Download PDF
J Knee Surg 2023; 36(12): 1259-1265
DOI: 10.1055/s-0042-1755359
Original Article

Preoperative Statin Exposure Reduces Periprosthetic Fractures and Revisions following Total Knee Arthroplasty

Oliver C. Sax
1   Rubin Institute for Advanced Orthopedics, Sinai Hospital of Baltimore, Baltimore, Maryland
,
Sandeep S. Bains
1   Rubin Institute for Advanced Orthopedics, Sinai Hospital of Baltimore, Baltimore, Maryland
,
Zhongming Chen
1   Rubin Institute for Advanced Orthopedics, Sinai Hospital of Baltimore, Baltimore, Maryland
,
Scott J. Douglas
1   Rubin Institute for Advanced Orthopedics, Sinai Hospital of Baltimore, Baltimore, Maryland
,
James Nace
1   Rubin Institute for Advanced Orthopedics, Sinai Hospital of Baltimore, Baltimore, Maryland
,
Ronald E. Delanois
1   Rubin Institute for Advanced Orthopedics, Sinai Hospital of Baltimore, Baltimore, Maryland
› Author Affiliations
› Further Information
 
 PDF Download Permissions and Reprints

Abstract

The purpose of this study is to examine patients undergoing primary total knee arthroplasty (TKA) with and without prior history of statin use. We specifically evaluated (1) 90-day to 2-year periprosthetic fractures, (2) revisions, and (3) respective risk factors. We queried a national, all-payer database for patients undergoing primary TKA between 2010 and 2020. Chronic statin exposure was then identified and defined as more than three prescriptions filled within 1 year prior to TKA (statin users). A control cohort of patients undergoing TKA without the prior history of statin use was then created (statin naïve). Cohorts were matched 1:1 based on age range, Charlson Comorbidity Index, sex, diabetes, obesity, and tobacco use, yielding 579,136 patients. Multivariate logistic regression was performed to evaluate the risk factors for periprosthetic fractures and revisions, adjusted for demographics and comorbidities. Statin users had a lower incidence of periprosthetic fractures from 90 days to 2 years compared with the statin naïve (p < 0.001). Similarly, statin users had a lower incidence of revisions at 90 days to 2 years (p < 0.001). Using the statin-naïve cohort as a reference, statin use was independently associated with decreased odds of periprosthetic fractures and revisions. Statin use was associated with a reduced risk of periprosthetic fractures and revisions. These results may mitigate postoperative risks though statin therapy is currently not recommended for fracture-related benefits alone.


#

Keywords

statin - periprosthetic fracture - total knee arthroplasty - arthroplasty

The pleiotropic effects of 3-hydroxy-3-methylglutaryl-coenzyme A reductase inhibitors (statins) extend beyond managing cardiovascular health. Statin use has been suggested to suppress osteoclast cell activity to strengthen the bone formation.[1] [2] [3] Thus, the statin use in the setting of total knee arthroplasty (TKA) may have a greater value than previously understood. As TKA continues to serve as one of the fastest-growing procedures, the cumulative incidence of postoperative fractures will theoretically rise as well.[4] Periprosthetic fractures have a reported incidence of 1.7% and 0.3 to 2.5% following primary total hip arthroplasty (THA) and TKA, respectively.[5] [6] [7] [8] Further, periprosthetic fractures constitute a substantial proportion of patients requiring revision surgeries.[9] [10] However, a large study specifically evaluating statin exposure and fracture risk following TKA is lacking.

Multiple studies have attempted to identify the role of statin in enhancing bone health by blocking osteoclastogenesis, thereby preserving bone mass.[1] [2] [3] Luckman et al[1] observed statin-induced apoptosis of specific macrophages and murine osteoclasts by a similar mechanism to nitrogen-containing bisphosphonates. Another study observed statin's inhibitory effect on the differentiation of osteoclasts.[3] Statins have also been suggested to attenuate fracture risk. Results from a Danish Hip Arthroplasty Registry demonstrated a significant risk reduction of periprosthetic fractures and revision following THA.[11] These results were similarly demonstrated among United States veterans where statin use was associated with reduced fracture risk when compared with nonlipid lowering agents.[12] Statin's potential to reduce fracture risk is promising, but further study with increased sample sizes may be warranted to corroborate previous findings.

