- Research article
- Open Access
Solutions to improve the latent tuberculosis Cascade of Care in Ghana: a longitudinal impact assessment
BMC Infectious Diseases volume 20, Article number: 352 (2020)
Loss of patients in the latent tuberculosis infection (LTBI) cascade of care is a major barrier to LTBI management. We evaluated the impact and acceptability of local solutions implemented to strengthen LTBI management of household contacts (HHCs) at an outpatient clinic in Ghana.
Local solutions to improve LTBI management were informed by a baseline evaluation of the LTBI cascade and questionnaires administered to index patients, HHCs, and health care workers at the study site in Offinso, Ghana. Solutions aimed to reduce patient costs and improve knowledge. We evaluated the impact and acceptability of the solutions. Specific objectives were to: 1) Compare the proportion of eligible HHCs completing each step in the LTBI cascade of care before and after solution implementation; 2) Compare knowledge, attitude, and practices (KAP) before and after solution implementation, based on responses of patients and health care workers (HCW) to structured questionnaires; 3) Evaluate patient and HCW acceptability of solutions using information obtained from these questionnaires.
Pre and Post-Solution LTBI Cascades included 58 and 125 HHCs, respectively. Before implementation, 39% of expected < 5-year-old HHCs and 66% of ≥5-year-old HHCs were identified. None completed any further cascade steps. Post implementation, the proportion of eligible HHCs who completed identification, assessment, evaluation, and treatment initiation increased for HHCs < 5 to 94, 100, 82, 100%, respectively, and for HHCs ≥5 to 96, 69, 67, 100%, respectively. Pre and Post-Solutions questionnaires were completed by 80 and 95 respondents, respectively. Study participants most frequently mentioned financial support and education as the solutions that supported LTBI management.
Implementation of locally selected solutions was associated with an increase in the proportion of HHCs completing all steps in the LTBI cascade. Tuberculosis programs should consider prioritizing financial support, such as payment for chest x-rays, to support LTBI cascade completion.
Latent tuberculosis infection (LTBI) management is a key component in the World Health Organization (WHO) End TB Strategy . Household contacts (HHCs) of individuals with active pulmonary tuberculosis (TB) have a high risk of developing active TB . Recent WHO guidelines recommended LTBI treatment for all HHCs diagnosed with LTBI in both low and high incidence TB countries .
Management of HHCs is a multistep process that begins with identification and concludes with treatment completion. This process has been referred to as the LTBI Cascade of care (Fig. 1). Recent systematic reviews have identified substantial patient losses at steps throughout the LTBI Cascade [3, 4]. The largest proportion of losses occurs prior to LTBI treatment initiation, but few studies have examined reasons, or evaluated solutions for these losses .
Ghana is a high incidence TB country, with an estimated incidence rate of 152 per 100,000 population in 2017 . TB care in Ghana is provided through the Ghana National Tuberculosis Program (NTP). The 2015–2020 NTP strategic plan identified provision of isoniazid preventative treatment to high risk HHCs as a key activity . There is no published evaluation of the implementation of these targets in practice in Ghana .
A multi-centre cluster randomized trial of a programmatic public health intervention to improve LTBI treatment initiation in HHCs was completed in 2019 (Enhancing the Public Health Impact of LTBI Diagnosis and Treatment (ACT4) ). As part of this study local stakeholders selected and implemented solutions to improve LTBI management based on local LTBI cascade and questionnaire data.
We have evaluated the impact and acceptability of the locally implemented solutions to strengthen LTBI management at the study site in Ghana. Specific objectives were to: 1) Compare the proportion of eligible HHCs completing each step in the LTBI cascade of care before and after implementation of the local solutions; 2) Compare knowledge, attitude, and practices (KAP) related to LTBI management before and after implementation of the solutions, based on responses of patients and health care workers (HCW) to questionnaires; 3) Evaluate patient and HCW acceptability of solutions using information obtained from these questionnaires.
