Introduction
The African continent has one of the highest burdens of disease, yet African research has been described as “
moribund” [
1] and lags behind the rest of the world with respect to scientific publishing [
2]. There is also a limited amount of published research “
done in Africa for Africa” [
1]. Limited research capacity in Africa is an important factor that impedes the continent’s ability to produce health research [
3‐
5]. For strategies on improving health outcomes to be effective, health sciences research and capacity development in this arena is critical. In South Africa, a middle-income country with a quadruple burden of disease [
6], the strengthening of capacity development and of research skills is essential in order to support health research [
7‐
10]. One such skill, fundamental for quality and relevant health research, is biostatistics.
Not only is biostatistics essential for clinical decision-making and the analysis of data for informing health policy [
11] but also in the design, management and analysis of data in both applied and basic medical science research. Without knowledge of this key skill, it is not only difficult to plan and execute research but also to understand published research in the health sciences fields. Clinicians believe that an understanding of biostatistics would benefit their careers [
12]. Knowledge of biostatistics may also result in more efficient and effective cost–benefit solutions to financially constrained health departments and assist with medical decision-making. Furthermore, the demand for skills in biostatistics to support research in clinical trials, genomics, proteomics and bioinformatics [
13] predicts a need, not only to train more biostatisticians, but also to expand their areas of training. Thus, it appears that knowledge of basic biostatistics is fundamental for all medical doctors and biomedical researchers in current and future practice [
14].
In South Africa, most students graduate from secondary schools with a huge knowledge deficit in mathematics and science [
14‐
17]. Such students will thus require strong educational input in biostatistics at tertiary level in order for them to fulfil their roles as clinicians and biomedical scientists in the next millennium. This is supported by Chima et al. [
14], who demonstrated poor baseline knowledge of biostatistics among biomedical researchers and postgraduate students in South Africa.
While a Master’s programme in epidemiology and biostatistics was already in existence in the Faculty of Health Sciences, University of the Witwatersrand [
18], a biostatistical support system for all postgraduate students and staff was initiated and operationalised by the Health Sciences Research Office (HSRO) of the Faculty of Health Sciences (FHS), University of the Witwatersrand (Wits) in 2008. Between 2008 and 2012, the system consisted of modules in biostatistics at entry and advanced level to postgraduate students, a module aimed specifically for supervisors, and one-on-one consultations for students and staff [
19,
20]. This system resulted in an increased number of graduates and publications, although we expressed caution in linking these outcomes directly to the system. The setting up of the initial system was carried out on a limited budget but would be affordable to institutions in a resource-restricted environment [
19]. As the uptake of biostatistical and research methodology courses by staff and students increased from 2010 to 2012, so too did the number of graduates and publications, although other strategic initiatives may also have contributed to these increases [
20]. An assessment of one-on-one consultations over the period 2008–2012 was also undertaken. While the initial biostatistical courses and consultations were in place, there was a need to expand and sustain the ongoing programmes. Expansion occurred in relation to the burgeoning needs of the Wits FHS from 2013 onwards. These needs were related to a perceived increase in postgraduate student registrations and entry of increased numbers of staff and students into research areas related to clinical trials, proteomics and mixed methods analysis. This perceived growth translated into an observed demand on the biostatistical support initiatives around the years 2011–2012.
Thus, the aim of the present study was to describe and analyse the nature and quality of the biostatistical initiatives that allowed expansion of the existing support system in the Wits FHS between 2013 and 2017. In addition, we wished to determine whether the support system is sustainable in terms of financial costs in a limited-resource developing country.
The objectives of this study were to (1) describe the initiatives that were added to the existing support system; (2) assess the quality of the biostatistical support system by the evaluation of the one-on-one consultations and to compare the number of graduates and publication units in relation to the foregoing assessment from 2008 to 2012; and (3) to determine the current financial budget of the support system.
Methods
Ethics clearance was obtained from the Human Research Ethics Committee (Medical) of the University of the Witwatersrand (M1211112; W-CP-180280-2).
Study site
The study was conducted in the Faculty of Health Sciences, University of the Witwatersrand, which is based in Johannesburg, Gauteng Province, South Africa. The Faculty not only trains undergraduate students in medicine and allied health sciences professions but also caters for postgraduate students in these fields. Such students are from within South Africa as well as across the African region. Most of the limited training in biostatistics occurs at postgraduate rather than undergraduate level [
19].
Study design
This descriptive, cross-sectional investigation examines the initiatives put in place in a biostatistical support system based in the Wits HSRO. It extends the assessment on the feedback on consultations of postgraduate students and staff on the support system [
19].
The outcomes assessed were (1) the quality of the one-on-one consultations; (2) the number of graduates and publication units compared to those of 2008–2012; and (3) the financial sustainability of the current support system.