The expansion of TKA in recent years to include more patients than ever directly translates to increased periprosthetic fracture risk incidence. Furthermore, a substantial proportion of TKA recipients receive statin therapy. The purpose of this study is to examine chronic statin users versus statin-naïve TKA recipients utilizing a national dataset. We specifically evaluated (1) 90-day to 2-year periprosthetic fractures, (2) revisions, and (3) respective risk factors.

Methods

Database Selection

We queried the “MKnee” dataset within a national, all-payer database (PearlDiver, Inc., Colorado Springs, CO). This database contains over 122 million Health Insurance Portability and Accountability Act compliant patient records spanning January 1, 2010 and April 31, 2020. Patient records across all payer categories are available, including commercial, Medicare, Medicaid, and cash payers. To date, this is one of the largest updated national databases with the ability to track a substantial number of patients longitudinally over a long time period. In effect, this reduces potential type II errors that may arise. Patient populations, outcomes, and complications were identified using International Classification of Diseases (ICD) nine and ten procedural and diagnoses codes, as well as Current Procedural Terminology (CPT) codes. Institutional review board approval was waived for this publicly available database study.


#

Patient Selection

All patients who underwent primary TKA between January 1, 2010 and April 31, 2020 were identified (n = 1,837,719). Patients who were chronic statin users prior to surgery were then identified using the Universal System of Classification drug code (USC-32110). Chronic statin use was defined as filling more than three statin prescriptions in the year prior to receiving a TKA (n = 603,326). A control cohort of patients who never received a statin prescription prior to TKA was then identified (statin naïve), yielding 1,036,897 patients. Both cohorts were then matched 1:1 based on age range, sex, Charlson Comorbidity Index (CCI), diabetes, obesity, and tobacco use, yielding 579,136 patients.


#

Outcomes

Primary outcomes included 90-day, 1-year, and 2-year periprosthetic fractures and revision surgeries. Secondary outcomes included patient demographics such as age, sex, diabetes, obesity, and tobacco use.


#

Patient Demographics

Demographics and baseline characteristics were similar among both TKA cohorts. They had a mean age of 67 ± 7.8 years, female predominance (61.1%), diabetes (55.9%), obesity (53.2%), and tobacco use (22.9%). All p-values for these matched variables were 0.999 (see [Table 1]).

Table 1

Demographics and baseline characteristics

TKA statin users (n = 579,136)

TKA statin naïve (n = 579,136)

p-Value

Age (SD)

67 (7.8)

67 (7.8)

0.999

Sex

0.999

Male

225,255 (38.9)

225,255 (38.9)

Female

353,881 (61.1)

353,881 (61.1)

Diabetes

323,675 (55.9)

323,675 (55.9)

0.999

Obesity

307,957 (53.2)

307,957 (53.2)

0.999

Tobacco use

132,838 (22.9)

132,838 (22.9)

0.999

Abbreviations: TKA: total knee arthroplasty; SD, Standard deviation.



#

Statistical Analyses

Continuous variables including ages were compared using Student's t-tests. Categorical variables including demographics, comorbidities, periprosthetic fractures, revision surgeries, and other complications were compared using chi-square tests. Multivariate logistic regressions were conducted to evaluate risk factors for periprosthetic fractures and revision surgeries from 90 days to 2 years. Assessed variables included ages (<60; 60 to 70; 71 to 80; >80 years), female sex, alcohol abuse, body mass index (<25; 25 to 30; 30.1 to 40; >40), CCI > 3, diabetes, statin use, and tobacco use. The statin-naïve cohort served as the reference. All analyses were performed using R Studio (Statistics Department of the University of Auckland) with significance defined as p < 0.05.


#
#

Results

Periprosthetic Fractures and Revision Surgeries

The incidence and odds of periprosthetic fractures at 90 days were lower among statin users, compared with the statin naïve (0.10 vs. 0.13%, odds ratio [OR] 0.81 [0.72–0.89], p < 0.001; see [Tables 2] and [3]). These differences were more pronounced at 1 year (0.20 vs. 0.24%, OR 0.83 [0.77–0.90], p < 0.001) and 2 years (0.20 vs. 0.24%, OR 0.85 [0.80–0.91], p < 0.001). The incidence and odds of revision surgeries at 90 days were lower among statin users compared with the statin naïve (0.48 vs. 0.56%, OR 0.86 [0.81–0.90], p < 0.001). Revision surgery rate differences continued at 1 year (1.14 vs. 1.30%, OR 0.88 [0.85–0.91], p < 0.001) and 2 years (2.18 vs. 2.38%, OR 0.91 [0.89–0.94], p < 0.001).

