Abstract
Objective
To compare information on highly complex radiological procedures—computed tomography (CT) and magnetic resonance imaging (MRI)—between the public and private health care systems, across the five regions of Brazil, in terms of the numbers of radiological devices and examinations performed, between 2015 and 2021.
Materials and Methods
This was a descriptive time series analysis of secondary data in the public domain, available from the Information Technology Department of the Brazilian Unified Health Care System, an entity of the Brazilian National Ministry of Health (NMH) that is responsible for collecting and storing health-related information in Brazil. The analysis included the numbers of CT and MRI scanners; the volumes and types of examinations; the type of institution (public or private); the regions of the country; and the years (2015 to 2021).
Results
Progressive increases in the numbers of CT and MRI devices, as well as in the volumes of examinations, were observed over the years in all regions of the country. The private sector showed higher rates of equipment acquisition and of growth in the number of examinations. However, the public health care system did not reach the equipment targets set by the NMH, whereas the private health care system surpassed those targets. A greater number of examinations were performed in the private sector than in the public sector.
Conclusion
During the period evaluated, the public health care system did not meet the equipment or examination targets recommended by the NMH, in any of the regions of the country, unlike the private health care system, which exceeded both in all of the regions.
Keywords: Tomography, X-ray computed; Magnetic resonance imaging; Health information systems; Public sector; Private sector
Abstract
Objetivo
Comparar informações sobre procedimentos radiológicos de alta complexidade – tomografia computadorizada (TC) e ressonância magnética (RM) –, considerando o número de aparelhos e o quantitativo de exames nas esferas pública e privada nas cinco regiões brasileiras entre 2015 e 2021.
Materiais e Métodos
Trata-se de um estudo descritivo de série temporal que utilizou dados secundários do Departamento de Informática do Sistema Único de Saúde, órgão do Ministério da Saúde (MS) responsável pela coleta e armazenamento das informações relacionadas à saúde no Brasil. Analisamos os números de aparelhos e de exames de TC e RM, considerando os tipos de aparelhos e exames, instituição (pública ou privada), região brasileira e ano (2015 a 2021).
Resultados
Houve aumento de aparelhos e exames de TC e RM em todas as regiões ao longo dos anos. A esfera privada apresentou maior aquisição desses aparelhos e crescimento no número de exames. O sistema público não atingiu o número de aparelhos preconizado pelo MS, enquanto o sistema privado superou a recomendação. Observou-se maior número de exames na esfera privada quando comparada à pública.
Conclusão
O sistema público não atendeu aos números de aparelhos e exames realizados preconizados pelo MS, diferentemente da esfera privada, em todas as regiões no período estudado.
Keywords: Tomografia computadorizada, Ressonância magnética, Sistemas de informação em saúde, Setor público, Setor privado
INTRODUCTION
Diagnostic medicine is crucial in health care, encompassing a variety of examinations, including radiological imaging studies(1). Although the foundations of this area date back to the beginnings of medical science, it was thanks to technological advances and the deepening of disciplines such as physics, chemistry, and pathophysiology that it reached its current level of precision and applicability. Thus, diagnostic medicine has come to account for a significant portion of the health professional labor market and is expanding rapidly(2).
The Brazilian Sistema Único de Saúde (SUS, Unified Health Care System) aims to guarantee full, universal, free access to health care, including diagnostic medicine services, to all citizens(3). Therefore, radiological examinations are included among the procedures offered by the SUS, which categorizes them by the degree of complexity(4): medium complexity—radiography and ultrasound; and high complexity—computed tomography (CT) and magnetic resonance imaging (MRI). Despite being charged with providing these procedures by the federal government, the SUS is not always able to meet the high demand for them(3). Consequently, the concepts of complementary health care, which combines efforts from the private sector with those from the public sector, and supplementary health care, which refers to services provided via private health care plans, regulated and supervised by the Brazilian Agência Nacional de Saúde Suplementar (ANS, National Health Insurance Agency), have been incorporated(5).
The Information Technology Department of the SUS (DATASUS) is an organ of the Secretariat for Strategic and Participatory Management of the Brazilian National Ministry of Health (NMH), responsible for collecting, processing, storing, and disseminating data on health care services in Brazil, including radiological procedures of high complexity. The DATASUS obtains information from health care systems and institutions affiliated with the SUS, making it available to the general public and serving not only as a repository of information but also as a valuable tool for analyzing and understanding public health in the country(3,6,7). Those data influence decisions made by health care managers and professionals, allowing the identification of specific needs, the detection of trends, strategic planning, the appropriate allocation of resources, and evaluation of the results of implemented policies. In addition, making access to information open and free allows researchers and society in general to conduct studies, contributing to the body of scientific knowledge and monitoring of the health care system in Brazil(8).