Overview of ACT4 trial
ACT4 was a pragmatic cluster randomized trial at 24 sites in 5 countries. The full protocol has been published elsewhere . Intervention sites received a two-phase intervention. In Phase 1, sites performed a standardized evaluation to identify and understand local gaps and barriers to LTBI care for HHCs of pulmonary TB patients. This included an evaluation of the LTBI cascade of care at each site, and questionnaires that were administered to Patients (index patients, adult HHCs, parents of child HHCs) and HCW. Site-specific solutions were then developed in consultation with local stakeholders. The solutions at the Ghana study site, summarized in Table 1, targeted barriers related to knowledge, stigma, and patient cost. In Phase 2, sites implemented their solutions with financial support provided by the research trial.
Solutions impact study (see also Fig. 2: schematic of study design)
For this study we used a quasi-experimental design to compare the LTBI cascade of care before (April–June 2017; “Pre-solutions cascade”) and after solution implementation (February to April 2018;“Post-solutions cascade”). The Cascades included all HHCs of index patients diagnosed with microbiologically confirmed pulmonary TB. In an earlier study conducted in Ghana, no HHC completed any LTBI cascade steps past “Identification”, meaning that no HHCs were investigated, nor treated. Based on this, we calculated that the expected number of HHC identified for 6 index patients (n = 56 HHCs) Post Solutions would provide > 80% power to detect a 30% increase in Identification. Due to variability in the number of index patients identified per month, a three-month period was selected for the Pre and Post cascades to ensure an adequate sample size. Cascade data was collected for HHCs from Step 1, Identification, to Step 4, Treatment Initiation.
To assess solution acceptability, we used the results from the questionnaires administered between November 2016 to January 2017 to Patients and HCW as part of the ACT4 trial (“pre-solutions questionnaires”). In August and September 2018, we administered a second set of questionnaires to Patients and HCW (“post-solutions questionnaires”).
This study was conducted at St. Patrick’s Hospital Outpatient TB clinic in Offinso, Ghana between November 2016 and September 2018. St. Patrick’s hospital is part of the National Catholic Health Services system in Ghana. The hospital has a catchment area of approximately 90,000 people. In 2016 and 2017 there were approximately 58 patients treated for active TB each year. None of their HHCs were started on LTBI treatment during this time. At a national level, the Ghanaian NTP coordinates TB care. There are ten administrative regions in the country with Regional NTP Coordinators responsible for TB management in each region. TB care and services are provided free .
Index patients with newly diagnosed microbiologically confirmed pulmonary TB were eligible if they had at least one identified HHC. Adult HHCs and parents of child HHCs < 5 years of age were eligible to complete questionnaires if they (or their child) had been identified as a HHC of a patient with newly diagnosed microbiologically confirmed pulmonary TB. Index TB patients and HHC could complete only one questionnaire. Local HCW involved in routine patient care identified potentially eligible Patients. The TB clinic manager identified potentially eligible HCWs.
The Index TB Patient register was used to identify all patients diagnosed with active pulmonary TB during all data gathering periods. Prior to solution implementation, the study site used a “Register of TB Contact Investigations” to list identified HHCs and any contact investigation activities. This registry was used to collect information for the pre-solutions cascade. A more detailed contact registry containing information about identification, symptom screen, TST, chest x-ray, and treatment initiation/completion was implemented in the study, and used to collect data for the post-solution cascade.
Questionnaires assessed KAP related barriers to LTBI care and were based on those used in a previous study (available on request from authors) . The specific questions within each questionnaire differed according to the group surveyed (index patients versus HHCs versus HCW). Responses to open ended questions were coded into common themes. All questionnaires were pre-tested for clarity. For the post-solutions questionnaires, shortened versions of the pre-solutions questionnaires addressing KAP were used. Open-ended questions evaluating the respondents’ perspectives on the solutions were added (available on request from authors). The pre-solutions questionnaires were shortened to remove redundant and non-informative questions based on structured content analysis and feedback from study sites. A trained research assistant administered all questionnaires with the exception of the post-solutions questionnaire for HCW, which was self-administered. Questionnaires were administered in the participants’ primary language (Twi). The self-administered HCW questionnaire was in English. We aimed to interview 20 persons from each of the participant groups in the pre and post-solutions questionnaires.
