An assessment of equity in the distribution of non-financial health care inputs across public primary health care facilities in Tanzania

Decentralization has been one of the most important health sector reforms in Tanzania since the early 2000s, which led to the transfer of autonomy from the central government to local authorities (districts) of which there are currently 169 [18]. There are two main modes of financing districts that are used in this context: block grants and basket funding. Block grants are funds generated from general tax revenue, while basket funds come from external sources that are pooled at the central level [28, 43, 45]. A needs-based formula was developed by the Ministry of Health for the allocation of financial resources from the health basket fund and block grant to the district councils, based on the following criteria; age and sex-weighted population (50%); poverty levels (15%); an index of mileage to and within the local government area (15%); and burden of disease, to incorporate under-five and adult mortality rates plus any others available (20%) [28]. Recently, the government has adopted a performance-based approach implying that part of the basket distribution would be contingent on local government authorities (LGAs) meeting certain conditions [34]. Districts also receive revenue from cost sharing funds, which include user fee revenue from facilities as well as premium contributions for the community health fund (a form of community-based health insurance). Districts are also allocated a government matching grant equal to community health fund member contributions collected by each district [38, 54]. While this provides an incentive for districts to generate community health fund revenue, it cannot be described as an equitable distribution mechanism as relatively poor districts are less able to generate these contributions in the first place [38].

Much of the recruitment and distribution of health personnel is done at the central level, although regions and districts have the mandate to identify and inform the Ministry to deploy new staff to fill vacancies [36]. Staffing norms vary by level of care, for example, a public dispensary requires 15–20 staff, consisting of clinical and non-clinical support staff. Health centres are required to have between 39 and 52 staff [35].

The ordering of drugs and medical supplies is done quarterly by facilities using a system known as Integrated Logistic System (ILS) through the District Medical Office (DMO) to the Medical Stores Department (MSD), which in turn distributes facility-specific packs directly to the facilities [33, 52]. However, the medicine supply chain has been facing a number of challenges including insufficient availability of drugs at MSD to fulfil orders, long ordering cycles and late delivery of medicines and medical supplies [60]. Local government authorities can also use their own funds to procure medicines from alternative suppliers in case of medicine stock-outs at the MSD level. Districts have being allocating about 30–33% of revenue from the community health fund to public primary health care facilities for minor repair and the local purchase of drugs. Vaccines are allocated directly to facilities through the Expanded Programme for Immunisation.

While poverty is taken into consideration in the allocation of central government funds and basket funds from donors, the equity implications of existing staff allocation mechanisms and drug procurement are less clear. Hence this study seeks to examine how equitable the distribution of health care inputs is across facilities at district level.

This is a quantitative assessment of equity in the distribution of health care inputs at the primary health care facility level within districts. By taking the health facility as the unit of analysis, rather than a geographic area, the focus is on resource distribution across service providers, thereby capturing equity of public and external resource allocation.

We generated indices to measure the availability of staff, drugs, medical supplies and equipment at facilities. We created four indices related to facility staffing levels per 1000 population, one for each of three potential cadres: staff in the clinical cadre (including medical officers, assistant medical officers, clinical officers and clinical assistant), staff in the nursing cadre (including nurse officers, anaesthetists, registered nurses, nurse midwives, public health nurses and maternal and child health aides) and support staff (including medical attendants and health attendants). Support staffs are mainly holders of an ordinary secondary school certificate and have a pre-nursing certificate from a recognized institution. An index of total staff available per 1000 population was estimated by combining all items included in each of the three cadre-level indices. To measure staff per 1000 population, total staffs were divided by the facility catchment population and multiplied by a thousand. Catchment population data was extracted from the recent census which was conducted by the National Bureau of Statistics in Tanzania [42].

We grouped 37 drugs into 8 categories based on their therapeutic use in the clinical care guidelines of the Ministry of Health and Social Welfare, namely; anti-malarials (3); oxytocics (3); anti-hypertensives (4); antiretroviral therapy (ART) drugs (8); vaccines (6); antibiotics (6); anti-diarrhoeal (2) and others which includes normal saline, savlon, povidone iodine, eye drops and Rifampin, Isoniazid, Pyrazinamide and Ethambutol (RHZE) for tuberculosis treatment(5). We generated indices for each as well as an overall index by combining the above categories. Drugs were coded as 1 if available on the day of the survey and 0 if they were not available on the day of the survey. Indices were estimated as mean scores across all items within a category.

Equipment and medical supplies were coded as 1 if they were available or 0 if they were unavailable on the day of the survey. We generated an index of equipment availability as a mean score across all 15 equipment items, as well as an index of medical supply availability as a mean score across all 10 supply items, and an index of contraceptives containing 8 items.

Finally, we constructed an overall index for all non-staff inputs by generating a mean score across all non-staff items.

We measured the wealth of patients attending the health facilities – considered a proxy of the catchment population – by means of a wealth index that was developed using principal component analysis [23, 57]. Ownership of a total of 28 items was measured based on their inclusion in previous studies [57] (Additional file 1: Annex 1). Facilities were ordered based on their index score, and grouped into five equally sized groups (quintiles) from poorest to least poor.

We measured distance between the facility and the district headquarters in kilometres. Facilities were ordered based on their distance and grouped into five equally sized groups from most remote to least remote [58].

For each of the indices relating to the inputs, we estimated the mean index value for each of the quintiles of wealth/distance, as well as the standard deviation and tested for differences across wealth groups using the chi squared test. We estimated the pair-wise correlation coefficients between wealth and distance and health care inputs and assessed the statistical significance of the associations. Distance was inversely ranked implying that the closer facilities were better off compared to those which are far away.