Although the SUS provides most radiological procedures free of charge, it is estimated that there is inequality among the regions of Brazil, as well as between the public and private sectors, in terms of the distribution of equipment and the availability of examinations(9). Given this context, the objective of the present study was to compare the public and private sectors in all five regions of Brazil, on the basis of the information available in the DATASUS regarding highly complex radiological procedures (CT and MRI), considering the distribution and quantity of radiological equipment in use, as well as the volume of examinations carried out, between 2015 and 2021.
MATERIALS AND METHODS
This was a descriptive study employing secondary data from the DATASUS. The requirement for research ethics committee analysis was waived because the study used public-domain data, without any personal or identifiable information about the individuals involved. The study covered the entire territory of Brazil, including the five regions of the country (north, northeast, central-west, south, and southeast), for the period from 2015 to 2021.
Information systems
Highly complex equipment was defined as CT and MRI devices in operation, data on which are available from the National Registry of Health Care Facilities for each region of Brazil. Data regarding the number of examinations were collected from the Sistema de Informação Ambulatorial (SIA, Outpatient Information System) and Sistema de Informação Hospitalar (SIH, Hospital Information System) of the SUS. Data relating to supplementary health care were also analyzed.
Information from the National Registry of Health Care Facilities, the SIA, and the SIH are available from the DATASUS (https://datasus.saude.gov.br/), whereas data on supplementary health care are available on the ANS website (https://www.gov.br/ans/pt-br). To calculate proportions and coefficients, we used the population estimates available from the Instituto Brasileiro de Geografia e Estatística (IBGE, Brazilian Institute of Geography and Statistics) for the 2015–2021 period(10).
Data analysis
The processing, analysis, and organization of data, as well as the creation of graphs and tables, were carried out by two researchers (a fifth-year medical student and a radiologist with 17 years of experience), using the Microsoft Office Excel program, version 10.
To analyze the geographic distribution of CT and MRI devices and the annual numbers of examinations performed via the SUS, we followed the recommendations outlined in NMH Ordinance no. 1,631/2015(11) and the NMH booklet “Parameters for Scheduling Health Care Activities and Services of Medium to High Complexity Via the SUS”(12).
The calculations used in order to determine the quantity of CT and MRI equipment, as well as the number of MRI examinations, needed to serve the population of each region are shown in equations 1, 4, and 5. In NMH Ordinance no. 1,631/2015(11), there is no defined parameter for the number of CT examinations required, nor was that information found in any other NMH document.
Eq. 1 |
Eq. 2 |
Eq. 3 |
Eq. 4 |
Eq. 5 |
Annual number of CT scanners required per region
On the basis of NMH Ordinance no. 1,631/2015(11), which calls for 10 CT scanners per million inhabitants, the following equation was employed:
Annual number of MRI scanners required per region
According to NMH Ordinance no. 1,631/2015(11), the required number of MRI scanners is six per million inhabitants. The productivity of an MRI scanner is 5,000 examinations per year, and the estimated number of scans needed is 30 per 1,000 inhabitants:
where SR is the (number of) scans required.
To calculate the number of MRI scanners needed, the following equation was employed:
where N is the number of scanners needed and SR is the (number of) scans required.
That culminated in an equation for calculating the quantity of MRI scanners needed per region:
where NR is the number of scanners needed for the region.
Number of CT examinations required per year and region
Because NMH Ordinance no. 1,631/2015(11) does not provide information on the number of CT examinations required to serve the population per year and region, it was not possible to carry out a comparative analysis of those parameters.
Number of MRI examinations required per year and region
According to NMH Ordinance no. 1,631/2015(11), an estimated 30,000 MRI examinations are needed per million inhabitants in Brazil. To calculate the annual number of MRI scans required per region, we used the following equation:
where SR is the (number of) scans required.
Year-to-year percentage change
The annual percentage change was calculated for the population and for the number of highly complex examinations, as well as for the numbers CT and MRI scanners. That change was calculated with the following equation:
Eq. 6 |
where APC is the annual percentage change.
Average percentage growth
The average percentage growth for the 2015–2021 period was calculated for the population and for the number of highly complex examinations, as well as for the numbers of CT and MRI scanners. That growth was calculated with the following equation:
Eq. 7 |
RESULTS
Estimated population by region
According to IBGE estimates(10), there were population increases in all regions of Brazil over the years evaluated, with an average growth rate of 0.72% during the 2015–2021 period (Table 1).
Table 1.