Table 2

Postoperative periprosthetic fractures and revisions

TKA statin users (n = 579,136)

TKA statin naïve (n = 579,136)

p-Value

90-d complications

 Periprosthetic fractures

599 (0.10)

747 (0.13)

<0.001

 Revisions

2,795 (0.48)

3,266 (0.56)

<0.001

1-y complications

 Periprosthetic fractures

1,133 (0.20)

1,369 (0.24)

<0.001

 Revisions

6,596 (1.14)

7,518 (1.30)

<0.001

2-year complications

 Periprosthetic fractures

1,842 (0.32)

2,158 (0.37)

<0.001

 Revisions

12,636 (2.18)

13,808 (2.38)

<0.001

Abbreviation: TKA, total knee arthroplasty.


Table 3

Odds ratios for periprosthetic fractures and revisions

TKA odds ratios (95% CI)

90-d complications

 Periprosthetic fractures

0.81

0.72–0.89

 Revisions

0.86

0.81–0.90

1-y complications

 Periprosthetic fracture

0.83

0.77–0.90

 Revision

0.88

0.85–0.91

2-y complications

 Periprosthetic fracture

0.85

0.80–0.91

 Revision

0.91

0.89–0.94

Abbreviations: CI, confidence interval; TKA, total knee arthroplasty.



#

Risk Factors for Periprosthetic Fractures

Statin use was associated with decreased odds of periprosthetic fractures, when referencing the statin-naïve cohort (ORs ≤ 0.82; see [Table 4]). Age from 71 to 80 years was the most significant age-related risk factor for periprosthetic fractures (TKA: ORs ≥3.01). BMI > 40 kg/m2 was the most significant body-mass-related risk factor for periprosthetic fractures (TKA: ORs ≥1.54).

Table 4

Multivariate logistic regression for periprosthetic fractures

TKA

Odds ratio

Confidence interval

p-Value

90-d complications

Age <60

1.39

1.10–1.74

0.005

Age 60–70

2.01

1.62–2.45

<0.001

Age 71–80

3.24

2.61–3.99

<0.001

Age >80

1.07

0.61–2.09

0.821

Female sex

2.94

2.62–3.31

<0.001

Alcohol abuse

1.95

1.63–2.30

<0.001

BMI <25 kg/m2

1.34

1.11–1.61

0.002

BMI 25–30 kg/m2

0.93

0.80–1.07

0.326

BMI 30.1–40 kg/m2

1.00

0.90–1.10

0.994

BMI >40 kg/m2

1.87

1.68–2.07

<0.001

CCI > 3

1.71

1.53–1.91

<0.001

Diabetes mellitus

1.01

0.92–1.11

0.875

Statin users

0.77

0.69–0.85

<0.001

Tobacco use

1.19

1.09–1.31

<0.001

1-y complications

Age <60

1.82

1.54–2.13

<0.001

Age 60–70

2.06

1.77–2.38

<0.001

Age 71–80

3.01

2.57–3.50

<0.001

Age >80

1.28

0.81–2.16

0.326

Female sex

2.10

1.94–2.27

<0.001

Alcohol abuse

1.88

1.66–2.12

<0.001

BMI <25 kg/m2

1.37

1.19–1.56

<0.001

BMI 25–30 kg/m2

0.94

0.85–1.04

0.261

BMI 30.1–40 kg/m2

1.02

0.95–1.09

0.646

BMI >40 kg/m2

1.67

1.54–1.80

<0.001

CCI > 3

1.63

1.50–1.77

<0.001

Diabetes mellitus

1.06

0.99–1.13

0.117

Statin users

0.80

0.74–0.86

<0.001

Tobacco use

1.20

1.12–1.28

<0.001

2-y complications

Age <60

2.32

2.05–2.61

<0.001

Age 60–70

2.49

2.23–2.77

<0.001

Age 71–80

3.70

3.30–4.14

<0.001

Age >80

0.74

0.55–1.02

0.053

Female sex

1.95

1.84–2.08

<0.001

Alcohol abuse

1.84

1.67–2.03

<0.001

BMI <25 kg/m2

1.49

1.34–1.65

<0.001

BMI 25–30 kg/m2

0.94

0.87–1.02

0.156

BMI 30.1–40 kg/m2

1.02

0.96–1.08

0.481

BMI >40 kg/m2

1.54

1.44–1.64

<0.001

CCI > 3

1.70

1.59–1.81

<0.001

Diabetes mellitus

1.09

1.03–1.15

0.002

Statin users

0.82

0.77–0.87

<0.001

Tobacco use

1.19

1.13–1.25

<0.001

Abbreviations: BMI, Body mass index; CCI, Charles Comorbidity Index; TKA, total knee arthroplasty.


Note: Referent cohort: Statin naive control cohort.



#

Risk Factors for Revision Surgeries

Statin use was associated with decreased odds of revision surgeries, when referencing the statin-naïve cohort (ORs ≤0.90; see [Table 5]). Age >80 years was the most significant age-related risk factor for revision surgeries (ORs ≥ 1.66). BMI >40 kg/m2 was the most significant body-mass-related risk factor for revision surgeries (ORs ≥1.35).

Table 5

Multivariate logistic regression for revision surgeries

TKA

Odds ratio

Confidence interval

p-Value

90-d complications

Age <60

2.58

2.32–2.85

<0.001

Age 60–70

2.08

1.89–2.29

<0.001

Age 71–80

1.96

1.77–2.17

<0.001

Age >80

4.30

2.50–8.32

<0.001

Female sex

0.77

0.74–0.80

<0.001

Alcohol abuse

1.73

1.61–1.86

<0.001

BMI <25 kg/m2

1.26

1.14–1.39

<0.001

BMI 25–30 kg/m2

0.88

0.82–0.94

<0.001

BMI 30.1–40 kg/m2

0.98

0.93–1.02

0.304

BMI >40 kg/m2

1.75

1.67–1.84

<0.001

CCI > 3

1.36

1.29–1.44

<0.001

Diabetes mellitus

1.26

1.20–1.31

<0.001

Statin users

0.85

0.81–0.89

<0.001

Tobacco use

1.23

1.18–1.28

<0.001

1-y complications

Age <60

3.31

3.10–3.53

<0.001

Age 60–70

2.11

1.98–2.25

<0.001

Age 71–80

1.73

1.62–1.85

<0.001

Age >80

3.72

2.63–5.50

<0.001

Female sex

0.82

0.80–0.84

<0.001

Alcohol abuse

1.51

1.44–1.58

<0.001

BMI <25 kg/m2

1.23

1.16–1.31

<0.001

BMI 25–30 kg/m2

0.99

0.94–1.03

0.603

BMI 30.1–40 kg/m2

1.06

1.03–1.09

<0.001

BMI >40 kg/m2

1.42

1.37–1.46

<0.001

CCI > 3

1.19

1.15–1.24

<0.001

Diabetes mellitus

1.27

1.24–1.31

<0.001

Statin users

0.88

0.85–0.91

<0.001

Tobacco use

1.24

1.21–1.28

<0.001

2-y complications

Age <60

4.54

4.34–4.74

<0.001

Age 60–70

2.81

2.70–2.93

<0.001

Age 71–80

2.23

2.13–2.33

<0.001

Age >80

1.66

1.37–2.03

<0.001

Female sex

0.88

0.86–0.89

<0.001

Alcohol abuse

1.35

1.30–1.40

<0.001

BMI <25 kg/m2

1.26

1.20–1.32

<0.001

BMI 25–30 kg/m2

1.10

1.06–1.13

<0.001

BMI 30.1–40 kg/m2

1.15

1.12–1.17

<0.001

BMI >40 kg/m2

1.35

1.32–1.39

<0.001

CCI > 3

1.30

1.26–1.33

<0.001

Diabetes mellitus

1.22

1.20–1.25

<0.001

Statin users

0.90

0.88–0.92

<0.001

Tobacco use

1.26

1.23–1.29

<0.001

Abbreviations: BMI, body mass index; CCI, Charles Comorbidity Index; TKA, total knee arthroplasty.


Note: Referent cohort: statin naive control cohort.



#
#

Discussion

Over 35 million people in the United States are prescribed statin therapy to manage cardiovascular health, trending higher since past few years.[13] Over the past two decades, numerous experimental and clinical studies have associated statin use with improved bone health, with potential consequences in patients undergoing TKA. Periprosthetic fracture remains a feared complication following TKA, and rates are likely to rise along with the concomitant increases in TKA.[14] However, the relationship between statin use and fracture healing in a national dataset is yet to be examined. We compared chronic statin users versus statin-native patients prior to TKA using a national, all-payer database. Ninety-day to two-year periprosthetic fracture rates were decreased among statin users. Similar findings were demonstrated for 90-day to 2-year revision rates.

The limitations of this study come from the use of a database. Study cohorts were assessed using medical and billing codes, both subject to misclassification and improper billing. However, an independent party formally audits patient information contained within the used database, mitigating these potential errors. Furthermore, specific patient, social, and, surgical factors could not be evaluated such as race, ethnicity, discharge status, operative time, or surgical volume. However, patient cohorts were specifically identified using ICD and CPT codes, as well as USC codes to determine statin status. This enabled proper evaluation of two large and distinct patient cohorts. Another limitation lies within how statin therapy was defined. We could not assess the specific dose of statin use or the therapy strength for each patient. However, we specifically defined chronic statin use as filling more than three statin prescriptions within the year of undergoing a TKA. These potential limitations should not be disqualifying given this database's unique strength to identify a large sum of distinct patients to track over a relatively long time period.

The role of statins on bone metabolism has been explored in several studies within the past two decades. Grasser et al[15] studied the influence of lovastatin's inhibitory effect on osteoclast development via blocking a key protein involved in bone resorption. Moon et al[16] assessed the inhibitory effects of simvastatin and highlighted its suppression of reactive oxygen species formed from osteoclast differentiating signaling pathways. They also found decreased expression of tartrate-resistant acid phosphatase, a marker of osteoclast differentiation. Actual bone formation following statin use is not as well understood. In a comparative study of hydrophobic and hydrophilic statins in animal models, Hughes et al[17] did not observe increased bone formation rates with statin treatment. In contrast, an impactful study by Mundy et al[18] highlighted statin's effect on increasing the expression of bone morphogenic protein-2 gene in bone cells, thereby increasing bone formation and cancellous bone volume. Another study showed increased bone formation and resorption when high-dose statin was administered.[19] Despite some varied reporting, statins are primarily suggested to influence the resorptive properties of osteoclasts as opposed to the regenerative capacity of other cell-mediated pathways. These experimental studies have laid the groundwork for further clinical study and its potential applications in arthroplasty, such as postoperative fracture prevention.

The association between statin use and fracture prevention has been explored in patients who have osteoporosis. In a large cross-sectional study of over 1,300 women in Australia, Pasco et al[20] demonstrated that the OR for fracture associated with statin use was 0.45 at the femoral neck, when adjusting for bone mineral density (BMD). The dramatic fracture reduction observed with statin use, they concluded, is substantially higher than expected from BMD changes alone. In a Scandinavian randomized trial of simvastatin versus placebo in patients with coronary heart disease, no differences were found in fracture risk between cohorts.[21] However, fracture incidence was not a predefined study endpoint, possibly influencing the actual fracture incidence. In a more recent randomized study with fracture incidence as a secondary outcome, Peña et al[22] reported a fracture incidence of 1.20 and 1.14 per 100 person-years for the statin and placebo cohort, respectively (p = 0.53). Statin's influence on fracture risk has been explored, despite varied reports available over the past two decades. However, arthroplasty procedures may confer a greater risk for fracture though statin's effect has not been thoroughly examined in this setting.

Few studies assess the role of statins following THA; however, they corroborate the present findings of decreased postoperative periprosthetic fracture and revision surgeries. Thillemann et al[11] identified over 2,300 matched patients from the Danish Hip Arthroplasty Registry who underwent revision THA. Compared with no use of statin, postoperative statin use was associated with reduced revision rates due to periprosthetic fractures (adjusted relative risk 0.12 [0.04 to 0.33]). Another study by Zhang et al[2] examined 42 patients treated with postoperative statin for 1 year versus no statins following primary THA. They reported significantly less BMD percentage loss among statin users (p < 0.05). The aforementioned studies evaluated statin use only in the postoperative setting; however, the present studies' methodology identified preoperative chronic statin use versus statin-naïve patients. We felt that this comparison has the potential to better elucidate differences in statin versus no statin use. