Risk of stroke after unilateral or bilateral TKA (simultaneous and staged without discharge) in 327,438 matched patients using data from the National Health Insurance Claims for South Korea

DOI: https://doi.org/10.21203/rs.3.rs-19817/v3

Abstract

Background: Limited data is available regarding the incidence rate and risk factors for stroke associated with unilateral total knee arthroplasty (TKA) and bilateral TKA. This study aims to investigate the incidence rate and risk factors of stroke in patients treated with bilateral TKA compared with patients with unilateral TKA.

Methods: In this retrospective nationwide cohort study, we compared patients undergoing unilateral TKA or bilateral TKA using data from the Korean National Health Insurance claims database between January 1, 2009 and August 31, 2017 and included patients older than 40 years of age who underwent primary TKA by the index date as documented primary diagnosis and first additional diagnosis without a history of stroke during the preceding 1 year. We used matched Cox regression models to compare the incidence rate and risk factors of newly acquired stroke among patients treated with unilateral TKA or bilateral TKA after propensity score (PS) matching.

Results: In the present study, 163,719 patients who received unilateral TKA were matched to163,719 patients with bilateral TKA (simultaneous and staged without discharge) based on PS. The risk of stroke during the study period was lower in patients treated with bilateral TKA than in patients with unilateral TKA (adjusted hazard ratio [HR] 0.79; P<0.001). Patients who received bilateral TKA were at decreased risk of stroke when the following variables were present: advanced age (70-79 years, HR 0.76; P<0.001), female sex (HR 0.75; P<0.001), rural area (HR 0.77; P<0.001), small- or medium-sized hospital (HR 0.75; P<0.001), health insurance (HR 0.77; P<0.001), history of hypertension drug use (HR 0.75; P<0.001), congestive heart failure (HR 0.70; P=0.032), connective tissue disease (HR 0.71; P=0.01), diabetes (HR 0.77; P<0.001), and diabetes with complication (HR 0.76; P=0.034).

Conclusions: The risk of stroke was lower in patients treated with bilateral TKA (simultaneous and staged without discharge) than in patients with unilateral TKA. Patients treated with bilateral TKA were at decreased risk of stroke when the following variables were present: age (70-79 years), female sex, health insurance, history of hypertension drug use, and comorbidities, such as congestive heart failure, connective tissue disease, and diabetes. More importantly, we do state that those with simultaneous bilateral TKA and staged bilateral TKA without discharge could have been healthier. This is precisely what the guidelines implemented by South Korea for patient selection aim to do and our data show that the risk of stroke is not increased in selected patients undergoing SiBTKA and StBTKA without discharge. Therefore, those who underwent 2 unilateral TKAs could have been at more risk of stroke, especially in the 2nd unilateral TKA.

Background

Total knee arthroplasty (TKA) is the most efficacious and successful treatment for advanced osteoarthritis (OA) of the knee.[1, 2] However, 23% of patients scheduled for unilateral TKA show severe symptoms in the contralateral knee and 93% of patients required a contralateral TKA within 5 years of index surgery.[3] Moreover, unilateral deformity correction for patients with severe deformities creates asymmetric lower limb alignment that can significantly affect rehabilitation.[4] Thus, simultaneous bilateral TKA (SiBTKA) and staged bilateral TKA (StBTKA) without discharge have increased in popularity due to shorter overall recovery time and decreased total cost compared with unilateral TKA and StBTKA with discharge.[5] However, SiBTKA and StBTKA without discharge are associated with potential issues such as increased perioperative complications, including pulmonary embolism, deep vein thrombosis, and stroke.[6, 7] Stroke after TKA is a rare but catastrophic complication associated with high rates of morbidity and mortality.[8] Although the risk of stroke after TKA has been investigated in numerous studies, only small sample sizes were used, which can lead to reduced statistical power.[4, 9] In addition, the incidence and risk factors of stroke in patients treated with unilateral TKA compared with subjects with bilateral TKA have been investigated in only a few large-scale studies.

We performed a nationwide, population-based, retrospective cohort study using the National Health Insurance (NHI) claims database, participation in which is compulsory and required by Korean law and covers up to 98% of the approximately 50 million people in South Korea.[10] Korea’s national registries have recently been the source of numerous epidemiological studies, demonstrating high completeness and validity, with an overall predictive value of diagnosis of 83.4%.[11] We designed the present study to investigate the incidence rate and risk factors of stroke in patients treated with unilateral TKA compared with subjects with bilateral TKA. It was hypothesized that the risk of stroke would be lower in patients treated with bilateral TKA than in patients with unilateral TKA.

Methods

Study design and data source

This nationwide, population-based, retrospective cohort study used the Korean NHI claims database (diagnoses based on International Classification of Disease, 10th Revision [ICD-10] codes and procedure history based on Electronic Data Interchange [EDI] codes), which includes all claims data from the Korean NHI program and the Korean Medical Aid program from 2009 until 2016; the data are integrated into the Health Insurance Review and Assessment Service (HIRA) database to include all healthcare utilization data for both inpatients and outpatients. These data contained a de-identification code representing patient age, sex, diagnosis, hospital admissions, dates of visits, and procedure history.[10, 12] Additionally, prescribed drug information containing the generic name, prescription date, and duration of prescription was included. The Institutional Review Board (IRB) of our institution approved the study. Consent was specifically waived by the IRB because all personal identifying information was removed from the database. 

Selection of study sample and definitions

The outcomes of interest were incidence rate and risk factors of new-onset postoperative stroke in patients treated with unilateral TKA compared with subjects with bilateral TKA. The study population comprised individuals older than 40 years of age who received TKA (EDI: N2072, N2077) without history of stroke (ICD-10: I60, I61, I62, I63) during the preceding 1 year, as documented by primary diagnosis and first additional diagnosis in the NHI database between January 1, 2009 and December 31, 2016. Patients treated with bilateral TKA were classified into two groups: patients who underwent SiBTKA and had two primary TKA procedure codes entered on the same day and patients who underwent StBTKA and had two primary TKA procedure codes entered without discharge. Similarly, patients treated with unilateral TKA were classified into two groups: patients who underwent only one TKA during the study period and patients who underwent a second TKA more than 6 months after discharge of index TKA. This is because the planned-staged cohort (more than 6 months) does not appear to be directly related to the index TKA for the risk of cardiovascular complication. New-onset postoperative stroke was defined as history of stroke from the date of primary admission or re-admission for stroke in the hospital following TKA.All patients who were deemed to have had a stroke within 12 months after TKA were identified. Patients considered eligible for newly acquired stroke included subjects who received computed tomography (CT) and magnetic resonance imaging (MRI) within one week after admission as well as subjects undergoing relevant surgical procedures, such as burr hole, craniectomy, craniotomy, or thrombectomy. To assess the diagnostic accuracy of the stroke cases registered in the NHI program, we reviewed the image sets and medical records of all registered stroke patients who received TKA at a single medical center. Two neurosurgeons independently investigated whether registered and suspected cases met the diagnostic criteria for strokes released by NHI. 

Potential confounders

Patient characteristics, comorbidities, and co-medication were considered as confounders in this study. Characteristics were age, sex, location, hospital size, and insurance type. Comorbidities comprised acquired immune deficiency syndrome (AIDS), congestive heart failure (CHF), chronic kidney disease (CKD), chronic obstructive pulmonary disease (COPD), connective tissue disease, transient ischemic attack (TIA), dementia, hemiplegia, myocardial infarction (MI), peptic ulcer disease (PUD), peripheral vascular disease (PVD), liver disease, severe liver disease, malignancy, diabetes, diabetes with complication, atrial fibrillation (AF), valvular heart disease (VHD), carotid artery disease (CAD), and hypothyroidism based on previous diagnoses within one year before the index date. In addition, the Charlson Comorbidities Index was calculated for all patients [13]; those with no comorbidities received a score of 0 points. Information on the use of drugs was based on a three-month period within one year before the index date because, in South Korea, drugs are generally prescribed for three months and are typically used on a continuous basis. Potent anticoagulants, such as aspirin, vitamin K antagonist, factor Xa inhibitor, and direct thrombin inhibitor, also were selected as confounders because they have been used for thrombophylaxis following TKA. In addition, hospitals were classified into two groups based on size (large: tertiary hospital or general hospital; small or medium: hospital or clinic). In the Korean health care system, the parent category of hospitals includes subcategories of hospitals, general hospitals, and tertiary hospitals, the requirements for whose qualifications are stated by Korean law. As a subcategory, a hospital signifies a small hospital in Korea (30-100 beds). General hospitals are hospitals equipped with more than 100 beds and several specialty departments as designated by law, and tertiary hospitals are large-sized university hospitals selected by the government. 

Statistical analysis

The results of the study should be randomly selected to ensure that there is no difference in characteristics. However, case-control study works on a specific group, so there is no random assignment, and selection bias cannot be avoided.

PS-based analyses were used to simultaneously control for a large number of covariates and to mimic some of the particular characteristics of a randomized controlled trial; these analyses provide a more robust, less biased estimate when the number of outcome events is low relative to the number of confounders.[14] PS matching is a method of matching the most similar PS. In this study, PS was calculated using logistic regression and performed one-to-one nearest neighbor matching based on the estimated PS. We fit a logistic regression model to estimate the probability of treatment with unilateral TKA versus bilateral TKA, adjusted for all covariates including age category, sex, comorbidities, and co-medication. We evaluated the balance of measured confounders before and after weighting using absolute standardized differences and considered balance as an absolute value less than 0.1, which has been used in the literature as the definition of a negligible difference.[15, 16] We calculated the incidence rate per 1,000,000 person-years by dividing the number of stroke events by the total number of person-years at risk and multiplying the result by 1,000,000. The 95% confidence interval (CI) was calculated assuming a Poisson distribution. Subgroup analysis was conducted based on age category, sex, location, hospital size, insurance type, comorbidities and co-medication. Adjusted hazard ratio (HR) and 95% CI were calculated using multivariate logistic regression modelling after adjusting for age, sex, location, hospital size, co-medication, and comorbidities. In addition, a sensitivity analysis was conducted to assess the influence of residual confounding based on insurance type. All analyses were conducted using SAS Enterprise software version 6.1 (SAS Institute, Cary, NC, USA) and R software version 3.4.1 (R Foundation for Statistical Computing, Vienna, Austria).

Results

Among the 373,847 patients identified from the Korean NHI claims database who met the inclusion criteria, 210,128 underwent unilateral TKA and 163,719 bilateral TKA. The logistic model by which the PS was estimated showed predictive value (C statistic = 0.843), which is a reasonable level detecting differences between the two groups in the outcome variables. After applying the PS matching, 327,438 patients were included in the comparative analysis of unilateral TKA versus bilateral TKA. The details of the cohort selection process are summarized in Figure 1. The association of incidence of stroke and annual procedure volume after unilateral TKA or bilateral TKA in South Korea during the study period is shown in Figure 2, indicating that the incidence of stroke decreased steadily regardless of the type of surgery. The decrease in SiBTKA over time in Korea was unlikely to affect our results because PS matching allowed us to match each patient within the smaller SiBTKA cohort with the patient in the second TKA more than 6 months after discharge of index TKA or unilateral TKA cohort who had the most similar patient characteristics. These two subjects were then removed from the group, and the process continued in the same fashion until each patient in the SiBTKA cohort had been matched with a patient in the second TKA more than 6 months after discharge of index TKA or unilateral TKA cohort.