Year | Region | Total | ∆A% | AG% | ||||
---|---|---|---|---|---|---|---|---|
Southeast | Northeast | South | North | Central-west | ||||
2015 | 85,745,520 | 56,560,081 | 29,230,180 | 17,472,636 | 15,442,232 | 204,450,649 | — | 0.72 |
2016 | 86,356,952 | 56,915,936 | 29,439,773 | 17,707,783 | 15,660,988 | 206,081,432 | 0.80 | |
2017 | 86,949,714 | 57,254,159 | 29,644,948 | 17,936,201 | 15,875,907 | 207,660,929 | 0.77 | |
2018 | 87,521,700 | 57,576,309 | 29,843,748 | 18,158,149 | 16,086,896 | 209.186.802 | 0.73 | |
2019 | 88,072,407 | 57,883,049 | 30,036,030 | 18,373,753 | 16,293,774 | 210.659.013 | 0.70 | |
2020 | 88,601,482 | 58,174,912 | 30,221,606 | 18,583,035 | 16,496,340 | 212,077,375 | 0.67 | |
2021 | 89,107,377 | 58,453,160 | 30,398,904 | 18,786,300 | 16,694,717 | 213,440,458 | 0.64 |
Source: IBGE(10). ∆A%, annual percentage change; AG%, average percentage growth during the 2015–2021 period.
Number of CT and MRI scanners needed in each region
The numbers of CT and MRI devices required in order to serve the population of each region of Brazil satisfactorily are shown in Table 2. An increase in the quantity of CT and MRI scanners needed was observed over the years in all regions (Table 2), following the trend of population growth.
Table 2.
Year | CT | MRI | ||||||||
---|---|---|---|---|---|---|---|---|---|---|
Southeast | Northeast | South | North | Central-west | Southeast | Northeast | South | North | Central-west | |
2015 | 857 | 566 | 292 | 175 | 154 | 514 | 339 | 175 | 105 | 93 |
2016 | 864 | 596 | 294 | 177 | 157 | 516 | 341 | 177 | 106 | 94 |
2017 | 869 | 573 | 296 | 179 | 159 | 522 | 344 | 178 | 108 | 95 |
2018 | 875 | 576 | 298 | 182 | 161 | 525 | 345 | 179 | 109 | 97 |
2019 | 881 | 579 | 300 | 184 | 163 | 528 | 347 | 180 | 110 | 98 |
2020 | 886 | 582 | 302 | 186 | 165 | 532 | 349 | 181 | 111 | 99 |
2021 | 891 | 585 | 304 | 188 | 167 | 535 | 351 | 182 | 113 | 100 |
Source: NMH Ordinance no. 1,631/2015.
Number of CT and MRI scanners in use in the public and private sectors in each region
During the 2015–2021 period, there were increases in the numbers of CT and MRI devices in use in all regions (Table 3), and those increases were more pronounced in the private sector. In all regions and years, the proportion of devices in use was highest in the private sector, which accounted for more than 60% of the equipment required for highly complex radiological examinations.
Table 3.
CT | Public sector | Private sector | ||||||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
Southeast n (%) | Northeast n (%) | South n (%) | North n (%) | Central-west n (%) | Total | ∆% | AG% | Southeast n (%) | Northeast n (%) | South n (%) | North n (%) | Central-west n (%) | Total | ∆% | AG% | |
2015 | 246 (12.8) | 155 (22.5) | 46 (6.9) | 39 (17.6) | 43 (11.7) | 529 | — | 7.6 | 1319 (68.6) | 483 (70.2) | 425 (63.4) | 171 (77) | 289 (78.7) | 2687 | — | 7.0 |
2016 | 263 (13.4) | 119 (16.5) | 49 (6.8) | 42 (18.2) | 41 (10.3) | 514 | -2.8 | 1353 (68.9) | 514 (71.1) | 455 (63.4) | 175 (75.8) | 319 (79.8) | 2816 | 4.8 | ||
2017 | 270 (12.8) | 137 (17.2) | 54 (7.1) | 45 (18) | 44 (9.6) | 550 | 7.0 | 1477 (69.9) | 565 (71.1) | 485 (64.2) | 190 (76) | 369 (80.6) | 3086 | 9.6 | ||
2018 | 271 (12) | 151 (18) | 57 (7) | 49 (17.6) | 46 (9.5) | 574 | 4.4 | 1584 (70.4) | 595 (70.4) | 527 (64.8) | 209 (72.2) | 392 (81) | 3307 | 7.2 | ||
2019 | 285 (12) | 160 (17.9) | 56 (6.3) | 50 (17.8) | 47 (8.6) | 598 | 4.2 | 1641 (66.8) | 635 (70.9) | 589 (66.6) | 208 (74) | 459 (83.6) | 3532 | 6.8 | ||