Walk-in consultations
The existing platform for one-on-one walk-in biostatistics consultations with tutors increased from 9 h per week in 2012 to 16 h per week from 2014, due to increased demand by postgraduate students and staff. In a similar way to the 2009 survey [
19], the current study utilised closed, anonymous questionnaires that were completed by individuals following walk-in one-on-one biostatistical consultations with a tutor. Questions in the brief assessment related to the quality of the consultation were rated on a Likert scale of 1–4, where 1 was ‘very bad’ and 4 was ‘excellent’. The questions related to learning from the consultation, confidence to analyse independently after consultation and whether the service would be recommended were answered on a scale of yes/no/not sure. The questionnaire was optional and anonymous, was undertaken at the end of a consultation and took no longer than 5 min to complete. The questionnaire was then placed in a sealed box.
Additional workshops/modules
Additional biostatistics short courses, workshops and activities became necessary following initial set-up of support. An introductory course in qualitative methodology was established in 2012 due to increased demands from students and researchers for qualitative and mixed methods analysis. A workshop on data management and analysis, utilising the postgraduate student/staff own data, was initiated in 2014.
Capacity development
The tutors performing biostatistical one-on-one consultations and facilitation are postgraduate students undertaking either a MSc or PhD degree in Biostatistics in the FHS. From 2018, these duties became part of their curriculum. The tutors are closely supervised by a senior biostatistician.
Financial costs
The costs of senior biostatistics staff, tutors and facilitators were calculated from data received from the Wits HSRO. The average annual charges for licenses of biostatistical packages were calculated over the last 5 years.
The postgraduate students who acted as tutors in the one-on-one consultations that were ‘walk-in’ sessions (i.e. without booking) are not paid as such duties became part of their curriculum. If advanced statistical support was required, the tutors referred such cases to senior biostatisticians on a booking system.
Workshops and consultations are free to postgraduate students and staff within the Wits FHS. However, courses of over 4 hours in duration were charged at a nominal fee of R300 (~US$ 23) per course for students. This amount is paid to the Wits Faculty Research Office by departments.
Number of graduates and research publications
The number of graduates and the publication units were used as an indirect proxy of achievement of the system. Units are the value of measurement used by the South African Department of Higher Education and Training for South African tertiary Institutions in relation to publication output. This measure is utilised as a comparator across institutions instead of publication numbers. One unit does not equate to one publication.
Data were extracted from the Institution’s database on postgraduate enrolments and graduations.
Data management and analysis
Data was entered into an Excel spreadsheet and imported to STATA version 14 for analysis. The analysis of the data was descriptive and the results were presented in frequency tables with corresponding percentages.
Discussion
The expansion of the modules of the biostatistics support system augmented the need for increasing student numbers and affected the nature of the research being undertaken. The quality of the one-on-one consultations remained high during the 5-year period reviewed. Concomitant with the increased numbers of consultations was an increase in the number of graduates and research units over the same period. Financial costs of the support system during this period were cost-effective.
One of the reasons for increasing the resources for biostatistics training in our institution was the introduction of a requirement by the Health Professions Council of South Africa [
21], in 2010, for clinicians who were specialising in specific disciplines to undertake a research project as part of their Master’s degree, which became mandatory in 2011. Hence, the increase in the number of graduates may also be as a result of this implementation as these students required statistical support for project completion.
There are few case studies on the investment in biostatistical skills in health sciences to build research capacity in the developing world. This study sought to evaluate the quality and financial sustainability related to the additional activities instituted in biostatistical support since 2013 in the Wits FHS. Ideally, one would like to see a cohort effect of individuals who have gone through such support. It is difficult to find an objective mechanism for measuring success in relation to implementation of strategies [
5]. However, there has been a growth in high impact factor publications (IF ≥20) from Wits FHS. In the period 2000–2012, there were 28 high impact factor publications, increasing to 39 over the period 2013–2016 (Health Sciences Research Office annual reports 2008–2016, Internal publication). It should be noted that this increase might not be directly linked to the Biostatistics support system, as the target of the support system is postgraduate students and more junior researchers. In addition, accompanying the increase of almost 10% in registrations over all the degree types between the periods 2010–2012 and 2013–2017 in the Faculty, the proportion of graduates increased by approximately 30% over the same period of time.
Notwithstanding these limitations, we note that the number of graduates and research publications lead to great benefit for the Institution as recognition in the South African context. South African Institutions keenly follow the international Institutional Rankings and are highly competitive both locally and internationally in achieving higher rankings. In 2017, Wits was ranked 101–125 out of 500 institutions in the clinical, pre-clinical and health category of the Times Higher Education World University Rankings. Thus, although we cannot link increases in publications and number of graduates directly to the biostatistics strategies introduced at Wits as other factors may be involved, it is, however, a partial indicator of the value of the training in biostatistics. Our postgraduate programmes have a structured coursework and research component. Coursework is completed on time but the challenge has been completion of the research, since most students lack statistical guidance for analysis. This biostatistics support system has bridged that gap and led to an increase in completion of research reports and, hence, graduations. The original biostatistical courses were initiated in 2008 and one-on-one consultations initiated in 2009. Hence, the number of graduating students in relation to the biostatistical support system were reported from 2010 [
19]. Compared to the previous period [
19], the numbers of graduating students in all degrees has increased. This can be indirectly associated with the increased biostatistical initiatives in recent time periods.