Table 1 shows the baseline characteristics of patients treated with unilateral TKA compared with subjects with bilateral TKA in the overall and PS-matched cohorts. After PS matching, the two groups were balanced in terms of baseline covariates (Fig. 3). Among patients who received unilateral TKA, 1,411 (0.86%) developed stroke; 1,168 (82.8%) cases were ischemic and the remaining 243 (17.2%) were hemorrhagic stroke, whereas 1,120 patients (0.68%) who underwent bilateral TKA developed stroke; 905 (80.8%) cases were ischemic and the remaining 215 (19.2%) were hemorrhagic stroke. Of the patients experiencing new-onset stroke, 301 (21.3%) treated with unilateral TKA and 220 (19.7%) with bilateral TKA experienced a stroke within two weeks.

Table 2 shows the risk of stroke in subgroups based on surgical type, age, sex, location, hospital size, insurance type, comorbidities, and co-medication. The risk of stroke during the entire study period was lower in patients treated with bilateral TKA than in patients with unilateral TKA (HR 0.79, 95% CI: 0.73 to 0.85). Furthermore, patients who received bilateral TKA were at a decreased risk of stroke when the following variables were present: advanced age (70-79 years, HR 0.76, 95% CI: 0.69 to 0.84), female sex (HR 0.75, 95% CI: 0.71 to 0.86), rural area (HR 0.77, 95% CI: 0.70 to 0.86), small- or medium-sized hospital (HR 0.75, 95% CI: 0.68 to 0.83), health insurance (HR 0.77, 95% CI: 0.71 to 0.84), history of hypertension drug use (HR 0.75, 95% CI: 0.54 to 1.04), CHF (HR 0.70, 95% CI: 0.51 to 0.97), connective tissue disease (HR 0.71, 95% CI: 0.54 to 0.92), diabetes (HR 0.77, 95% CI: 0.67 to 0.89), and diabetes with complication (HR 0.76, 95% CI: 0.59 to 0.98).

Table 3 shows the association of unilateral TKA with bilateral TKA after adjusting for variables that were significant on univariate analysis, indicating that the risk of stroke was lower in patients treated with bilateral TKA than in patients with unilateral TKA (adjusted HR 0.79, 95% CI: 0.73 to 0.86). The sensitivity analysis also supported this finding after adjusting for the same variables as in multivariate analysis and insurance type.

Discussion

In this nationwide cohort study, patients treated with bilateral TKA had a significantly lower rate of stroke (adjusted HR 0.79) than patients with unilateral TKA. These findings conflict with results in a previous study that showed no significant difference between unilateral TKA and bilateral TKA with respect to postoperative stroke evaluated in a single institution.[9] Furthermore, subgroup analyses stratified based on the factors that affect outcome showed that patients treated with bilateral TKA had a lower risk of postoperative stroke than patients with unilateral TKA when the following variables were present: age (70-79 years), female sex, health insurance, history of hypertension drug use, and comorbidities such as CHF, connective tissue disease, and diabetes.

Sex differences are specific characteristics of postoperative stroke with respect to clinical manifestations and outcomes. In a general surgical population, the manifestations of postoperative stroke were found more frequently in female patients than in male patients.[17] In contrast, when investigating different patient-related factors and their association with postoperative stroke, the risk of stroke was not significantly different between female and male patients.[9] Notably, in the present study, the risk of stroke was significantly decreased in both male (HR 0.79) and female (HR 0.75) patients treated with bilateral TKA compared with subjects with unilateral TKA, indicating that Korean female patients treated with unilateral TKA have an increased risk of stroke. The mechanism by which the risk of stroke is increased in female patients remains unclear. Proposed explanations for the association between stroke and female sex include a higher rate of embolism in females than males and decreased sensitivity to anticoagulant agents.[18, 19] Another potential explanation is that a substantial number of female patients treated with unilateral TKA who required prophylactic anticoagulant agents might be at greater risk of stroke due to lack of use of prophylactic anticoagulant agents during the postoperative period compared with patients with bilateral TKA even though prophylaxis with universal anticoagulant agents is not generally recommended to patients undergoing TKA in South Korea because the incidence of postoperative stroke is relatively low.[20]

CHF is a commonly reported cardiac complication after bilateral TKA because of  suboptimal cardiopulmonary reserve in patients with preexisting comorbid medical conditions and in elderly patients, resulting in greater need for monitoring cardiopulmonary parameters, subsequently leading to a higher rate of admission to the intensive care unit patients treated with bilateral TKA than patients with unilateral TKA.[21, 22] Conversely, in previous studies with relatively small cohorts, significant differences were not reported in terms of cardiac complications between unilateral TKA and bilateral TKA.[23, 24] The large differences among study findings is likely caused by the small numbers of patients enrolled in individual studies. In the present study, a nationwide population-based cohort analysis of 210,128 patients treated with unilateral TKA and 163,719 patients with bilateral TKA was performed, and CHF was most strongly associated with new-onset stroke in patients treated with unilateral TKA. In the current study, patients who received bilateral TKA were divided into two groups: patients who underwent SiBTKA and had two primary TKA procedure codes entered on the same day and patients who underwent StBTKA and had two primary TKA procedure codes entered without discharge. These situations may better identify healthier patients or medically optimized patients who had received bilateral TKA, and the results adequately represent the real-world incidence and disease association.

Unexpectedly, other factors such as advanced age, connective tissue disease, and diabetes were all high risk factors for developing postoperative stroke in patients treated with unilateral TKA. This could be explained by the fact that patients treated with unilateral TKA may be more likely to experience stress and complications associated with preexisting conditions affecting the heart and kidneys which can lead to an ischemic stroke because part of those subjects come from candidates for SiBTKA through a selective preoperative screening process. This suggests that these patients have less access to be under the care of neurologists and may not receive optimal treatment of preexisting comorbidities.

Patients receiving hypertension drug use (non-cardioselective β-blockers), not surprisingly, had a higher incidence of postoperative stroke resulting from inhibition of β2-mediated cerebral vasodilation.[25] We found that hypertension drug use was a high risk factor for developing postoperative stroke in patients treated with unilateral TKA. These results may be attributable to the fact that patients treated with unilateral TKA have more patients receiving non-cardioselective β-blocker therapy, leading to a higher incidence of postoperative hypotension and bradycardia, subsequently increasing postoperative stroke.

This study had several limitations. First, the NHI claims database may contain incorrect diagnoses. To minimize this issue, patients with new-onset stroke were defined as subjects whose documented admission yielded principal diagnoses of stroke, patients who were administered relevant CT or MRI within one week after admission, or subjects who were undergoing surgical procedures for new-onset stroke. Second, lifestyle factors, such as smoking status, alcohol consumption, and dietary data, were not evaluated although they could affect the development of stroke. Moreover, we were unable to capture patients who died from a stroke. These seem important since some patients die before reaching the hospital. Third, not every patient needs a TKA on the opposite knee. Thus, all other kinds of unilateral patients who may have had bilateral osteoarthritis but were only treated with TKA on one side should be excluded from these analyses because it was too risky or too frail to operate the other side later. But, we could not adjust for potential confounders such as the severity levels of comorbidities because the Korean NHI claims database did not provide it and substantial criteria in deciding, which of the two modalities to recommend. Fourth, we do not have any information regarding postoperative outcomes such as infection, blood transfusion, length-of-rehabilitation, range of motion, and functional outcome. Clinical information available in the Korean NHI claims database is insufficiently reported and thus have limited effect in this comparative analysis. Additionally, we could not report the perioperative protocols used for the cases because of the inability to account for the effect of individual surgeons, the absence of measures that could characterize the severity of the joint disease, the dose of perioperative medications, the type of DVT prophylaxis, and mobilization therapy although they could affect the development of stroke. Fifth, we have a likely biased sample in that those who are deemed eligible for bilateral TKA after screening are healthier than those who undergo unilateral TKA even though we have attempted to limit such bias with multivariate logistic regression analysis and propensity score matching. Finally, a one-year period may not be sufficient to exclude all pre-existing strokes. However, the possibility of selection bias in both unilateral and bilateral TKA groups was equal. Despite these limitations, to the best of our knowledge, this is the first nationwide epidemiological study in which the incidence and risk factors for stroke in patients treated with unilateral TKA or bilateral TKA were evaluated using matched control patients.

Conclusions

The risk of stroke was lower in patients treated with bilateral TKA (simultaneous and staged without discharge) than in patients with unilateral TKA. Patients treated with bilateral TKA were at a decreased risk of stroke when the following variables were present: age (70-79 years), female sex, health insurance, history of hypertension drug use, and comorbidities such as CHF, connective tissue disease, and diabetes. More importantly, we do state that those with SiBTKA and StBTKA without discharge could have been healthier. This is precisely what the guidelines implemented by South Korea for patient selection aim to do and our data show that the risk of stroke is not increased in selected patients undergoing SiBTKA and StBTKA without discharge. Therefore, those who underwent 2 unilateral TKAs could have been at more risk of stroke, especially in the 2nd unilateral TKA.

List of Abbreviations

TKA: total knee arthroplasty; PS: propensity score; PSM: propensity score matching; SiBTKA: simultaneous bilateral TKA; StBTKA: staged bilateral TKA; NHI: National Health Insurance

Declarations

Ethics approval and consent to participate

The current study includes the name of the ethics committee and the committee’s reference number. 

Consent for publication

Consent was specifically waived by the approving IRB because all personal identifying information was removed from the database. 

Availability of data and materials

The datasets used and/or analysed during the current study are available within the manuscript. 

Competing interests

The authors declare that they have no competing interests. 

Funding

No benefits in any form have been received or will be received from a commercial party related directly or indirectly to the subject of this article, nor have any funds been received in support of this study. 

Authors' contributions

YSS was responsible for the study concept and design, and supervised the study. SBH, JRY, JYC, and SSL were responsible for analysis and interpretation of data. SBH and JRY wrote the first draft of the manuscript, and YSS critically revised the manuscript. YSS did the statistical analysis. YSS is the study guarantor, had full access to all of the data in the study and takes responsibility for the integrity of the data, and the accuracy of the data analysis, and had the final responsibility to submit for publication. 

Acknowledgements

The authors did not receive any outside funding or grants in support of their research for or preparation of this work. The authors would like to thank Mr. Kwang-Young Jung and Ms. Jae-Ok Park for her help in preparing the manuscript.

References

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Tables

Table 1. Baseline characteristics of patients with unilateral total knee arthroplasty, compared to those with bilateral total knee arthroplasty, in overall cohort and PS matched cohort.

 

Characteristic

Overall cohort

Standardised

difference

PS

Standardised

difference

Unilateral TKA, n=210 128

Bilateral TKA, n=163 719

Unilateral TKA, n=163 719

Bilateral TKA, n=163 719

Demographics

Stroke type, n (%)

 

 

0.029

 

 

0.021

ischemic

1641 (83.5)

905 (80.8)

 

1168 (82.8)

905 (80.8)

 

hemorrhagic

324 (16.5)

215 (19.2)

 

243 (17.2)

215 (19.2)

 

Time since TKA, n (%)

 

 

0.028

 

 

0.220

< 2 weeks

402 (20.5)

220 (19.7)

 

301 (21.3)

220 (19.7)

 

2-6 weeks

130 (6.6)

84 (7.5)

 

94 (6.7)

84 (7.5)

 

6-12 weeks

185 (9.4)

120 (10.7)

 

126 (8.9)

120 (10.7)

 

3-6 months

451 (22.9)

231 (20.6)

 

313 (22.2)

231 (20.6)

 

6-12 months

797 (40.6)

465 (41.5)

 

577 (40.9)

465 (41.5)

 

Mean in-hospital stay ± SD, d (%)

17.9 ± 8.5 (100)

SB SiB 18.1 ± 9.3 (23.7)/ 

0.728

17.7 ± 8.3 (100)

SB SiB 18.1 ± 9.3 (23.7)/ 

0.746

 

 

StB 28.3 ± 9.9 (76.3)

 

 

StB 28.3 ± 9.9 (76.3)

 

Mean age ± SD, y

69.8 ±7.3

69.8 ±6.6

0.001

69.8 ± 6.8

69.8 ±6.6

0.001

Age distribution, n (%)

 

 

0.123

 

 

0.014

40-49

1 217 (0.6)

415 (0.3)

 

400 (0.2)

415 (0.3)

 

50-59

17 566 (8.4)

10 842 (6.6)

 

11 380 (7.0)

10 842 (6.6)

 

60-69

77 086 (36.7)

64 163 (39.2)

 

63 617 (38.9)

64 163 (39.2)

 

70-79

98 182 (46.7)

79 094 (48.3)

 

78 980 (48.2)

79 094 (48.3)

 

≥ 80

16 077 (7.7)

9 205 (5.62)

 

9 342 (2.7)

9 205 (5.6)

 

Sex, n (%)

 

 

0.291

 

 

0.004

Male

36 710 (17.5)

12 925 (7.9)

 

13 092 (8.0)

12 925 (7.9)

 

Female

173 418 (82.5)

150 794 (92.1)

 

150 627 (92.0)

150 794 (92.1)

 

Location, n (%)

 

 

0.182

 

 

0.085

Urban

82 445 (39.2)

78 931 (48.2)

 

71 981 (44.0)

78 931 (48.2)

 

Rural

127 683 (60.8)

84 788 (51.8)

 

91 738 (56.0)

84 788 (51.8)

 

Hospital size, n (%)

 

 

0.056

 

 

0.012

Large

81 706 (38.9)

59 232 (36.2)

 

60 198 (36.8)

59 232 (36.2)

 

Small or medium

128 422 (61.1)

104 487 (63.8)

 

103 521 (63.2)

104 487 (63.8)

 

Insurance type, n (%)

 

 

0.023

 

 

0.001

Health insurance

192 102 (91.4)

150 727 (92.1)

 

150 783 (92.1)

150 727 (92.1)

 

Medical aid

18 026 (8.6)

12 992 (7.9)

 

12 936 (7.9)

12 992 (7.9)

 

History of drug use and comorbiditiesin previous year

NSAIDs, n (%)

 

 

0.101

 

 

0.047

No

54 253 (25.8)

49 710 (30.4)

 

46 189 (28.2)

49 710 (30.4)

 

Yes

155 875 (74.2)

114 009 (69.6)

 

117 530 (71.8)

114 009 (69.6)

 

Statin drugs, n (%)

 

 

0.068

 

 

0.01

No

203 837 (97.0)

160 543 (98.1)

 

160 769 (98.2)

160 546 (98.1)

 

Yes

6 291 (3.0)

3 173 (1.9)

 

2 950 (1.8)

3 173 (1.9)

 

Antiplatelet drugs, n (%)

 

 

0.037

 

 

0.006

No

208030 (99.0)

162 635 (99.3)

 

162 712 (99.4)

162 635 (99.3)

 

Yes

2098 (1.0)

1 084 (0.7)

 

1 007 (0.6)

1 084 (0.7)

 

Aspirin, n (%)

 

 

0.053

 

 

0.006

No

206 077 (98.1)

161 645 (98.7)

 

161 752 (98.8)

161 645 (98.7)

 

Yes

414 (1.9)

2 074 (1.3)

 

1 967 (1.2)

2 074 (1.3)

 

Vitamin K antagonists, n (%)

 

 

0.024

 

 

0.003

No

209 714 (99.8)

163 549 (100.0)

 

163 563 (99.9)

163 549 (99.9)

 

Yes

414 (0.2)

170 (0.0)

 

156 (0.1)

170 (0.1)

 

Factor Xa inhibitors, n (%)

 

 

0.079

 

 

0.001

No

209 251 (99.6)

163 651 (100.0)

 

163 648 (100.0)

163 651 (100.0)

 

Yes

877 (0.4)

68 (0.0)

 

71 (0.0)

68 (0.0)

 

Direct thrombin inhibitors, n (%)

 

 

0.002

 

 

0.001

No

210 113 (100.0)

163 710 (100)

 

163 709 (100.0)

163 710 (100.0)

 

Yes

15 (0.0)

9 (0.0)

 

10 (0.0)

9 (0.0)

 

Hypertension drugs, n (%)

 

 

0.077

 

 

0.006

No

200 082 (95.2)

158 365 (96.7)

 

158 549 (96.8)

158 365 (96.7)

 

Yes

10 046 (4.8)

5 354 (3.3)

 

5 170 (3.2)

5 354 (3.3)

 

AIDS, n (%)

 

 

0.001

 

 

0.002

No

210119 (100.0)

163 713 (100.0)

 

163 711 (100.0)

163 713 (100.0)

 

Yes

9 (0.0)

6 (0.0)

 

8 (0.0)

6 (0.0)

 

CHF, n (%)

 

 

0.015

 

 

0.003

No

201 807 (96.0)

157 694 (96.3)

 

157 776 (96.4)

157 694 (96.3)

 

Yes

8 321 (4.0)

6 025 (3.7)

 

5 943 (3.6)

6 025 (3.7)

 

CKD, n (%)

 

 

0.048

 

 

0.003

No

206 392 (92.2)

161 763 (98.8)

 

161 820 (98.8)