2020 | 351 (14.1) | 196 (20.4) | 64 (6.9) | 60 (19) | 61 (9.9) | 732 | 22.4 | 1665 (66.8) | 659 (68.5) | 619 (66.5) | 229 (72.7) | 507 (81.9) | 3679 | 4.2 | ||
2021 | 370 (13.8) | 224 (20.8) | 62 (6.3) | 73 (19.4) | 78 (11.3) | 807 | 10.2 | 1800 (67.4) | 733 (68.1) | 662 (66.8) | 274 (72.9) | 556 (80.3) | 4025 | 9.4 | ||
MRI | ||||||||||||||||
2015 | 58 (5.6) | 16 (5.5) | 10 (2,7) | 11 (10.9) | 4 (2.4) | 99 | — | 10.8 | 803 (77.4) | 247 (84.6) | 267 (2.7) | 84 (83.2) | 148 (89.7) | 1549 | — | 7.8 |
2016 | 69 (6.4) | 21 (6.4) | 10 (2,6) | 11 (10.0) | 3 (1.8) | 114 | 15.2 | 832 (77.6) | 280 (84.8) | 288 (73.5) | 93 (84.5) | 151 (88.8) | 1644 | 6.1 | ||
2017 | 70 (6.0) | 33 (8.6) | 12 (2,9) | 14 (10.8) | 5 (2.3) | 134 | 17.5 | 928 (78.9) | 319 (83.1) | 311 (74.2) | 109 (82.3) | 193 (89.4) | 1860 | 13.1 | ||
2018 | 67 (5.3) | 43 (10.3) | 15 (3,3) | 18 (12.2) | 6 (2.5) | 149 | 11.2 | 996 (79.4) | 346 (82.6) | 336 (74.0) | 121 (82.3) | 211 (89.0) | 2010 | 8.1 | ||
2019 | 70 (5.2) | 50 (10.6) | 14 (2,9) | 19 (12.6) | 6 (2.3) | 159 | 6.7 | 1061 (79.1) | 382 (81.3) | 363 (75.5) | 122 (80.8) | 233 (90.3) | 2161 | 7.5 | ||
2020 | 76 (5.5) | 52 (10.8) | 15 (2,9) | 18 (11.4) | 8 (2.6) | 169 | 6.3 | 1083 (78.5) | 393 (81.7) | 388 (74.9) | 130 (82.3) | 274 (89.9) | 2268 | 5.0 | ||
2021 | 77 (5.3) | 60 (11.4) | 16 (2,9) | 20 (11.1) | 9 (2.8) | 182 | 7.7 | 1146 (79.1) | 426 (81.0) | 415 (75.6) | 150 (83.3) | 292 (89.3) | 2429 | 7.1 |
Source: NMH – DATASUS (https://datasus.saude.gov.br/). ∆A%, annual percentage change; AG%, average percentage growth during the 2015–2021 period.
The proportion of CT scanners in use was higher in the private sector, ranging from 63.4% (in the southern region in December 2015) to 83.6% (in the central-west region in December 2019). In the public sector, the proportion of CT scanners in use ranged from 6.8% (in the southern region in December 2016) to 20.8% (in the northeastern region in December 2021).
The numbers of MRI scanners in use, in the public and private sectors, were highest in the southeastern region. Overall, the proportion of MRI devices in use was higher in the private sector, ranging from 73.0% (in the southern region in December 2015) to 90.3% (in the central-west region in December 2019). The proportion of MRI devices in use in the public sector ranged from 1.8% (in the central-west region in December 2016) to 12.6% (in the northern region in December 2019). Figure 1 compares the numbers of CT and MRI devices in use in the public and private sectors in the southeastern region. In the public sector, the average percentage growth was 7.6% for CT scanners and 10.8% for MRI scanners, compared with 7.0% and 7.8%, respectively, in the private sector.
Although the annual percentage growth was higher in the public sector, the target numbers of scanners, as defined in NMH Ordinance no. 1,631/2015(11), were not met in the public sector in any region of the country during the period under study (Table 4). In the private sector, the NMH target for CT scanners was met in all regions. For CT scanners in the public sector, the average percentages of the NMH target were quite similar among regions, being lowest in the southern region, whereas in the private sector, those percentages were lowest in the northern and northeastern regions. For MRI scanners, the private sector met the NMH target in all regions except the northeastern region, whereas the target was not met in the public sector in any of the regions, the percentages being lowest in the southern and central-west regions (Table 4).