The proportion of HHCs who successfully completed each cascade step among those eligible in the pre-solutions versus post-solutions assessment period was compared using Fisher’s exact test with p < 0.05 considered significant. We could not find any published data from Ghana estimating the number of expected HHCs per index patient. Therefore, we used data on the average number of HHCs identified per index TB patient in the last 3 months of the study, when the contact investigation procedures were well established. This number was then used to calculate the expected number of HHCs (i.e. those eligible to enter Step 1), for all study periods.
Questionnaire KAP responses on pre versus post-solutions questionnaire were compared using Fisher’s exact test with p < 0.05 considered significant.
Acceptability of solutions was based on post-solution questionnaires responses. Questions were open ended and respondents were not prompted regarding potential solutions, so they could mention literally any possible item. Therefore, if at least 30% of patient respondents listed the same solution as helpful, this solution was considered to have “good” acceptability. Mention of any item by at least one respondent was considered to represent “moderate” acceptability. The same criteria were used for HCW, with the exception that if a solution was reported as “most helpful” it was judged to have “good” acceptability. Data analysis was performed using statistical package for social science (SPSS) version 25.
This study was approved by McGill University Health Centre Research Institute ethical review board (ERB) (15–291-MUHC) and the Committee on Human Research, Publication and Ethics of the School of Medical Sciences/Komfo Anokye Teaching Hospital.
LTBI Cascade completion
As shown in Fig. 3, in the pre-solutions cascade, 39% of expected HHCs < 5 years (n = 5), and 66% of expected HHCs ≥5 years (n = 53), were identified. Medical assessment and LTBI treatment were not provided to any eligible HHCs. In the post-solutions cascade, the proportion of adult and child HHCs completing each step in the LTBI Cascade increased by at least 30%, compared to the pre-solutions cascade (p < 0.05 for all steps).
Questionnaires: to assess the acceptability of the solutions
Characteristics of respondents
The characteristics of the 80 respondents who completed questionnaires before, and the 95 respondents who completed questionnaires after solution implementation were similar (Table 2).
Patient and HCW Solution Acceptability
Home visits (9/12(75%)) and education (5/12(42%)) were the activities that HCWs most frequently reported as helpful for Identification of HHCs.
As shown in Fig. 4, financial support, education provided by HCW to HHCs, and home visits were the most frequently reported determinants that supported completion of the Initial Assessment by Patients and HCWs.
In the post-solutions questionnaires, adult HHCs (7/15(47%)), parents of child HHCs (7/11(64%)), and HCW (2/11(18%)) all reported that financial coverage was an important determinant in completing the Medical Evaluation (Fig. 3). Both adult HHC (6/15(40%)) and HCW (4/11(40%)) specifically mentioned financial coverage of the cost for chest x-ray was important. Education provided by HCW was also mentioned as an important determinant by adult HHC (3/11(27%)) and parents of child HHC (5/11(45%)).
Financial support and education provided by HCW were the most frequently reported determinants by HHCs and HCW that supported LTBI treatment initiation.
A summary of the patient and HCW solution assessments, along with a description of solutions adoption at the study conclusion, is shown in Table 3. HCW training, educational materials, home visits, and chest x-ray funding were all reported to have good Patient (index patient, HHC, and parent of child HHC) and provider (HCW) acceptability (Fig. 4). The main determinant of successful adoption of a solution was the availability of funding for the solution (e.g. reimbursement for the cost of a chest x-ray had good patient and provider acceptability but was not adopted because funding could not be obtained).
Knowledge, attitude, and practices
Detailed responses to each section of the questionnaires are presented in Supplemental Tables 1A-1E. The proportion of patients who reported they completed the Initial LTBI Assessment because of HCW advice in the post-solutions questionnaire significantly increased (5% versus 33% for pre versus post-solutions questionnaires respectively, p < 0.05) (Appendix 1-Supplemental Table 1A).
Pre-solutions, all parents reported their child did not complete a medical assessment for TB/LTBI because they lacked adequate knowledge (Appendix 1-Supplemental Table 1B). Post-solution, this was not reported as a barrier by any parents.
Overall, “affordability/low cost” was the most frequently reported reason for clinic satisfaction by parents of child HHCs and the third most frequently reported reason for clinic satisfaction by adult HHCs and index patients (Appendix 1-Supplemental Table 2).
In this assessment of strategies to improve LTBI management in Ghana, the implementation of locally selected solutions was associated with large improvements in the LTBI cascade. Financial support and patient education were the most frequently reported factors that supported LTBI cascade completion.
In low and middle-income countries, the cost of chest x-ray alone can be a major financial burden on patients with TB and their families [8, 9]. In this study, payment for chest x-rays was implemented as a solution to financially support HHCs. The average monthly salary prior to TB diagnosis among patients with active TB in Ghana has been estimated at approximately 300 GHC ($62 USD) . At the time of the study, the local cost for one chest x-ray was 40 GHC ($10 USD). If two or three HHCs from one family require a chest x-ray for LTBI medical assessment, as is often the case, it is clear that the cost for this step alone could be a major barrier.
Several studies of HHCs have reported significant knowledge gaps surrounding TB transmission, screening measures, and infection status [10,11,12,13]. The solutions at the Ghana site included education for HCW and patients. Patient education was consistently reported by HCW, and by the HHC themselves, as contributing to LTBI cascade completion.
Our study has several limitations. The lack of an external control group for comparison limits our ability to attribute the improvements in the cascade to the study solutions. However, no other changes were made to the LTBI management program during this time so the impact of other or external factors should have been minimal. Secondly, our data is limited to a single site. Sample size calculation was based only on Step 1- Identification; however, given the large improvements at all steps this likely has minimal impact on interpretation of our results. Post-solutions questionnaires were administered after some solutions had been discontinued. Therefore, some respondents may not have been exposed to all solutions, thereby limiting their assessment. Post-solutions HCW questionnaire was self-administered. This likely reduced response bias, however, some respondents misinterpreted some questions, which limited the number of informative responses. Finally, we were not able to assess possible interaction effects of different program strengthening activities and solutions on each other.
Based on our results, reducing the financial burden for HHC should be a key priority for the Ghanaian NTP. Education of the index TB patients and their HHCs should also be a priority. Finally, despite improvements in LTBI cascade completion, some gaps persisted at the study site. In order to continuously improve TB programs, repeated assessments of the LTBI cascade are needed.
Following the implementation of multiple solutions to strengthen LTBI management at a TB clinic in Ghana, there was a large increase in the proportion of HHC started on LTBI treatment. Although inferences are limited from a single site study, our conclusion is that reducing financial barriers and providing education to index patients and HHCs were the most important solutions.
Availability of data and materials
All relevant data generated and analysed during the current study are included in this published article (and it supplementary information files). Further data that was considered non-relevant (limited questionnaire data) are available from the corresponding author on reasonable request.
Enhancing the Public Health Impact of LTBI Diagnosis and Treatment
Health Care Worker
Low and Middle Income Countries
Latent Tuberculosis Infection
Tuberculin Skin Test
United States Dollar
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This study was funded by the Canadian Institutes of Health Research, Ottawa, Canada. Grant number FDN-143350.
Ethics approval and consent to participate
This study was approved by McGill University Health Centre Research Institute ethical review board (ERB) (15–291-MUHC) and the Committee on Human Research, Publication and Ethics of the School of Medical Sciences/Komfo Anokye Teaching Hospital. Signed informed consent was obtained for all eligible participants before the questionnaire was administered.
Consent for publication
The authors declare that they have no competing interests.
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Barss, L., Obeng, J., Fregonese, F. et al. Solutions to improve the latent tuberculosis Cascade of Care in Ghana: a longitudinal impact assessment. BMC Infect Dis 20, 352 (2020). https://0-doi-org.brum.beds.ac.uk/10.1186/s12879-020-05060-0
- End TB strategy
- Cascade of care