161 763 (98.8)

 

Yes

3 736 (1.8)

1 956 (1.2)

 

1 899 (1.2)

1 956 (1.2)

 

COPD, n (%)

 

 

0.058

 

 

0.012

No

124 299 (59.2)

101 467 (62.0)

 

100 486 (61.4)

101 467 (62.0)

 

Yes

85 829 (40.9)

62 252 (38.0)

 

63 233 (38.6)

62 252 (38.0)

 

Connective tissue disease, n (%)

 

 

0.009

 

 

0.004

No

188 530 (89.7)

147 356 (90.0)

 

147 158 (89.9)

147 356 (90.0)

 

Yes

21 598 (10.3)

16 363 (10.0)

 

16 561 (10.1)

16 363 (10.0)

 

CVA or TIA, n (%)

 

 

0.05

 

 

0.002

No

187 245 (89.1)

148 357 (90.6)

 

148 271 (90.6)

148 357 (90.6)

 

Yes

22 883 (10.9)

15 362 (9.4)

 

15 448 (9.4)

15 362 (9.4)

 

Dementia, n (%)

 

 

0.05

 

 

<0.001

No

204 127 (97.1)

160 313 (97.9)

 

160 310 (97.9)

160 313 (97.9)

 

Yes

6 001 (2.9)

3 406 (2.1)

 

3 409 (2.1)

3 406 (2.1)

 

Hemiplegia, n (%)

 

 

0.020

 

 

0.004

No

209 716 (99.8)

163 529 (99.9)

 

163 551 (99.9)

163 529 (99.9)

 

Yes

412 (0.2)

190 (0.1)

 

168 (0.1)

190 (0.1)

 

Myocardial infarction n (%)

 

 

0.028

 

 

0.002

No

207 802 (98.9)

162 361 (99.2)

 

162 390 (99.2)

162 361 (99.2)

 

Yes

2 326 (1.1)

1 358 (0.8)

 

1 329 (0.8)

1 358 (0.8)

 

Peptic ulcer disease, n (%)

 

 

0.037

 

 

0.007

No

133 184 (63.4)

106 698 (65.2)

 

106 168 (64.8)

106 698 (65.2)

 

Yes

76 944 (36.6)

57 021 (34.8)

 

57 551 (35.2)

57 021 (34.8)

 

Peripheral vascular disease, n (%)

 

 

0.020

 

 

0.006

No

185 614 (88.3)

145 660 (89.0)

 

145 371 (88.8)

145 660 (89.0)

 

Yes

24 514 (11.7)

18 059 (11.0)

 

18 348 (11.2)

18 059 (11.0)

 

Liver disease, n (%)

 

 

0.027

 

 

0.004

No

204 069 (97.1)

159 719 (97.6)

 

159 820 (97.6)

159 719 (97.6)

 

Yes

6 059 (2.9)

4 000 (2.4)

 

3 899 (2.4)

4 000 (2.4)

 

Severe liver disease, n (%)

 

 

0.06

 

 

0.001

No

209 610 (99.8)

163 365 (99.8)

 

163 375 (99.8)

163 365 (99.8)

 

Yes

518 (0.2)

354 (0.2)

 

344 (0.2)

354 (0.2)

 

Cancer, n (%)

 

 

0.030

 

 

0.003

No

199 631 (95.0)

15 670 (95.6)

 

156 681 (95.7)

15 670 (95.6)

 

Yes

10 497 (5.0)

7 149 (4.4)

 

7 038 (4.3)

7 149 (4.4)

 

Metastatic cancer, n (%)

 

 

0.009

 

 

0.002

No

209 547 (99.7)

163 338 (99.8)

 

163 353 (99.8)

163 338 (99.8)

 

Yes

581 (0.3)

381 (0.2)

 

366 (0.2)

381 (0.2)

 

Diabetes, n (%)

 

 

0.024

 

 

0.003

No

151 518 (72.1)

119 831 (73.2)

 

119 604 (73.1)

119 831 (73.2)

 

Yes

58 610 (27.9.)

43 888 (26.8)

 

44 115 (26.9)

43 888 (26.8)

 

Diabetes with complication, n (%)

 

 

0.029

 

 

0.001

No

194 170 (92.4)

152 531 (93.2)

 

152 470 (93.1)

152 531 (93.2)

 

Yes

15 958 (7.6).

11 188 (6.8)

 

11 249 (6.9)

11 188 (6.8)

 

 

 

 

 

 

 

 

Charlsoncomorbity score, mean ± SD

5.25 ± 1.70

5.12 ± 1.59

0.001

5.13 ± 1.59

5.12 ± 1.59

0.001

 

 

 

 

 

 

 

Atrial fibrillation, n (%)

 

 

0.027

 

 

<0.001

No

207 033 (98.5)

161 818 (98.8)

 

161 822 (98.8)

161 818 (98.8)

 

Yes

3 095 (1.5)

1901 (1.2)

 

1897 (1.2)

1 901 (1.2)

 

Valvular heart disease, n (%)

 

 

0.002

 

 

0.002

No

210 088 (100.0)

163 692 (100.0)

 

163 687 (100.0)

163 692 (100.0)

 

Yes

40 (0.0)

27 (0.0)

 

32 (0.0)

27 (0.0)

 

Carotid artery disease, n (%)

 

 

0.013

 

 

0.003

No

208 925 (99.4)

162 931 (99.5)

 

162 962 (99.5)

162 931 (99.5)

 

Yes

1 203 (0.6)

788 (0.5)

 

757 (0.5)

788 (0.5)

 

Hypothyroidism, n (%)

 

 

0.003

 

 

0.002

No

202 566 (96.4)

157 928 (96.5)

 

157 988 (96.5)

157 928 (96.5)

 

Yes

7 562 (3.6)

5 791 (3.5)

 

5 731 (3.5)