Table 4.
CT | Public sector | Private sector | ||||||||
---|---|---|---|---|---|---|---|---|---|---|
Southeast (%) | Northeast (%) | South (%) | North (%) | Central-west (%) | Southeast (%) | Northeast (%) | South (%) | North (%) | Central-west (%) | |
2015 | 28.70 | 27.39 | 15.75 | 22.29 | 27.92 | 153.91 | 97. 71 | 145.55 | 85.34 | 187.66 |
2016 | 30.44 | 19.97 | 16.67 | 23.73 | 26.11 | 156.60 | 98.87 | 154.76 | 86.24 | 203.18 |
2017 | 31.07 | 23.91 | 18.24 | 25.14 | 27.67 | 169.97 | 106.15 | 163.85 | 98.60 | 232.08 |
2018 | 30.97 | 26.22 | 19.13 | 26.92 | 28.57 | 181.03 | 114.84 | 176.85 | 103.30 | 243.48 |
2019 | 32.35 | 27.63 | 18.67 | 27.17 | 28.83 | 186.27 | 113.04 | 196.33 | 109.67 | 281.60 |
2020 | 39.62 | 33.68 | 21.19 | 32.26 | 36.97 | 187.92 | 123.12 | 204.97 | 113.23 | 307.27 |
2021 | 41.53 | 38.29 | 20.39 | 38.83 | 46.71 | 202.02 | 145.74 | 217. 76 | 125.30 | 332.93 |
M | 33.53 | 28.15 | 18.58 | 28.05 | 31.83 | 176.82 | 103.10 | 180.01 | 114.21 | 255.46 |
MRI | ||||||||||
2015 | 11.28 | 4.72 | 5.71 | 10.48 | 4.30 | 156.23 | 72.86 | 152.57 | 80.00 | 159.14 |
2016 | 13.37 | 6.16 | 5.65 | 10.38 | 3.19 | 161.24 | 82.11 | 162.71 | 87.74 | 160.64 |
2017 | 13.41 | 9.59 | 6.74 | 12.96 | 5.26 | 177.78 | 92.73 | 174.72 | 100.93 | 203.16 |
2018 | 12.76 | 12.46 | 8.38 | 16.51 | 6.19 | 189.71 | 100.29 | 187. 71 | 111.01 | 217.53 |
2019 | 13.26 | 14.41 | 7.78 | 17. 27 | 6.12 | 200.95 | 110.09 | 201.67 | 110.91 | 237.76 |
2020 | 14.29 | 14.90 | 8.29 | 16.22 | 8.08 | 203.57 | 112.61 | 214.36 | 117.12 | 276.77 |
2021 | 14.39 | 17.09 | 8.79 | 17.70 | 9.00 | 214.21 | 121.37 | 228.02 | 132.74 | 292.00 |
M | 13.25 | 11.33 | 7.33 | 14.50 | 6.02 | 186.24 | 98.87 | 188.82 | 105.78 | 221.00 |
Source: NMH – DATASUS (https://datasus.saude.gov.br/). M, mean of the annual percentages of the targets set.
Number of CT and MRI examinations required
Recommended numbers of CT examinations needed in order to serve the population were not addressed in NMH Ordinance no. 1,631/2015(11). The recommended numbers of MRI examinations for each region are shown, by year, in Table 5.
Table 5.
Year | Southeast | Northeast | South | North | Central-west | Total |
---|---|---|---|---|---|---|
2015 | 2,572,366 | 1,696,802 | 876,905 | 524,179 | 463,267 | 6,133,519 |
2016 | 2,590,709 | 1,707,478 | 883,193 | 531,233 | 469,830 | 6,182,443 |
2017 | 2,608,491 | 1,717,625 | 889,348 | 538,086 | 476,277 | 6,229,828 |
2018 | 2,625,651 | 1,727,289 | 895,312 | 544,744 | 482,607 | 6,275,604 |
2019 | 2,642,172 | 1,736,491 | 901,081 | 551,213 | 488,813 | 6,319,770 |
2020 | 2,658,044 | 1,745,247 | 906,648 | 557,491 | 494,890 | 6,362,321 |
2021 | 2,637,221 | 1,753,595 | 911,967 | 563,589 | 500,842 | 6,403,214 |
Source: NMH Ordinance no. 1,631/2015.
Number of CT and MRI examinations performed in the public and private sectors
Tables 6 and 7 show that there were increases in the annual numbers of CT and MRI examinations performed via the public and private health care systems, respectively. However, during the period analyzed, the private health care system produced 20–80% more CT scans (depending on the year of analysis) than did the SUS.
Table 6.
