Abstract
The number of orthopedic surgeries is increasing as populations steadily age, but surgical site infection (SSI) rates remain relatively consistent. This study aimed to quantify the healthcare resources attributable to methicillin-resistant Staphylococcus aureus (MRSA) SSIs in orthopedic surgical patients. The analysis was conducted using a national claims database comprising data from almost all Japanese residents. We examined patients who underwent any of the following surgeries between April 2012 and March 2018: amputation (AMP), spinal fusion (FUSN), open reduction of fracture (FX), hip prosthesis (HPRO), knee prosthesis (KPRO), and laminectomy (LAM). Propensity score matching was performed to identify non-SSI control patients, and generalized estimating equations were used to estimate the differences in outcomes between the case and control groups. The numbers of MRSA SSI cases (infection rates) ranged from 64 (0.03%) to 1,152 (2.33%). MRSA SSI-attributable increases in healthcare expenditure ranged from $11,630 ($21,151 vs. $9,521) for LAM to $35,693 ($50,122 vs. $14,429) for FX, and increases in hospital stay ranged from 40.6 days (59.2 vs. 18.6) for LAM to 89.5 days (122.0 vs. 32.5) for FX. In conclusion, MRSA SSIs contribute to substantial increases in healthcare resource utilization, emphasizing the need to implement effective infection prevention measures for orthopedic surgeries.
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Introduction
Orthopedic surgeries are increasingly prevalent, with over 1 million primary total arthroplasties (both hip and knee)1 and 180,000 spine surgeries2 conducted in the US annually. In Japan, 195,000 primary total arthroplasties and 122,000 spine surgeries are performed every year3. Furthermore, the numbers of these surgeries are reportedly rising in the US4 and the UK5. Due to rapidly aging populations and longer life expectancies, orthopedic surgeries are likely to steadily increase in many countries.
Despite the high efficacy and success rates of orthopedic surgeries, a non-negligible proportion of these procedures require reoperations due to infection6. Although the infection rates in arthroplasty and spine surgeries are relatively low4,7, the occurrence of these infections can have a heavy impact on morbidity, mortality, and costs8,9. Surgical site infection (SSI) rates following arthroplasty have remained largely unchanged between 2005 and 20154. In view of the growing volume of orthopedic surgeries, the economic impact of postoperative infections cannot be ignored. However, few studies have examined the additional use of healthcare resources required to treat orthopedic surgical patients with SSIs across a wide variety of medical institutions.
This study aimed to quantify the additional healthcare resources (i.e., healthcare expenditure and hospitalization duration) attributable to SSIs in orthopedic surgical patients in Japan using national-level data. The analysis focused on SSIs caused by methicillin-resistant Staphylococcus aureus (MRSA), which accounts for a large proportion of these infections in many countries.
Results
The analysis was conducted using a total of 3,078,777 patients across the 6 target surgery types. The number of MRSA SSI cases and infection rates for each surgery type according to infection definition are presented in Table 1. When MRSA SSI cases were defined as patients who had been administered anti-MRSA antibiotics for 7 days or more and had undergone surgical debridement (i.e., the base case definition), the number of MRSA SSI cases (infection rate) for amputation (AMP), spinal fusion (FUSN), open reduction of fracture (FX), hip prosthesis (HPRO), knee prosthesis (KPRO), and laminectomy (LAM) were 1,152 (2.33%), 1,279 (0.23%), 1,046 (0.08%), 567 (0.09%), 257 (0.07%), and 64 (0.03%), respectively. With the exception of AMP, the SSI rates did not exceed 1% among the surgery types. When debridement was not included in this definition, infection rates were substantially increased by 7.01% (LAM) to 0.14% (AMP).
The characteristics of patients with and without MRSA SSI before propensity score matching are summarized according to surgery type in Table 2. SSI patients tended to have higher Charlson comorbidity index (CCI) scores and higher proportions of men, older patients, diabetic patients requiring insulin, and patients requiring dialysis. The proportion of patients with rheumatic disease was high for all surgery types except AMP. In the propensity score-matched groups, the absolute values of the standardized difference were < 10% for all baseline characteristics (Table 3).