5 791 (3.5)

 

TKA, total knee arthroplasty; PS, propensity score; SD, standard deviation; SB SiB, simultaneous bilateral; StB, staged bilateral; NSAIDs, non-steroidal anti-inflammatory drugs; AIDS, acquired immune deficiency syndrome; CHF, congestive heart failure; CKD, chronic kidney disease; COPD, chronic obstructive pulmonary disease; CVA, cerebrovascular disease; TIA, transient ischemic attack


Table 2
Subgroup analyses of risk of stroke with bilateral total knee arthroplasty, compared to unilateral total knee arthroplasty, in PS matched cohort.
Subgroup
Sum of
person years
Number of events
Incidence rate per 1000000
person years (95% CI)*
95% CI
HR
95% CI
p value
p value for interaction
lower
upper
lower
upper
Overall
487 273 006
2 531
5.19
4.99
5.40
0.79
0.73
0.85
< 0.001
 
 
unilateral TKA
235 758 899
1 411
5.98
5.68
6.31
         
 
bilateral TKA
251 514 107
1 120
4.45
4.20
4.72
         
Age
                 
0.368
40–49
1 538 293
1
0.65
0.02
3.62
NA
NA
NA
NA
 
50–59
37 380 596
70
1.87
1.46
2.37
1.17
0.73
1.88
0.504
 
60–69
199 119 148
651
3.27
3.02
3.53
0.81
0.69
0.94
0.007
 
70–79
226 804 347
1 556
6.86
6.52
7.21
0.76
0.69
0.84
< 0.001
 
≥ 80
22 430 622
253
11.28
9.93
12.76
0.84
0.66
1.07
0.164
 
Sex
                 
0.657
Male
35 445 002
258
7.28
6.42
5.24
0.79
0.59
0.96
0.022
 
Female
451 828 004
2 273
5.03
4.83
8.22
0.75
0.71
0.86
< 0.001
 
Location
                 
0.463
Urban
226 829 869
1 078
4.75
4.47
5.04
0.82
0.73
0.93
0.001
 
Rural
260 443 137
1 453
5.58
5.30
5.87
0.77
0.70
0.86
< 0.001
 
Hospital size
                 
0.098
Large
175 297 445
976
5.57
5.22
5.93
0.86
0.76
0.97
0.018
 
Small or medium
311 975 561
1 555
4.98
4.74
5.24
0.75
0.68
0.83
< 0.001
 
Insurance type
                 
0.101
Health insurance
448 017 058
2 236
4.99
4.79
5.20
0.77
0.71
0.84
< 0.001
 
Medical aid
39 255 948
295
7.51
6.68
8.42
0.94
0.75
1.19
0.623
 
History of drug use and comorbidities in previous year
NSAIDs
                 
0.732
No
133 406 439
669
5.01
4.64
5.41
0.77
0.66
0.90
0.001
 
Yes
353 866 567
1 862
5.26
5.03
5.51
0.80
0.73
0.87
< 0.001
 
Statin drugs
                 
0.533
No
478 764 990
2 458
5.13
4.93
5.34
0.79
0.73
0.86
< 0.001
 
Yes
8 508 016
73
8.58
6.73
10.79
0.68
0.43
1.08
0.106
 
Antiplatelet drugs
                 
0.578
No
484 349 186
2 504
5.17
4.97
5.38
0.79
0.73
0.86
< 0.001
 
Yes
2 923 820
27
9.23
6.09
13.44
0.63
0.29
1.37
0.246
 
Aspirin
                 
0.941
No
481 724 149
2 480
5.15
4.95
5.35
0.79
0.73
0.85
< 0.001
 
Yes
5 548 857
51
9.19
6.84
12.08
0.77
0.45
1.34
0.361
 
Vitamin K antagonists
                 
0.330
No
486 788 236
2 525
5.19
4.99
5.39
0.79
0.73
0.85
< 0.001
 
Yes
484 770
6
12.38
4.54
26.94
1.83
0.34
10.00
0.484
 
Factor Xa inhibitor
                 
0.973
No
487 137 787
2 530
5.19
4.99
5.40
0.79
0.73
0.85
< 0.001
 
Yes
135 219
1
7.40
0.19
41.20
NA
NA
NA
NA
 
Direct thrombin inhibitor
                 
1.000
No
487 264 451
2 531
5.19
4.99
5.40
0.79
0.73
0.85
< 0.001
 
Yes
8 555
0
0.00
0.00
431.20
NA
NA
NA
NA
 
Hypertension drugs
                 
0.753
No
471 886 519
2 383
5.05
4.85
5.26
0.79
0.73
0.86
0.082
 
Yes
15 386 487
148
9.62
8.13
11.30
0.75
0.54
1.04
< 0.001
 
AIDS
                 
1.000
No
487 254 281
2 531
5.19
4.99
5.40
0.79
0.73
0.85
< 0.001
 
Yes
18 725
0
0.00
0.00
197.00
NA
NA
NA
NA
 
CHF
                 
0.467
No
469 984 045
2 378
5.06
4.86
5.27
0.79
0.73
0.86
< 0.001
 
Yes
17 288 961
153
8.85
7.50
10.37
0.70
0.51
0.97
0.032
 
CKD
                 
0.622
No
482 451 662
2 490
5.16
4.96
5.37
0.79
0.73
0.86
< 0.001
 
Yes
4 821 344
41
8.50
6.10
11.54
0.68
0.36
1.26
0.217
 
COPD
                 
0.909
No
302 399 164
1 624
5.37
5.11
5.64
0.79
0.71
0.87
< 0.001
 
Yes
184 873 842
907
4.91
4.59
5.24
0.79
0.70
0.91
0.001
 
Connective tissue disease
                 
0.391
No
435 853 149
2 308
5.30
5.08
5.52
0.80
0.73
0.87
< 0.001
 
Yes
51 419 857
223
4.34
3.79
4.94
0.71
0.54
0.92
0.010
 
CVA or TIA
                 