Examination | Setting | Southeast | Northeast | South | North | Central-west | Total | ∆A% | AG% |
---|---|---|---|---|---|---|---|---|---|
CT | |||||||||
2015 | Outpatient | 1,271,139 | 373,769 | 149,872 | 135,510 | 147,298 | 3,624,501 | — | 13.3 |
Inpatient | 787,068 | 219,917 | 375,892 | 51,930 | 112,106 | ||||
2016 | Outpatient | 1,346,117 | 438,659 | 169,194 | 134,471 | 146,574 | 3,898,861 | 7.6 | |
Inpatient | 821,078 | 243,003 | 418 ,164 | 57,420 | 124,181 | ||||
2017 | Outpatient | 1,448,813 | 487,599 | 199,823 | 150,368 | 151,057 | 4,225,912 | 8.4 | |
Inpatient | 864,860 | 267,985 | 457,570 | 63,025 | 134,812 | ||||
2018 | Outpatient | 1,617,974 | 603,349 | 221,136 | 190,254 | 177,841 | 4,746,185 | 12.3 | |
Inpatient | 946,572 | 297,228 | 473,819 | 66,709 | 151,303 | ||||
2019 | Outpatient | 1,723,110 | 682,354 | 271,965 | 200,839 | 223,339 | 5,264,167 | 10.9 | |
Inpatient | 1,051,033 | 344,917 | 526,483 | 73,256 | 166,871 | ||||
2020 | Outpatient | 1,939,155 | 668,974 | 320,038 | 259,434 | 265,735 | 6,097,281 | 15.8 | |
Inpatient | 1,310,520 | 411,511 | 605,065 | 101,003 | 215,846 | ||||
2021 | Outpatient | 2,334,702 | 902,732 | 413,649 | 310,769 | 387,491 | 7,618,721 | 25.0 | |
Inpatient | 1,592,693 | 534,718 | 755,500 | 128,102 | 258,365 | ||||
MRI | |||||||||
2015 | Outpatient | 215,556 | 29,444 | 22,150 | 21,095 | 5,968 | 414,239 | — | 13.3 |
Inpatient | 55,410 | 21,939 | 35,627 | 2,354 | 4,696 | ||||
2016 | Outpatient | 219,945 | 39,995 | 27,557 | 26,804 | 3,379 | 444,062 | 7.2 | |
Inpatient | 57,167 | 21,020 | 40,160 | 3,123 | 4,912 | ||||
2017 | Outpatient | 240,999 | 49,864 | 33,655 | 32,654 | 6,541 | 503,295 | 13.4 | |
Inpatient | 60,427 | 23,714 | 47,232 | 3 ,174 | 5,035 | ||||
2018 | Outpatient | 268,850 | 77,769 | 49,186 | 33,763 | 6,315 | 585,325 | 16.3 | |
Inpatient | 64,233 | 25,792 | 51 , 617 | 2,426 | 5,374 | ||||
2019 | Outpatient | 288,305 | 105,315 | 72,405 | 36,463 | 7,830 | 674,608 | 15.3 | |
Inpatient | 71,660 | 27,372 | 55,069 | 4,036 | 6,153 | ||||
2020 | Outpatient | 251,130 | 88,761 | 62,390 | 19,065 | 8,576 | 595,603 | -11.7 | |
Inpatient | 74,832 | 26,296 | 52,609 | 4,236 | 7,708 | ||||
2021 | Outpatient | 297,174 | 128,317 | 82,051 | 29,522 | 15,178 | 731,627 | 25.0 | |
Inpatient | 82,325 | 28,813 | 53,766 | 5,574 | 8,907 |
Source: NMH – SIA/SUS, SIH/SUS, and ANS. ∆A%, annual percentage change; AG%, average percentage growth during the 2015–2021 period.
Table 7.