Table 4 shows the results of the regression analysis with MRSA SSI occurrence (base case) as the dependent variable. In all 6 surgery types, the analysis identified men, diabetes status, dialysis treatment, and CCI score to be significantly associated with MRSA SSI occurrence. Furthermore, rheumatic disease was significantly associated with MRSA SSI occurrence for FUSN, FX, and HPRO. Among FUSN patients, the month of surgery was associated with MRSA SSI occurrence, where surgeries in May to October had odds ratios of 1.48 to 1.84. Among HPRO patients, May, July, and August had odds ratios of 1.63, 1.58, and 1.72, respectively, for MRSA SSI occurrence.
The estimates of MRSA SSI–attributable healthcare expenditure and length of hospital stay (LOS) from the generalized estimating equations after propensity score matching are presented in Table 5. In all surgery types, MRSA SSIs were significantly associated with increases in healthcare expenditure and LOS. The analysis estimated MRSA SSI–attributable increases in healthcare expenditure of $33,290 ($53,003 vs. $19,713) for AMP, $28,858 ($48,461 vs. $19,603) for FUSN, $35,693 ($50,122 vs. $14,429) for FX, $24,252 ($47,784 vs. $23,532) for HPRO, $24,667 ($47,120 vs. $22,453) for KPRO, and $11,630 ($21,151 vs. $9,521) for LAM. The analysis also estimated MRSA SSI–attributable increases in LOS of 69.4 days (118.6 vs. 49.2) for AMP, 61.1 days (90.4 vs. 29.3) for FUSN, 89.5 days (122.0 vs. 32.5) for FX, 75.0 days (118.1 vs. 43.1) for HPRO, 74.9 days (115.1 vs. 40.2) for KPRO, and 40.6 days (59.2 vs. 18.6) for LAM.
The annual budget impact analysis (Table 6) estimated that MRSA SSIs in orthopedic surgeries were associated with additional expenditures of $6.39 million for AMP, $6.15 million for FUSN, $6.22 million for FX, $2.29 million for HPRO, $1.06 million for KPRO, and $120,000 for LAM. The total budget impact for all 6 procedures was $22.24 million.
Discussion
In an analysis of national-level claims data, this study quantified the economic impact of MRSA SSIs in over 3 million patients across 6 types of orthopedic surgery. Orthopedic surgeries have relatively low SSI rates, and few studies have produced quantitative estimates of the additional healthcare resources attributable to these infections. The estimates presented in this study therefore provide new evidence from (to the best of our knowledge) the largest dataset of orthopedic surgeries to date.
For studies that quantify MRSA SSI–attributable increases in healthcare expenditure, the use of patients with antibiotic-susceptible infections (“replacement” model where resistant infections replace susceptible infections in the total disease burden) versus the use of patients without infections (“addition” model where resistant infections add to the total disease burden) as the comparison group is a point of debate10,11,12. This lack of consensus among researchers is exemplified in the variety of approaches used to explore the disease burden of antibiotic-resistant infections, with some studies using the replacement model13,14, some using the addition model15,16,17, and others using a combination of both18,19. This study utilizes the addition model with a control group comprising non-SSI patients. In another study conducted in Japan, Uematsu et al. reported that MRSA infections had significantly higher healthcare expenditures than patients with methicillin-susceptible S. aureus infections using the replacement model20. While the existing literature contains studies that have utilized either approach, we consider that both strategies have value in contributing to our understanding of the disease burden of antibiotic-resistant infections, and support the development of effective measures against disease transmission and the improvement of antibiotic use to reduce the selection of resistant bacterial strains. In this way, our study provides valuable data for the addition model.
This study represents, to the authors’ knowledge, the first report from Japan that examines MRSA SSI occurrence, risk factors, and attributable healthcare expenditure in a variety of orthopedic surgery types in Japan. Previous studies in Japan have addressed the antimicrobial susceptibility of pathogens21, trends in reoperation for MRSA SSIs in spinal surgery patients only22, SSI incidence in orthopedic surgery patients23, and additional healthcare expenditures attributable to MRSA infections not limited to SSIs20,24. However, these studies have not focused on MRSA SSIs in orthopedic surgery patients. Furthermore, a strength of this study is that separate analyses were conducted for 6 different orthopedic surgery types, which provides insight into the differential impact of MRSA SSI among these procedures.