In relation to wealth, we calculated the equity ratio, and concentration indices for each of the health care inputs (clinical staff, nursing staff, support staff, total staff; vaccination, antibiotics, anti-malarials, oxytocics, anti-hypertensive drugs, ART, anti-diarrhoeal; other drugs; equipment, medical supplies, contraceptives, and all non-staff inputs), to assess equity in their distribution. The equity ratio for a given index is calculated as the mean score in the least poor (least remote) quintile divided by the mean score in the poorest (most remote) quintile, with a ratio greater than one indicating pro-rich inequality. This index is chosen because of its simplicity, but has the disadvantage of not considering the full distribution across the population as a whole, and relying on each quintile’s equal size. Concentration indices and concentration curves are also generated as these are widely used in the literature on health inequalities and consider the distribution of inputs across the whole population [37, 59]. The concentration index is defined as twice the area between the concentration curve and the line of equality (the 45-degree line). The concentration curve plots the cumulative share of health care inputs by facilities ranked by the socio-economic status of their patients or by the distance from the headquarters. The distribution of a given health care input is considered pro-poor (pro-rich) if the concentration curve of a given health care input lies above (below) the line of equality, and if the concentration index is negative (positive). Dominance tests were used to explore the statistical significance of the differences between the concentration curves of health care inputs and the 45 degree line of equality. Dominance tests were conducted at 5% significance level using 19 quintile points and applying the multiple comparison approach (mca), as proposed in [44]. If the concentration curve for health care inputs used lies below the 45 degree line of equity, the 45 degree line of equity is said to dominate the concentration curve (D-).

Ethical clearance for this study was obtained from the Ifakara Health Institute Institutional Review Board (IRB), the Tanzanian National Institute for Medical Research (NIMR) and the London School of Hygiene & Tropical Medicine (LSHTM) Research Ethics Committee. District managers and health facility in-charges were informed about the study and written informed consent was obtained from each participant.

Additional file 1: Table S2 presents a correlation matrix showing the association between the availability of health care inputs, the wealth index and distance variable. There was a borderline significant positive association between the quantity of nurses per thousand population and the wealth of the facility catchment population (the correlation coefficient was 0.35) (Additional file 1: Table S2). The association between the quantity of staff and distance showed a negative association except for supportive staff, but these were not statistically significant.

Additional file 1: Table S3a and S3b present the distribution of health care inputs by wealth and distance quintiles. For both measures the distribution of staff is skewed towards the more advantaged (wealthier catchment areas and closer to the district headquarters). Facilities with the poorest patients (most remote facilities) have fewer staff per 1000 population than those with the least poor patients (least remote facilities) i.e. 0.6 staff per 1000 among the poorest, compared to 0.9 among the least poor; 0.7 staff per 1000 among the most remote facilities compared to 0.9 among the least remote. The distribution of clinical and nursing staff was pro-rich as demonstrated by the equity ratios and concentration indices (Additional file 1: Table S3a) and concentration curves (Fig. 1), with the distribution of nursing staff being the most pro-rich (CI: 0.122, p ~ 0.105 and CI: 0.167 p ~ 0.007). The negative concentration index (CI: −0.082, p ~ 0.331) for support staff suggests a pro-poor distribution of this cadre but the 45 degree dominated the concentration curve.

Vaccinations were the most widely available with almost all facilities reporting availability of vaccines on the day of the survey, irrespective of patient wealth and distance from the district headquarters, followed by anti-malarials at over 90% (Additional file 1: Tables S3a and S3b). While around half of facilities had essential antibiotics, anti- diarrhoeal and other drugs, facilities with poorer catchment populations were much less likely to stock oxytocics, anti-hypertensives or ARTs on the day of the survey than those with wealthier populations.

There was a significant positive (negative) correlation between wealth (distance) and the availability of ARTs (p ~ 0.000), and a significant positive association between wealth and the availability of anti-hypertensives and other drugs (p ~ 0.000), but the association was not significant for distance (Additional file 1: Table S2). There was a non-significant negative (positive) correlation between wealth (distance) for anti-malarial drugs, and a significant negative association between vaccines and distance (p ~ 0.042). The distribution of vaccines, antibiotics, anti-diarrhoeal and anti-malarials was approximately proportional (non dominance), whereas the distribution of oxytocics (CI: 0.114, p ~ 0.008), ART’s (CI: 0.366, p ~ 0.000) and anti-hypertensive (CI: 0.179, p ~ 0.001) drugs was pro-rich (see Fig. 2 and Additional file 1: Table S3a). However, only the distribution of ARTs achieved dominance.

Availability of essential equipment also varied across facilities, from being present in just over 50% of the poorest facilities, to just under 80% of the least poor, with medical supply availability varying between similar ranges. Contraceptives were available in around half of all facilities sampled.

There was a positive (negative) association between wealth (distance) and the availability of contraceptives, equipment and medical supplies, with contraceptives having the greatest association with wealth, and the availability of equipment having the greatest association with distance (Additional file 1: Table S2). Additional file 1: Tables S3a and S3b indicate that the concentration of medical equipment, supplies and contraceptives is higher in facilities serving least poor patients (least remote) than those servicing poorer patients (most remote). The distribution of contraceptives (CI: 0.117, p ~ 0.000) and medical equipment (CI: 0.087, p ~ 0.000) were pro-rich; however, there was non-dominance in both cases (Additional file 1: Table S3a and Fig. 3). The distribution of medical supplies was almost proportional (Additional file 1: Table S3a and Fig. 3).

Figure 4 depicts the overall distribution of inputs (excluding staff) in public primary health care facilities. The overall distribution of inputs excluding staff was marginally pro-rich (CI: 0.076, p ~ 0.000).