported on the consequences of the COVID-19 pandemic at various PHC facilities. TB clinics in New York, USA temporarily halted the performance of any new TB tests [32] . A study from a LMIC reported that fewer TB cases were diagnosed due to the difficulty in accessing primary care [45] , while a clinic in Nigeria reported that one person came to collect the TB medication during the lockdown [37] . South Africa experienced a 25% drop in access to primary healthcare following the lockdown, as well as a 9% drop in TB testing [41] . Another study in China reported that 75.3% of primary healthcare workers were reallocated from routine services to COVID-19 related work [9] . In a similar manner, clinics from Ethiopia were repurposed as COVID-19 centers [29] or in the case of TB clinics in New York, USA, closed altogether [32] . In Japan, the media reported a shortage of the BCG vaccine in order to claim that it was effective against COVID-19 [30] .

A project that brought TB healthcare to the doorstep of a community was abruptly halted after the nationwide lockdown in India [39] . This project was aimed at rendering a neighborhood block TB-free and achieved it by actively finding TB cases and providing point-of-care mobile diagnostic services. The effects were seen by the abrupt drop in TB notifications during the 3 months of the national lockdown. In addition, direct comparisons with the same period from previous years showed a stark contrast. Another study in Nigeria that sought to directly compare TB case notifications and detection rates in the first few months of 2020 compared with the same period from 2019 showed similar results [35] . Another study from Ethiopia showed that patient flow had significantly decreased in the first months of the COVID-19 lockdowns compared with the same period from the previous year [29] . Moreover, TB case notifications at primary healthcare centers in Malawi were shown to be disproportionately lower than at a regional hospital in Malawi [31] . The current evidence shows that the COVID-19 pandemic has created a scenario where fewer TB cases were detected than usual. However, more evidence is required to determine the extent of the potentially missed cases.

Four of the included studies recorded the perspectives of healthcare workers and patients. All of the participants struggled to access healthcare facilities. Rumors on the closure of certain facilities meant that patients were not seeking care for a period of time in Malawi [31] . In India, 17.3% of patients defaulted on their TB treatment and others consulted general practitioners and private pharmacies for treatment due to the difficulty in accessing healthcare facilities [38] . A survey by the Stop TB partnership found that in several countries, fear of contracting COVID-19 kept patients away from visiting clinics [47] . Likewise, in Malawi, fear and ignorance of COVID-19 meant that many healthcare personnel refused to see or treat anyone displaying symptoms resembling COVID-19 [31] . Moreover, staff were increasingly reluctant to handle any sputum samples or observe sputum collection. Furthermore, this was the case in Nigeria [32, 38] . A lack of personal protective equipment (PPE) discouraged staff from attending to patients in many countries [31, 47] . A survey by the Stop TB partnership found that staff at TB clinics observed a need for patients to be given nutritional support, as well as have their transportation costs covered for visiting healthcare facilities [47] .

Five studies from multiple authors including the WHO have detailed recommendations on how TB services can be improved during a pandemic in high burden settings. All of the studies agreed that the use of telemedicine can be leveraged for TB care. Medical triage and counselling should be conducted by telephone. Where possible, sputum collection should be conducted in a well-ventilated area at home and staff must be adequately protected when collecting the samples from patients [46] . The switch to oral and shorter treatment regimens [42] , as well as the video-supported treatment would reduce the number of patients visiting health facilities [46] . Integrating TB and COVD-19 care, such as testing and active case finding, could benefit the management of both diseases [42] . HIV care must also be integrated for countries with a high disease burden [42] . Patients with drug-susceptible TB should be provided with enough TB medication for the intensive phase and only return to the healthcare facility for an assessment. In addition, they need to switch to the continuation phase where sufficient medication is provided [43, 45] . Patients with drug-resistant TB (DR-TB) must be switched to an oral treatment that lasts until the next scheduled visit, any patients exhibiting concerning iron levels or myelosuppression must be recalled by telephone [44, 46] . Moreover, decentralizing the treatment collection has been encouraged [42, 46] . Furthermore, there was an emphasis on strengthening primary care in order to help in managing the pandemic, by providing PHC workers with best practice training for COVID-19 [43, 46] . This ensures that PHC facilities are equipped with enough staff who have access to PPE and provision of all chronic medication should be available for extended periods to reduce visits to health facilities [43] . Finally, all of the PHCs offering TB testing must follow the recommended infection prevention and control (IPC) measures, from the collection of samples until testing is conducted and the sample is disposed of in the laboratory [46] . It is not clear how many high burden countries have implemented these changes for their TB programs and how successful implementation has been. The following section explores examples of instances where TB services have been adapted.