Examination | Sector | Total | ∆A% | AG% | ||||
---|---|---|---|---|---|---|---|---|
Self-management | Physician cooperative | Philanthropic organization | Group medicine | Health insurance company | ||||
TC | ||||||||
2015 | 737,649 | 2,131,723 | 103,323 | 1,727,442 | 1,934,674 | 6,634,811 | 6.6 | 6,4 |
2016 | 786,991 | 2,280,114 | 120,090 | 1,883,028 | 2,000,731 | 7,070,954 | 1.7 | |
2017 | 786,286 | 2,412,265 | 114,633 | 2,088,633 | 1,788,413 | 7,190,230 | 2.7 | |
2018 | 927.101 | 2,655,113 | 121,396 | 2,215,510 | 1,467,756 | 7,386,876 | 3.7 | |
2019 | 944,313 | 2,803,590 | 149,713 | 2,463,543 | 1,298,379 | 7,659,538 | -3.8 | |
2020 | 877,447 | 3,111,304 | 138,508 | 2,251,446 | 987,547 | 7,366,252 | 27.4 | |
2021 | 1,113,543 | 4,235,570 | 187,013 | 2,787,194 | 1,059,909 | 9,383,229 | 6.6 | |
RM | ||||||||
2015 | 806,473 | 2,246,656 | 80,505 | 1,585,843 | 1,791,700 | 6,511,177 | 8.8 | 4,2 |
2016 | 840,782 | 2,443,979 | 109,448 | 1,846,670 | 1,846,107 | 7,086,986 | 4.5 | |
2017 | 841,904 | 2,539,008 | 149,716 | 2,069,345 | 1,806,840 | 7,406,813 | 6.7 | |
2018 | 977,725 | 2,733,888 | 159,371 | 2,094,971 | 1,878,512 | 7,904,467 | 5.5 | |
2019 | 1,034,872 | 2,844,075 | 244,500 | 2,354,308 | 1,860,654 | 8,338,409 | -23.7 | |
2020 | 768,572 | 2,440,436 | 113,322 | 1,867,064 | 1,174,451 | 6,363,845 | 23.1 | |
2021 | 917,694 | 3,064,225 | 145,758 | 2,465,236 | 1,241,372 | 7,834,285 | 8.8 |
Source: NMH – SIA/SUS, SIH/SUS, and ANS. ΔA%, annual percentage change; AG%, average percentage growth during the 2015–2021 period.
The number of MRI examinations performed annually was also greater in the private sector than in the public sector. Notably, the total numbers of MRI examinations performed via the SUS did not reach the recommended numbers stipulated in NMH Ordinance no. 1,631/2015(11). Although the NMH has not stipulated recommended numbers of CT examinations, the data show that many more CT scans were performed in the private sector than in the public sector in all of the years studied, as illustrated in Figure 2. The recommended number of MRI examinations was not reached by the public health care system in any region of the country. However, the private system exceeded that number in all the years analyzed, as indicated in Figure 3.
DISCUSSION
In this study, we have compared the availability of CT and MRI equipment and examinations between the public and private sectors, in all regions of Brazil, between 2015 and 2021. The most striking finding was the lack of compliance of the public health care system in relation to government guidelines, with the numbers of devices available and numbers of examinations performed being greater in the private health care system, in all regions of the country.
Similar, previous studies have addressed only one imaging method(13), have covered CT and MRI but only in one Brazilian state(14), have compared only the distribution of equipment(15), have evaluated only the public health care system(13,15), or have been restricted to only one imaging method in only one specific geographic area(16). However, they all produced results similar to those of the present study, either by showing unequal distribution of equipment and examinations between the public and private sectors, with a predominance in the private sector(13,14,17), or by highlighting the fact that, in most regions of Brazil, the public health care system has not met the goals set by the NMH, for CT or for MRI(14,15,16). In the present study, we have provided an up-to-date overview of the distribution of CT and MRI devices in Brazil, as well as the number of examinations, in the public and private sectors, comparing them with the target values established in NMH Ordinance no. 1,631/2015(11), in all regions of the country.
Studies conducted prior to the advent of NMH Ordinance no. 1,631/2015(11) have also shown that the availability of equipment is greater in the private sector than in the public sector(13,15,17), highlighting the fact that the SUS has not obtained the number of devices recommended by the NMH in most regions of Brazil(14). In this context, it is worth remembering that, within the SUS, the accessibility of a procedure decreases as the complexity of the procedure increases(17). Our findings corroborate those data by demonstrating that, even after the implementation of NMH Ordinance no. 1,631/2015(11), the deficits in relation to highly complex radiological examinations persist in the SUS.
The challenges in Brazil include limited geographic access to essential health services via the SUS and the concentration of wealth in certain locations(18). Many SUS users live in underserved areas, which requires them to travel long distances to access health resources(14,18). Our data underscore that inequality by demonstrating a greater concentration of equipment and examinations in the southeastern region of the country, where much of the wealth is concentrated. In addition, the majority of the Brazilian population does not participate in the private health care system(19), in which there is a greater concentration of equipment and through which greater numbers of examinations are performed, a fact that heightens the inequality in health care access(17,20,21). In the present study, it was evident that the majority of CT and MRI scanners in Brazil are in service in the private sector. Therefore, the majority of the population faces difficulties in accessing highly complex examinations, either because of geographic barriers to undergoing those via the SUS or because of a lack of financial resources to resort to the private sector (complementary or supplementary health care).