As this study was conducted without data on microbiological test results and SSI surveillance, MRSA SSI cases were identified using information on anti-MRSA antibiotics available in claims data. This method of analyzing MRSA cases is similar to that used in Uematsu et al., which examined the additional expenditures associated with MRSA infections24. As a consequence, the MRSA cases identified in this study may also include infections by methicillin-resistant Staphylococcus epidermidis (MRSE) and coagulase-negative staphylococci (CNS). The Japanese government established the Japan Nosocomial Infections Surveillance (JANIS) program in 2000 to monitor the incidence and prevalence of nosocomial infections in voluntary participant hospitals. According to that program, the rates of deep incisional and organ/space SSIs caused by MRSA, MRSE, and CNS in 2017 were 0.20% for AMP, 0.31% for FUSN, 0.10% for FX, 0.08% for HPRO, 0.08% for KPRO, and 0.25% for LAM25. While our SSI rates were similar to these estimates for FUSN, FX, HPRO, and KPRO, our estimated SSI rate for AMP was 10 times that reported by the JANIS program. Many AMP patients undergo amputations for gangrene of the lower leg due to infections or ischemia, and a large proportion of these patients have severe infections prior to surgery26. Therefore, our antibiotic-based SSI identification method may have included patients who had been receiving long-term antibiotic treatment that continued after surgery. Our analysis may also have underestimated SSI rates for LAM. When compared with the other surgery types, LAM patients without infection tended to have short LOS durations below 30 days, which may have caused us to overlook SSIs that occurred after being discharged. Systematic reviews have estimated S. aureus SSI rates in the US and Europe to be 1.7% and 0.6%, respectively, after arthroplasty8 and 1.9% and 1.0%, respectively, after spine surgery9. However, the possible inclusion of non-MRSA infections in our subjects makes direct comparisons of these rates problematic. Nevertheless, when considering that MRSA accounts for 40–50% of S. aureus infections9 and that our MRSA SSI cases may also include MRSE and CNS infections, our estimated MRSA SSI rates are likely to be lower than those reported in the US and Europe.
After propensity score matching, the healthcare expenditure attributable to MRSA SSIs was 2.03 (HPRO) to 3.47 (FX) times more than the control patients, and the additional LOS attributable to MRSA SSIs was 2.41 (AMP) to 3.75 (FX) times more than the control patients. Several studies have reported that patients with SSIs have healthcare expenditures that are 1.4–3.7 times more than that of uninfected patients after arthroplasty8, but few of these studies have focused on MRSA infections. Edwards et al. compared the additional healthcare expenditures between 39 MRSA cases and 41 non-MRSA controls, and found that the expenditure for the cases was only 1.19 times (P = 0.964) that of the controls27. However, it should be noted that their findings were susceptible to influence by the small sample size. In addition, few studies have compared healthcare expenditures between patients with and without SSIs after spine surgery. Kuhns et al. reported that the healthcare expenditure of SSI cases was 2.29 times that of non-SSI controls among spine surgical patients28, but that study was a single-institutional analysis that did not take into consideration the causative pathogens. Accordingly, our study is the first to use large-scale data to quantify the additional healthcare expenditure attributable to MRSA SSIs in orthopedic surgical patients.
The findings of this study should be interpreted with consideration to the following limitations. First, MRSA SSIs were identified through the use of anti-MRSA antibiotic prescription patterns. Japanese guidelines recommend the discontinuation of antimicrobial prophylaxis within 24 or 48 h (depending on surgery type) after orthopedic surgery29. Therefore, our use of a 7-day cut-off for anti-MRSA antibiotic administration reduces the likelihood of misidentifying cases with routine prophylaxis as those being treated for MRSA infections. However, these antibiotics may have targeted infections other than SSI, and we sought to more accurately identify SSI cases through our database by including surgical debridement for the base case analysis. In addition, anti-MRSA antibiotics are also used to treat MRSE and CNS SSI cases, which may have been included in our subjects. According to the JANIS program, the proportions of MRSA SSIs among all methicillin-resistant staphylococcal SSIs are 100% for AMP, 72.8% for FUSN, 80.2% for FX, 77.1% for HPRO, 60.0% for KPRO, and 60.5% for LAM25. Second, we only analyzed infections that occurred during the index hospitalization. Although the US Centers for Disease Control and Prevention recommends a 90-day follow-up period after orthopedic surgery to detect SSIs30, patients who developed SSIs after being discharged were not included in our analysis. However, due to the relatively long hospitalizations for non-SSI patients in Japan (as shown in Table 5), we expect that a large proportion of SSIs would be detected during the initial hospitalization.
Conclusions
This study analyzed an unprecedented number of patients to quantify the potential economic burden of MRSA SSIs after orthopedic surgery. As the world’s population continues to age, orthopedic surgeries are expected to become increasingly common. Although these surgeries are associated with relatively low infection rates, MRSA SSIs can have an inordinately heavy clinical and economic impact. Our findings indicate a need to explore further measures to prevent SSIs after orthopedic surgeries. As this study was conducted using almost all eligible patients in Japan, our estimates may also have applications when investigating the cost-effectiveness of such measures.
Methods
Study design
Using a national-level claims database, this study employed a retrospective case–control design to quantify the differences in healthcare expenditure and LOS between orthopedic surgical patients with MRSA SSIs (i.e., cases) and those without any SSIs (i.e., controls). Control patients were identified using propensity score matching (Fig. 1).
The study was approved by the Kyushu University Institutional Review Board for Clinical Research (Approval Number 30–149), which acts in accordance with the ethical standards laid down in the “non-interventional clinical research” in Japan. The Kyushu University Institutional Review Board for Clinical Research also allowed the researchers to waive the requirement for obtaining informed consent because of the retrospective nature of the study and the use of anonymized data.
Database
Data were obtained from the National Database of Health Insurance Claims and Specific Health Checkups of Japan (NDB). The NDB collects and anonymizes all insurance claims data sent from medical institutions to insurers for the purpose of reimbursement, and provides anonymized datasets to authorized researchers for analysis after an application and review process. As Japan utilizes a universal health insurance system, the database encompasses data from all Japanese residents who use healthcare services covered by insurance. The claims data include detailed information on recorded diagnoses on admission, surgical procedures, pharmaceuticals, and healthcare expenditure, but lack clinical information regarding diagnostic testing and vital signs. The study subjects were identified using surgical procedures and prescription patterns, and the designated outcomes were compared between the case and control patients.
Patients
The subjects comprised patients who had been hospitalized for orthopedic surgery between April 1, 2012 and March 31, 2018. We analyzed the following 6 orthopedic surgery types: AMP, FUSN, FX, HPRO, KPRO, and LAM. Based on the International Classification of Diseases, Ninth Revision, Clinical Modification codes employed by the US National Healthcare Safety Network31, each surgery type was identified using the corresponding Japanese surgical procedure codes.
To examine patients with primary surgery and exclude cases of recent reoperations, we limited the analysis to patients who had not undergone any of the 6 target surgery types between April 2010 and March 2012. In addition, patients who underwent any of the 6 target surgery types after the index surgery were excluded from analysis.
Definition of MRSA SSI and Non-SSI
The NDB does not include results of blood tests, diagnostic microbiological tests, or antimicrobial susceptibility tests. As an alternative method to identify MRSA SSI cases, we examined the postoperative prescriptions of anti-MRSA antibiotics in each patient. Bolon et al. have previously identified SSI cases as patients who were administered antibiotics for 7 days or more after surgery32. Based on this criterion, we analyzed prescriptions of linezolid, vancomycin, teicoplanin, arbekacin, and daptomycin, which represent anti-MRSA antibiotics that are covered under insurance in Japan. To more accurately identify SSI cases, the base case analysis focused on patients who had also undergone surgical debridement.
As a sensitivity analysis, we also identified MRSA SSI cases as those who were administered anti-MRSA antibiotics for 5 days or more after surgery. Furthermore, not all SSI cases would have undergone surgical debridement. Therefore, this study identified MRSA SSI cases using the following 4 definitions: (1) patients administered anti-MRSA antibiotics for 7 days or more and had undergone surgical debridement, (2) patients administered anti-MRSA antibiotics for 5 days or more and had undergone surgical debridement, (3) patients administered anti-MRSA antibiotics for 7 days or more, and (4) patients administered anti-MRSA antibiotics for 5 days or more. The first definition was used in the base case analysis, and the remaining 3 definitions were used in the sensitivity analysis.
To estimate the differences in healthcare resources used between the MRSA SSI cases and non-SSI controls, we excluded all patients with suspected SSIs (including those with non-MRSA SSIs) from the latter. Specifically, we identified and excluded all orthopedic surgical patients who were administered any antibiotic for 5 days or more after surgery or had undergone surgical debridement from the control group.
Outcomes
The primary outcome was healthcare expenditure during hospitalization for orthopedic surgery. Healthcare expenditure in this study referred to the amount billed by the medical institutions to the insurers for the provision of healthcare to each patient, and therefore represents costs from the insurer’s perspective. In Japan, the fee schedule for medical goods and services undergoes minor revisions every 2 years, and our study period included 3 periods (2012–2013, 2014–2015, and 2016–2018) in which the unit prices may vary. For this analysis, all unit prices were adjusted to 2018 prices by applying the revision rates for each year of data. Japanese yen were converted to US dollars using the purchasing power parity rate in 2017 ($1.00 = 102.5 yen). The secondary outcome was LOS, which was calculated as the number of days from the date of admission to the date of discharge for the index hospitalization.
Statistical analysis
We first identified MRSA SSI cases among the patients hospitalized for orthopedic surgery between April 1, 2012 and March 31, 2018. Corresponding non-SSI controls were then identified using propensity score matching. Propensity scores were calculated for each of the 4 definitions of MRSA SSI using logistic regression models with SSI occurrence or non-occurrence as the dependent variable. The independent variables included diabetes status, dialysis treatment, rheumatic disease, sex, age, month of surgery, and CCI score. Several meta-analyses have identified diabetes status as a risk factor of SSI33,34,35. In this study, we analyzed 4 different statuses: no diabetes, recorded diabetes diagnosis, prescription of antidiabetic agents, and administration of insulin. The use or non-use of dialysis was also examined. Similarly, rheumatic disease has been previously reported to be an SSI risk factor33,34, and was identified in this study using the relevant recorded diagnoses in the claims data. As seasonal variability has been reported to be a risk factor of SSI36,37,38,39, each patient’s month of surgery was included in the regression models as a dummy variable. We then performed 1:1 matching with non-SSI control patients without replacement using a caliper width of 0.25 standard deviations of the logit of each propensity score. Standardized differences were used to test for balances between the case and control groups.
When analyzing healthcare resource utilization, a proportion of cases with inordinately high expenditures or protracted hospitalizations may shift the distribution of utilization such that it resembles a gamma distribution instead of a normal distribution40,41. If calculating the differences in mean healthcare resource utilization between the case and control groups with the assumption of a normal distribution, the presence of such outliers may introduce bias into the estimates. Alternatively, modal values can be used, but these would not provide insight into the mean healthcare resource utilization attributable to infections, and are not suitable for use in national-level budget impact analyses. As a result, the utilization of the case and control groups were estimated after propensity score matching using generalized estimating equations under the assumption of a gamma distribution. These estimates were used to calculate the mean healthcare expenditure and LOS attributable to MRSA SSIs.
All statistical analyses were performed using Stata/MP version 15.1 (Stata Corp., College Station, Texas, USA). P values (two-tailed) below 0.05 were considered statistically significant.
Budget impact
To estimate the total direct medical costs of MRSA SSI in orthopedic surgeries to Japan’s healthcare system, we quantified the annual budget impact of these infections. The budget impact was estimated using the total number of MRSA SSI base cases (i.e., those administered anti-MRSA antibiotics for 7 days or more and had undergone surgical debridement). As the study was conducted using 6 years of data, the annual budget impact was calculated using the mean annual number of cases and the MRSA SSI–attributable healthcare expenditure estimates produced in the main analysis. As a sensitivity analysis, we calculated the lower and upper limits of the MRSA SSI–attributable healthcare expenditures using the mean ± 2 standard deviations.
Data availability
The data that support the findings reported here were obtained from the Japanese Ministry of Health, Labour and Welfare under license for the current study, and are not publicly available due to restrictions stipulated by the ministry.
References
Kurtz, S. M., Ong, K. L., Lau, E. & Bozic, K. J. Impact of the economic downturn on total joint replacement demand in the United States: updated projections to 2021. J. Bone. Joint. Surg. Am. 96, 624–630 (2014).
Bernstein, D. N., Brodell, D., Li, Y., Rubery, P. T. & Mesfin, A. Impact of the economic downturn on elective lumbar spine surgery in the United States: a national trend analysis, 2003 to 2013 Global. Spine. J. 7, 213–219 (2017).
Ministry of Health, Labour and Welfare. 3rd NDB Open Data Japan. https://www.mhlw.go.jp/stf/seisakunitsuite/bunya/0000177221_00002.html. [in Japanese] (2016)
Kurtz, S. M. et al. Are we winning or losing the battle with periprosthetic joint infection: trends in periprosthetic joint infection and mortality risk for the medicare population. J. Arthroplasty. 33, 3238–3245 (2018).
National Joint Registry for England, Wales, Northern Ireland, and the Isle of Man. 18th Annual Report. https://www.njrreports.org.uk/Portals/0/PDFdownloads/NJR%2015th%20Annual%20Report%202018.pdf. (2018)
Delanois, R. E. et al. Current epidemiology of revision total knee arthroplasty in the United States. J. Arthroplasty. 32, 2663–2668 (2017).
Chahoud, J., Kanafani, Z. & Kanj, S. S. Surgical site infections following spine surgery: eliminating the controversies in the diagnosis. Front. Med. (Lausanne) 1, 7 (2014).
Patel, H., Khoury, H., Girgenti, D., Welner, S. & Yu, H. Burden of surgical site infections associated with arthroplasty and the contribution of Staphylococcus aureus. Surg. Infect. (Larchmt) 17, 78–88 (2016).
Patel, H., Khoury, H., Girgenti, D., Welner, S. & Yu, H. Burden of surgical site infections associated with select spine operations and involvement of Staphylococcus aureus. Surg. Infect. (Larchmt) 18, 461–473 (2017).
Limmathurotsakul, D. et al. Improving the estimation of the global burden of antimicrobial resistant infections. Lancet. Infect. Dis. 19, e392–e398 (2019).
Temkin, E. & Carmeli, Y. Zero or more: methodological challenges of counting and estimating deaths related to antibiotic-resistant infections. Clin. Infect. Dis. 69, 2029–2034 (2019).
Mostofsky, E., Lipsitch, M. & Regev-Yochay, G. Is methicillin-resistant Staphylococcus aureus replacing methicillin-susceptible S. aureus?. J. Antimicrob. Chemother. 66, 2199–2214 (2011).
Thorpe, K. E., Joski, P. & Johnston, K. J. Antibiotic-resistant infection treatment costs have doubled since 2002, now exceeding $2 billion annually. Health. Aff. (Millwood) 37, 662–669 (2018).
Johnston, K. J., Thorpe, K. E., Jacob, J. T. & Murphy, D. J. The incremental cost of infections associated with multidrug-resistant organisms in the inpatient hospital setting-a national estimate. Health. Serv. Res. 54, 782–792 (2019).
Ammerlaan, H. S. M. et al. Secular trends in nosocomial bloodstream infections: antibiotic-resistant bacteria increase the total burden of infection. Clin. Infect. Dis. 56, 798–805 (2013).
Ho, P. L., Kin-Hung Chow, K. H., Lai, E. L., Lau, E. H. Y. & Cheng, V. C. C. Extended-spectrum-β-lactamase-positive Escherichia coli mainly adds to, rather than replaces, extended-spectrum-β-lactamase-negative E coli in causing bacteraemia in Hong Kong, 2000–10. J. Antimicrob. Chemother. 67, 778–780 (2012).
Kraker, M. E. A. et al. Clinical impact of antimicrobial resistance in European hospitals: excess mortality and length of hospital stay related to methicillin-resistant Staphylococcus aureus bloodstream infections. Antimicrob. Agents. Chemother. 55, 1598–1605 (2011).
Anderson, D. J. et al. Clinical and financial outcomes due to methicillin resistant Staphylococcus aureus surgical site infection: a multi-center matched outcomes study. PLoS ONE 4, e8305 (2009).
Zhen, X. et al. Clinical and economic impact of methicillin-resistant Staphylococcus aureus: a multicentre study in China. Sci. Rep. 10, 3900 (2020).
Uematsu, H. et al. Effect of methicillin-resistant Staphylococcus aureus in Japan. Am. J. Infect. Control. 46, 1142–1147 (2018).
Takesue, Y. et al. Antimicrobial susceptibility of pathogens isolated from surgical site infections in Japan: Comparison of data from nationwide surveillance studies conducted in 2010 and 2014–2015. J. Infect. Chemother. 23, 339–348 (2017).
Kobayashi, K. et al. Trends in reoperation for surgical site infection after spinal surgery with instrumentation in a multicenter study. Spine (Phila Pa 1976) Online ahead of print.
Kadono, Y. et al. Statistics for orthopedic surgery 2006–2007: data from the Japanese diagnosis procedure combination database. J. Orthop. Sci. 15, 162–170 (2010).
Uematsu, H., Yamashita, K., Kunisawa, S., Fushimi, K. & Imanaka, Y. Estimating the disease burden of methicillin-resistant Staphylococcus aureus in Japan: Retrospective database study of Japanese hospitals. PLoS ONE 12, e0179767 (2017).