Five of the included studies documented the changes made to the TB services in response to the COVID-19 pandemic. Outpatient departments in India and Portugal screened patients for COVID-19 before they were attended to. Crowd control was also maintained to ensure that social distance and IPC measures are upheld at all times [28, 40] . The same center in Portugal did contact tracing by telephone and patients were only asked to come to the clinic if they had a positive screening after the phone call [28] . The oral treatment is now favored over injectables and treatment is administered in line with scheduled healthcare visits in India and the USA [32, 40] . Those requiring intravenous treatments are administered by community nurses at home [40] . In several countries, treatment initiation is conducted in clinics, but all of the follow-ups are conducted by telephone, including any consultation with doctors, unless presenting with severe symptoms or treatment side effects [28, 31, 34, 40] . TB clinics in New York, USA, have also begun giving patients daily reminders over the phone to ensure that they adhere to the treatments [28] . In cases where patients cannot utilize telehealth due to limitations in technology, then home visits are conducted on a case by case basis [32] . In Pakistan, general practitioners (GPs) who referred patients to TB centers were used to locate patients that could not be contacted during the pandemic. Moreover, their offices were used as a location where patients could fetch their medication [33] . Furthermore, certain provinces in Pakistan have mandated that private healthcare providers notify TB cases to national TB programs [34] . Healthcare workers are provided with the necessary PPE according to the risk of exposure and they work in shifts to avoid overcrowding [40] . In Pakistan, healthcare providers have been retrained in IPC and the correct use of PPE wherever necessary [34] . All of these adaptations are new and will need to be closely monitored throughout the pandemic to assess their sustainability and effectiveness. Furthermore, more data are needed on other high burden countries to see whether they have adapted TB services since the start of the pandemic.

This scoping review mapped the existing evidence of TB services at the PHC level in the COVID-19 era. The evidence was from a wide range of documentary sources, and most came from high TB burden regions of Pakistan, India, Nigeria, and South Africa. The bulk of the literature found was from the start of the pandemic. The findings show evidence that the COVID-19 pandemic had a negative effect on TB services, how patients and healthcare providers were impacted, as well as recommendations for adapting these services and instances where recommendations had been implemented. Overall, the COVID-19 pandemic has negatively impacted TB services, users, and healthcare providers alike. The findings suggest that TB services were disrupted. In addition, the fear and stigma experienced by healthcare providers and patients likely led to a drop in TB case detection and the notifications seen during the first months of the pandemic. More evidence is needed on the steps taken to identify potentially undiagnosed and missed TB cases and how provider attitudes and patient experiences have improved, especially in high TB burden countries. Although the review has highlighted recommendations for enhancing TB services in high burden settings during the pandemic, only one TB endemic country had implemented these changes. Before COVID-19, countries were making strides towards achieving the SDG targets for TB; a record number of people had been treated including those with DR-TB; the annual number of missed TB cases had fallen below 3 million; and the TB preventative treatment had been prioritized in high burden settings [7] . However, this has likely changed since the start of the COVID-19 pandemic.

The findings of this scoping review show that the arrival of COVID-19 and the measures used to curb the spread drastically reduced the number of TB cases detected and notified, in sharp contrast to the numbers from the same period in previous years [29, 32, 36] . It further demonstrated how TB services were significantly disrupted and sidelined in response to a new public health emergency [9, 32, 37, 45] . Moreover, the COVID-19 pandemic deterred health-seeking behaviors, hindered some patients from acquiring the TB treatment, and increased reluctance among healthcare workers to treat patients [31, 37] . These results have created scenarios for TB cases to go undiagnosed. Furthermore, the fear of attending health facilities and the disruptions leading to their closure have likely interrupted TB treatment regimens, which could lead to treatment failure exacerbating disease transmission and development of drug resistance. These would be grim outcomes for global TB control efforts. The responses, uncovered by the review, mirror those experienced during the Ebola virus outbreak in West Africa, which increased preventable TB deaths over time [48] . Following the Ebola outbreak, TB, HIV, and malaria deaths exceeded those directly caused by the Ebola virus itself [49, 50] . Similarly, the outbreak of the Middle East respiratory syndrome coronavirus (MERS-CoV) in Saudi Arabia harmed TB control efforts [51] . As a result of the Ebola outbreak [52] , certain West African countries have implemented measures for epidemic response. However, it is unclear whether these have had any bearing on TB control during the COVID-19 era. The increase in TB mortality in the coming years due to the disruptions to health services has been foreshadowed by several studies [13, 14, 53] . These will be most evident in high burden settings unless swift action is taken to minimize the impact on health services, while simultaneously identifying, diagnosing, and treating any cases that are not from the start of the pandemic.