It is of note that only 28.5% of Brazilian citizens have private health insurance(22) . However, as observed in our research, the private sector owns most of the equipment and performs most of the highly complex (CT and MRI) examinations. Therefore, the majority of the available resources are accessed by less than 30% of the population and the majority of the population depends on the public health care system, which has many fewer resources. That results in a discrepancy between the demand for highly complex examinations and the real capacity to access such examinations. According to Federal Law no. 8080, the SUS is responsible for formulating the policy on medicines, equipment, biologic agents, and other material of interest to health, as well as for participating in their production(23). However, government investment in public health in Brazil is likely to be insufficient(24), especially with recent reductions in public investment in all social spheres, including health(25). The financial management of the SUS, influenced by neoliberal economic policy, has contributed to a reduction of social capital, as have the increase in privatization and the support for large corporations(26). Although there have been increases in the numbers of CT and MRI scanners acquired by the SUS, as well as in the numbers of CT and MRI examinations performed therein, the public health care system has not kept pace with the private system. During the period analyzed, the public sector, in isolation, was unable to meet the demand for highly complex procedures according to the recommendations of NMH Ordinance no. 1,631/2015(11).
According to the IBGE, an annual average, in Brazilian reals (R$), of R$2,035.60 per capita is invested in family and institutional expenses related to health care in the private sector, compared with R$1,349.60 per capita invested in the public health care sector(10). In 2019, the average per capita health expenditure in Organisation for Economic Co-operation and Development (OECD) countries exceeded $4,000. The United States led with $11,000. Switzerland spent two-thirds of that amount, whereas Norway and Sweden spent a bit more than half of what was spent in the United States. Brazil is among the smallest investors in the OECD, investing less than half of the average but more than nations such as Indonesia and India(27). Spending on health in Brazil has reached 9.6% of the gross domestic product, with 5.8% going to the private sector, more than double the OECD average, which was 2.3%. As for spending on public health, Brazil appears near the bottom of the list of OECD countries, allocating only 3.8% of its gross domestic product to the SUS. Albeit ahead of Mexico, Brazil is behind European countries and other Latin American countries such as Colombia and Chile(10,27). Although our study does not directly evaluate health spending in the public and private sectors, our analysis of the increases in the numbers of scanners and the total numbers of examinations performed over the years allows us to verify the discrepancy in spending between the two sectors.
In the United States, most people obtain health insurance through their employers or separately from private companies(28,29), although some access health care services through government programs for specific populations, such as the elderly and low-income individuals(29,30). In Canada, however, the government guarantees universal access to health care for all citizens(31). In those two countries, imaging methods such as CT and MRI are becoming more widely used, representing some of the main services paid for by health insurance(28,32,33). Although those methods facilitate the diagnosis and treatment, they can also generate costs and risks, such as overdiagnosis(28,34). In this context, it is estimated that 30% of the imaging examinations performed in the United States and Canada are unnecessary(28,35). In Brazil, which has a public health care system similar to that of Canada, there is also a trend toward excessive imaging examinations(36). Our study demonstrated that much higher numbers of tests were performed in the private sector than in the public sector, raising the question of whether those values were related to overdiagnosis, similar to what has been reported for other countries(28,34,35,36). However, the databases used in the present study do not provide information about the indications for the examinations, and further studies are needed in order to confirm our assumption.
Our study has some limitations: a) the lack of information in the DATASUS about the number of joint public-private initiatives existing in the country and the amount of equipment and examinations managed by such initiatives, although that does not invalidate the results of our analyses; b) the fact that the NMH does not establish parameters regarding the annual number of CT examinations needed to serve the population, as well as that the ANS does not provide the number of examinations performed in the private sector by region; c) the fact that our analysis of the equipment covered in our study was quantitative, rather than qualitative, making it impossible to compare factors such as time of use and the state of maintenance of the devices; d) the fact that although philanthropic organizations are technically within the private sector, they must allocate at least 60% of their services to the SUS(37). However, neither the DATASUS nor the ANS delineate the proportion of examinations carried out by philanthropic organizations within the scope of the SUS. Despite these limitations, our data can guide public bodies in managing the availability of resources, as well as demonstrating existing gaps in the DATASUS where there is room for improvement. Future perspectives include the incentive to carry out other, more in-depth studies on the topic.
CONCLUSION
In all regions of Brazil and during all of the years evaluated, the public sector had lower numbers of devices and of highly complex radiological (CT and MRI) examinations than did the private sector. In addition, in the SUS, there was a notable lack of compliance with the parameters outlined in NMH Ordinance no. 1,631/2015(11).
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