Ministry of Health, Labour and Welfare. Japan Nosocomial Infections Surveillance Annual Report 2017. https://janis.mhlw.go.jp/report/open_report/2017/3/5/SSI_Open_Report_201700.xlsm (2017).
Hassan, M. A. et al. Insight into multidrug-resistant microorganisms from microbial infected diabetic foot ulcers. Diabetes. Metab. Syndr. 13, 1261–1270 (2019).
Edwards, C., Counsell, A., Boulton, C. & Moran, C. G. Early infection after hip fracture surgery: risk factors, costs and outcome. J. Bone. Joint. Surg. Br. 90, 770–777 (2008).
Kuhns, B. D. et al. Cost and quality of life outcome analysis of postoperative infections after subaxial dorsal cervical fusions. J. Neurosurg. Spine. 22, 381–386 (2015).
Japanese Society of Chemotherapy and Japan Society for Surgical Infection. Guidelines for Appropriate Antimicrobial Prophylaxis for the Prevention of Postoperative Infections. https://www.chemotherapy.or.jp/guideline/jyutsugo_shiyou_jissen.pdf [in Japanese] (2016).
Centers for Disease Control and Prevention, National Healthcare Surveillance Network (NHSN). Procedure-associated Module, Surgical Site Infection Event. Available from: https://www.cdc.gov/nhsn/pdfs/pscmanual/9pscssicurrent.pdf (2019).
National Healthcare Safety Network. Procedure-Associated Module SSI. https://apic.org/Resource_/TinyMceFileManager/Academy/ASC_101_resources/Surveillance_NHSN/CDC_NHSN_SSI_Event_Jan_2014.pdf (2014).
Bolon, M. K. et al. Improved surveillance for surgical site infections after orthopedic implantation procedures: extending applications for automated data. Clin. Infect. Dis. 48, 1223–1229 (2009).
Resende, V. A. C. et al. Higher age, female gender, osteoarthritis and blood transfusion protect against periprosthetic joint infection in total hip or knee arthroplasties: a systematic review and meta-analysis. Knee. Surg. Sports. Traumatol. Arthrosc. in press.
Zhu, Y. et al. Risk factors for periprosthetic joint infection after total joint arthroplasty: a systematic review and meta-analysis. J. Hosp. Infect. 89, 82–89 (2015).
Pesenti, S. et al. What are the risk factors for surgical site infection after spinal fusion? A meta-analysis. Eur. Spine. J. 27, 2469–2480 (2018).
Durkin, M. J. et al. Postoperative infection in spine surgery: does the month matter?. J. Neurosurg. Spine. 23, 128–134 (2015).
Anthony, C. A. et al. The seasonal variability of surgical site infections in knee and hip arthroplasty. J. Arthroplasty. 33, 510–514 (2018).
Gruskay, J. et al. The seasonality of postoperative infection in spine surgery. J. Neurosurg. Spine. 18, 57–62 (2013).
Kane, P. et al. Seasonality of infection rates after total joint arthroplasty. Orthopedics. 37, e182–e186 (2014).
Manning, W. G. & Mullahy, J. Estimating log models: to transform or not to transform?. J. Health. Econ. 20, 461–494 (2001).
Fukuda, H. et al. Impact of surgical site infections after open and laparoscopic colon and rectal surgeries on postoperative resource consumption. Infection 40, 649–659 (2012).
Acknowledgments
We are grateful to Mr. S. Kondo and Mr. S. Yamakawa from Denno Labo Corporation for their support in extracting the study sample from the National Database (NDB).
Funding
This work was supported by a Grant-in-Aid for Health Sciences Research from the Ministry of Health, Labour and Welfare of Japan (Grant Number: H30-Seisaku-Shitei-003) and JSPS KAKENHI Grant Numbers 17H04144 and 19K22781.
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H.F., D.S., T.I., K.Y., and K.M. contributed to the study’s conception and design. H.F. carried out the analysis of the data and drafted the manuscript. All authors were involved in the interpretation of the results, as well as in the editing and revision of the manuscript.
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Fukuda, H., Sato, D., Iwamoto, T. et al. Healthcare resources attributable to methicillin-resistant Staphylococcus aureus orthopedic surgical site infections. Sci Rep 10, 17059 (2020). https://doi.org/10.1038/s41598-020-74070-4
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DOI: https://doi.org/10.1038/s41598-020-74070-4
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