A study summarizing the effect of Ebola on TB services emphasized the importance of moving away from disease-specific national programmes to the holistic strengthening of health systems [48] . It further highlights how this kind of approach would not only assist with the management of infectious outbreaks, but ensure that disease control for other conditions is not compromised [48] . Two previous studies showed that China's and Saudi Arabia's prior coronavirus experience facilitated a better COVID-19 response than many other countries [54, 55] . In contrast, this review did not find evidence of TB endemic countries adopting the lessons from previous epidemics. However, our findings present current recommendations for conducting TB services during the COVID-19 pandemic [42] [43] [44] 46] . Although these are helpful, it would have been more beneficial if governments had adopted insights from past viral outbreaks. The review also demonstrates how the recent adaptations to TB services have been adopted in various countries [28, [32] [33] [34] 40] . However, only two of these were high TB burden countries [34, 40] . Considering that many of these suggestions rely on the use of technology, their practicality for resource-limited settings remains to be seen. Therefore, high burden countries must continue to monitor the impact of COVID-19 on TB services and address these with evidence-based interventions.

Many of the included studies documented the situation at the start of the COVID-19 pandemic. Consequently, geographic areas with a lower incidence at the start of the pandemic were not a focus of this study. Thus, an assessment of TB services in these regions is needed for better insight into the global effect of the COVID-19 pandemic. Research on how TB services have fared throughout the pandemic, including peaks in COVID-19 cases and subsequent vaccination strategies, are also needed. The same can be said for provider and health seeker attitudes. This will facilitate the measurement of the impact on TB and allow appropriate mitigation action. Undiagnosed TB cases and interruption to treatment were other issues likely to have been caused by the pandemic. Health systems must be ready to receive and appropriately treat and retain these cases until treatment completion. Therefore, assessing the quality of TB services in high burden settings and providing context-specific adaptations based on the findings could benefit TB control programmes. Moreover, only four empirical studies were found and even these scored low in terms of methodological quality. Therefore, robust primary studies are required to inform evidence-based decisions and recommendations for TB services during pandemics. These studies should focus on strengthening TB case findings, diagnostics, and treatment services for COVID-19 and future pandemics.

The scoping review employed a comprehensive database search that was not limited by language, publication or study design. In addition, the database search included a grey literature and repeated search in the database that retrieved the highest number of articles to maximize the number of studies found. The methodological quality of all the included primary studies was assessed and it was found that they ranged from a low to average quality. For this reason, the scoping review may not be appropriate to inform clinical practice, but does demonstrate a need for additional primary studies to be conducted with more methodological rigor. Moreover, the review retrieved evidence from the start of the COVID-19 pandemic. Therefore, certain geographic regions with initially low incidence rates were not covered. Furthermore, given the evolving nature of the pandemic, it is likely that latter phases including the emerging variants and vaccination control strategies have also impacted the TB service delivery.

In this review, the TB services at the PHC level were disrupted by the COVID-19 pandemic. The potential for undiagnosed TB cases and treatment failure are among the biggest concerns caused by the pandemic. For the TB elimination goals to be met, PHC must be strengthened and ready with effective solutions to address the issues caused by the COVID-19 pandemic and use these for pandemic preparedness in the future. Funding: This presentation/publication has been made possible by funding from UNICEF and with support from Future Africa, the University of Pretoria.

The data for the scoping review was obtained through secondary data analysis, all data supporting the conclusions of this scoping review are available through the reference list.