The Wits FHS has also seen increasing numbers of publications emanating from students work. More students have been accessing the biostatistical support system for consultations on statistical analysis of their research. The students are keen to publish their findings and this support system provides one mechanism for directing reports into publications.
On analysis of the survey on one-on-one consultations, a similar percentage of students (95.34%) used the service over the years 2013–2017 to the number of students that Chirwa et al. [
19] recommend the service to between 2010 and 2012 (95.8%). The continued excellence of the consultations has borne fruit considering the increased throughput of postgraduate students. As these consultations are provided to individuals from a variety of disciplines by a central group of biostatisticians and biostatisticians-in-training, the model is similar to that of the “Hub-and-Spoke Model” described by Earnest [
22]. However, in the case of consultations at Wits, these do not generally result in collaborations in which the biostatistician is included as an author on an article [
22].
Development of a Masters’ programme in the field of biostatistics within the health sciences is not only important for upskilling those clinicians and researchers who will undertake research in the expanding fields of genomics, proteomics, metagenomics and clinical trials [
23], but is also of importance in providing a pipeline of skilled biostatistics tutors [
13,
23]. This has also proven to be a cost saving measure as the curriculum for the Master’s programme includes training on consultation. In this regard, the Wits FHS no longer pays the tutors for their services. Of value is that some biostatisticians are absorbed into research entities thus increasing the pool supporting analysis at the Wits FHS.
Related to postgraduate courses is the need to initiate training in biostatistics at an earlier stage of allied health sciences undergraduate programmes. More advocacy is needed for the insertion of biostatistics into undergraduate programmes in order to build on basic skills at the postgraduate level [
14]. Basic biostatistics courses have been initiated in research methodology courses offered at undergraduate level in the Faculty in order to build graduates with competent skills in biostatistics and also as a pipeline of postgraduate students in health sciences fields. In fact, Mostert [
15] argues that biostatistics, epidemiology and evidence-based medicine should be taught as a continuum in the medical curriculum.
The demand for biostatistics, biostatistics training and biostatisticians exceeds the current capabilities of health sciences facilities [
13], particularly as biostatistics plays a large role in ‘big data’ research. Demand for biostatisticians far exceeds the supply in the United States [
13], and in Africa there is a marked need for growth in this sector. Kellerman et al. [
18] showed that investing in research training in African institutions resulted in the retention of graduates in Africa. Biostatistics has an unparalleled opportunity to contribute to Africa’s health needs as a fundamental of health research.
In relation to keeping costs minimal in a resource-restricted environment, the use of non-paid tutors for consultations seems a cost-effective alternative in providing a critical mass of assistance and mentors in the Faculty. In addition to spreading the financial burden, a recommendation is that this could be run as an integrated programme within existing entities with such expertise. In our case, the pooling of biostatistics resources between the Wits School of Public Health and HSRO has been cost-effective in driving activities for statistical support. The Wits FHS only pays for one biostatistician because of the shared roles at its disposal. The cost to graduation of US$ 227 per postgraduate student is cost effective. Of course, following training, Master’s and PhD graduates with these skills are engaged by commerce, where the enticement of a larger salary than in academia plays an important role.
When compared to the Wits FHS biostatistical initiative in 2012 [
19], the current system has increased in cost (2012, US$ 68,000; 2017, US$ 96,154). However, the cost per graduate in 2017 (US$ 227) decreased as the number of graduates increased. Hence, the support system is viable in the current economic climate that exists in the institution. However, further increases (e.g. student numbers or expansion of research areas) will place a burden on the finances of the system.
Offering the courses to external participants has financial benefits and such participants should be targeted more in order to increase funding to support the system going forward. Only 10% of such participants attended the course but contributed a third of the funds raised through short courses.
While biostatistics and epidemiology are of great importance in producing research and developing capacity, institutions in South Africa do not mention this skill when developing research strategies [
24,
25].
Chima et al. [
14] showed an improvement in knowledge of biomedical researchers and postgraduate students following the attendance of a short biostatistics course. While recognising the importance of courses, we have attempted to go one step further in providing ongoing support to postgraduate students and staff in addition to short courses by means of consultations and workshops. Solid biostatistical support systems, particularly with the advent of ‘big data’ analysis, are becoming challenging. In order to keep Africa from lagging in health sciences research with respect to the rest of the world, investing in the maintenance and growth of biostatistical support systems is of great importance. The model has become more cost effective as more students use and graduate in the system. This model, created by the Wits Health Sciences Faculty for biostatistics support, may assist other health sciences institutes in developing countries with instituting training at low cost.
Limitations of study
This is a cross-sectional study and thus there was no intervention, and hence no follow-up. There is no control group, as we do not have data for those students not attending the Biostatistical support unit. While Wits is an institution in a middle-income country, similar data from other institutions in the country are not available for comparison. The number of one-on-one consultations is based on the number of completed evaluations.
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