0.727
No
441 509 488
2 133
4.83
4.63
5.04
0.78
0.72
0.85
< 0.001
 
Yes
45 763 518
398
8.70
7.86
9.59
0.82
0.67
0.99
0.043
 
Dementia
                 
0.606
No
478 938 862
2 447
5.11
4.91
5.32
0.79
0.73
0.86
< 0.001
 
Yes
8 334 144
84
10.08
8.04
12.48
0.71
0.46
1.09
0.118
 
Hemiplegia
                 
0.229
No
486 728 204
2 524
5.19
4.99
5.39
0.79
0.73
0.85
< 0.001
 
Yes
544 802
7
12.85
5.17
26.47
2.16
0.42
11.11
0.359
 
Myocardial infarction
                 
0.544
No
483 269 362
2 496
5.16
4.96
5.37
0.79
0.73
0.86
< 0.001
 
Yes
4 003 644
35
8.74
6.09
12.16
0.64
0.33
1.26
0.196
 
Peptic ulcer disease
                 
0.493
No
309 899 308
1 636
5.28
5.03
5.54
0.77
0.70
0.85
< 0.001
 
Yes
177 373 698
895
5.05
4.72
5.39
0.82
0.72
0.93
0.003
 
Peripheral vascular disease
                 
0.136
No
432 394 256
2 182
5.05
4.84
5.26
0.77
0.71
0.84
< 0.001
 
Yes
54 878 750
349
6.36
5.71
7.06
0.92
0.74
1.13
0.411
 
Liver disease
                 
0.202
No
474 611 698
2 481
5.23
5.02
5.44
0.80
0.73
0.86
< 0.001
 
Yes
12 661 308
50
3.95
2.93
5.21
0.54
0.31
0.97
0.059
 
Severe liver disease
                 
0.806
No
485 959 159
2 525
5.20
5.00
5.40
0.79
0.73
0.85
< 0.001
 
Yes
1 313 847
6
4.57
1.68
9.94
0.96
0.19
4.76
0.961
 
Cancer
                 
0.492
No
468 096 910
2 444
5.22
5.02
5.43
0.79
0.73
0.85
< 0.001
 
Yes
19 176 096
87
4.54
3.63
5.60
0.91
0.60
1.39
0.674
 
Metastatic cancer
                 
0.800
No
486 212 605
2 526
5.20
4.99
5.40
0.79
0.73
0.85
< 0.001
 
Yes
1 060 401
5
4.72
1.53
11.00
0.64
0.11
3.81
0.622
 
Diabetes
                 
0.684
No
359 206 894
1 734
4.83
4.60
5.06
0.80
0.73
0.88
< 0.001
 
Yes
128 066 112
797
6.22
5.80
6.67
0.77
0.67
0.89
< 0.001
 
Diabetes with complication
                 
0.757
No
454 116 703
2 288
5.04
4.83
5.25
0.79
0.73
0.86
< 0.001
 
Yes
33 156 303
243
7.33
6.44
8.31
0.76
0.59
0.98
0.034
 
Atrial fibrillation
                 
0.936
No
483 244 151
2 453
5.08
4.88
5.28
0.79
0.73
0.85
< 0.001
 
Yes
4 028 855
78
19.36
15.30
24.16
0.80
0.51
1.26
0.337
 
Valvular heart disease
                 
0.973
No
487 184 407
2 530
5.19
4.99
5.40
0.79
0.73
0.85
< 0.001
 
Yes
88 599
1
11.29
0.29
62.89
NA
NA
NA
NA
 
Carotid artery disease
                 
0.385
No
485 545 773
2 509
5.17
4.97
5.37
0.79
0.73
0.85
< 0.001
 
Yes
1 727 233
22
12.74
7.98
19.28
1.15
0.50
2.66
0.749
 
Hypothyroidismm
                 
0.786
No
471 135 808
2 466
5.23
5.03
5.44
0.79
0.73
0.85
< 0.001
 
Yes
16 137 198
65
4.03
3.11
5.13
0.84
0.52
1.38
0.497
 
TKA, total knee arthroplasty; PS, propensity score; HR, hazard ratio; CI, confidence interval; NSAIDs, non-steroidal anti-inflammatory drugs; AIDS, acquired immune deficiency syndrome; CHF, congestive heart failure; CKD, chronic kidney disease; COPD, chronic obstructive pulmonary disease; CVA, cerebrovascular disease; TIA, transient ischemic attack
*Incidecnce rate=(No of events/sum of person years)x1000000; 95% CI calculated assuming Poisson distribution.



Table 3
Association between unilateral TKA and bilateral TKA
 
Univariable analysis
Multivariable analysis
Sensitivity analysis
 
Crude HR
95% CI
p value
Adjusted HR*
95% CI
p value
Adjusted HR†
95% CI
p value
 
lower
upper
lower
upper
lower
upper
Surgery
                       
Unilateral
reference
     
reference
     
reference
     
Bilateral
0.789
0.730
0.854
< 0.001
0.793
0.733
0.858
< 0.001
0.792
0.732
0.857
< 0.001
TKA, total knee arthroplasty; HR, hazard ratio; CI, confidence interval.
*Adjusted by age, sex, location, hospital size, NSAIDs, statin drugs, antiplatelet drugs, aspirin drugs, vitamin K antagonists, hypertension drugs, CHF, CKD, COPD, connective tissue disease, CVA or TIA, dementia, hemiplegia, myocardial infarction, peripheral vascular disease, cancer, diabetes, diabetes with complication, Charlson comorbidity score, atrial fibrillation, carotid artery disease, hypothyroidism.
†*Adjusted by the same variables as in multivariable analysis and insurance type.