Despite the availability of vaccinations and chemotherapy for prevention and treatment [1] , 10 million new cases of tuberculosis (TB) were recorded in 2019 [2] . A third of these cases were missed by health systems [3] , and considerably more were not started on an appropriate treatment [1] . These missed cases contribute to the ongoing transmission [4] , while prolonged diagnosis and treatment initiation exacerbate disease severity and continued spread [5] . Interrupting transmission through early and accurate detection, rapid treatment initiation, and completion, preferably at the primary healthcare level (PHC), aids efforts in ending the TB epidemic [3, 6] . In 2020, COVID-19 emerged, hindering global TB control efforts [7] , many routine TB services were sidelined in response to the COVID-19 pandemic [8, 9] . These services suffered a sharp decline due to lockdowns limiting access to healthcare and a rise in fear and stigma since the advent of COVID-19 [8, 10, 11] . Studies that predict the potential impact of COVID-19 on TB services suggest that temporary disruptions in response to COVID-19 will likely affect all aspects of the TB care cascade [12] [13] [14] . Even small disruptions to these services could have long-term consequences on TB control [12] . These will especially be felt by high burden countries where TB incidence and mortality have been predicted to increase by 6.3 and 1.4 million between 2020-2025, respectively [12] . Delays in patients seeking timely diagnosis and treatment are listed as the potential drivers for these grim outcomes [12, 14] . The World Health Organization's (WHO) End TB strategy and the sustainable development goal (SDGs) 3.3 aim to end TB through timely diagnosis and treatment, treatment adherence, and preventative therapy [15, 16] . The WHO aims to eliminate the TB epidemic by 2035 and has also set short-term milestones to reduce TB deaths and incidence rates by 2020 and 2025 [3, 15] . Findings from the TB global health report showed that 2020 milestones were not achieved [3] . Similarly, interim targets were set by the United Nations (UN) to diagnose and treat 40 million additional people by 2022 [7] . Although progress towards these goals has been made, it is below the threshold that would make TB elimination attainable [3, 18] . It is also possible that the small gains made towards controlling TB were disrupted by the COVID-19 pandemic, pushing the global TB targets further into the future [7, 19] . As the first point of contact with health services, PHC can reach large proportions of the population. It also promotes equitable access to health services and continuity of care and is thereby recognized as a powerful way that health SDGs can be achieved [16, 20] . The WHO has also emphasized that progress towards containing the TB epidemic can accelerate when TB control has been integrated with PHC [21] . Furthermore, high-quality PHC services are an important predictor for whether TB control strategies will realize their promise [22] . Despite the emergence of other public health priorities, such as the COVID-19 pandemic, uninterrupted TB services at PHC are crucial for TB targets to be reached. Given the novelty of the COVID-19 pandemic, its effects on TB services at the PHC level remain unclear and require further exploration. Therefore, this review aimed to systematically map evidence on TB services at the PHC level during the COVID-19 pandemic. The evidence obtained from the study will be used to develop primary research that is aimed at addressing and improving TB services at the PHC level during the COVID-19 pandemic to accelerate global efforts to end TB.

Objectives 4

This review aimed to systematically map evidence on TB services at the PHC level during the COVID-19 pandemic. Publications from before 2020.

6 Information sources 6 We conducted an advanced search using the following five academic databases: PubMed, Web of Science, Medline OVID, Medline EBSCO, and Scopus. 5

Studies were identified using the following keywords and medical subject heading (MeSH) terms: "TB diagnostics", "Health Service" "TB testing" "COVID-19", "SARS-CoV-2", "COVID-19 Pandemic", "COVID-19 era" and "Primary healthcare". A combination of medical subject headings (MeSH) and free word texts of the keywords were used when conducting the searches. WHO and Stop TB partnership websites were accessed for reports and the reference lists of all the included studies were consulted for additional literature.

Study records: Data management 8a Describe the mechanism(s) that will be used to manage records and data throughout the review.

The studies were selected in three phases. First, the principal investigator screened the titles of each article using the eligibility criteria as a guide. Eligible articles were exported to an EndNote20 library where duplicates were identified and removed. In the second phase, two independent reviewers screened the abstracts of the included articles using a screening tool developed through the use of the inclusion and exclusion criteria. The screening tool was piloted and adjusted using 10 articles before the screening process was conducted. The reviewers discussed any discrepancies that arose until they reached a consensus on the articles to select. In the third phase, the two reviewers screened the full texts of the relevant articles using a screening tool guided by eligibility criteria. Before use, the screening tool was piloted by both screeners, and changes were made accordingly. Discrepancies during full-text screening were resolved by a third reviewer. The level of agreement between the two reviewers was calculated using McNemar's Chi-square statistic.

Data collection process 8c An electronic data charting form containing variables relevant to the research question was developed. Two independent reviewers then piloted the data extraction tool using 10 of the included studies. The necessary changes were applied according to the feedback given by the reviewers. 7

Data items 9 Data were extracted from the included studies based on the following categories: Author, aim, type of publication, country, type of TB service, and primary healthcare provider. We employed thematic analysis to extract relevant evidence to answer our research questions and presented a narrative summary that centered around the emerging themes. The themes that arose most from the included studies were as follows: The unintended consequences of COVID-19 on TB services; comparison of TB services before and after COVID-19; patient experiences of TB services during COVID-19; and recommendations for TB services at PHC during COVID-19.

Confidence in cumulative evidence

To assess the risk of bias we determined the quality of the included studies using the mixed methods appraisal tool (MMAT) V.2018 software [27] . The tool assessed the methodological quality of the included primary studies. The particular study design guided how the article was appraised, following stipulations by the MMAT guidelines. Once the scores for each study were calculated as a percentage, they were given a specific rank. Studies equal to or below 50% were ranked as low quality, those between 51-75% were deemed average quality, and those ranging from 76-100% were given a high-quality score.

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Recovering from the Impact of the Covid-19 Pandemic and Accelerating to Achieving the United Nations General Assembly Tuberculosis Targets

Impact of the COVID-19 Pandemic on Tuberculosis Control: An Overview

The impact of the COVID-19 epidemic on tuberculosis control in China

COVID-19 affects HIV and tuberculosis care

Tuberculosis in the era of COVID-19 in India

The potential impact of the COVID-19 pandemic on the tuberculosis epidemic a modelling analysis

The potential impact of COVID-19-related disruption on tuberculosis burden

Potential impact of the COVID-19 pandemic on HIV, tuberculosis, and malaria in low-income and middle-income countries: A modelling study

WHO s new end TB strategy

Revisiting Alma-Ata: What is the role of primary health care in achieving the Sustainable Development Goals?

Global tuberculosis report 2020

World Tuberculosis Day 2021 Theme-'THE CLOCK IS TICKING'-and the world is running out of time to deliver the United Nations General Assembly commitments to End TB due to the COVID-19 pandemic

Adhanom Ghebreyesus, T. Primary healthcare is cornerstone of universal health coverage

Brief Guide on Tuberculosis Control for Primary Health Care Providers for Countries in the WHO European Region with a High and Intermediate Burden of Tuberculosis

Evaluating Tuberculosis Case Detection via Real-Time Monitoring of Tuberculosis Diagnostic Services

Scoping studies: Towards a methodological framework

Scoping studies: Advancing the methodology

Updated methodological guidance for the conduct of scoping reviews

PRISMA extension for scoping reviews (PRISMA-ScR): Checklist and explanation

Changes to TB care in an outpatient centre during the COVID-19 pandemic

The impact of COVID-19 on the tuberculosis control activities in Addis Ababa

Prioritizing infants in a time of Bacille Calmette-Guérin vaccine shortage caused by premature expectations against COVID-19

Effects of Coronavirus Disease Pandemic on Tuberculosis Notifications, Malawi. Emerg. Infect. Dis. 2021

Transforming essential services for tuberculosis during the COVID-19 pandemic: Lessons from New York City

COVID-19: Ensuring continuity of TB services in the private sector

Building better tuberculosis control systems in a post-COVID world: Learning from Pakistan during the COVID-19 pandemic

Impact of COVID-19 on TB care: Experiences of a treatment centre in Nigeria

Webinar on the Impact of COVID-19 on TB and PHC Services in Nigeria. Available online

Tuberculosis and HIV responses threatened by COVID-19

Problems faced by tuberculosis patients during COVID-19 pandemic: Urgent need to intervene

The untimely demise of the TB Free block model in the wake of coronavirus disease 2019 in India

Adapting TB services during the COVID-19 pandemic in Mumbai

Covid-19 disrupts HIV and TB services. Mail Guardian 2020

How COVID-19 could benefit tuberculosis and HIV services in South Africa

Sustaining essential healthcare in Africa during the COVID-19 pandemic

Critical changes to services for TB patients during the COVID-19 pandemic

Impact of COVID-19 on Tuberculosis Control

World Health Organization. World Health Organization (WHO) Information Note: Tuberculosis and COVID-19

The Impact of COVID-19 on the TB Epidemic: A Community Perspective

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Delays in Global Disease Outbreak Responses: Lessons from H1N1, Ebola, and Zika

Emerging and Reemerging Infectious Diseases: Global Overview

Middle East Respiratory Syndrome Coronavirus and Pulmonary Tuberculosis Coinfection: Implications for Infection Control

COVID-19 pandemic in west Africa

The potential impact of the COVID-19 response on tuberculosis in high-burden countries: A modelling analysis

Containment of COVID-19: The unprecedented response of Saudi Arabia

Preparedness and response to COVID-19 in Saudi Arabia: Building on MERS experience

Acknowledgments: Cheryl Tosh for editing.

The authors declare no conflict of interest. The funders had no role in the design of the study; in the collection, analyses, or interpretation of data; in the writing of the manuscript, or in the decision to publish the results.

 Table A1 . Preferred reporting items for systematic reviews and meta-analyses extensions for scoping reviews (PRISMA-ScR) checklist.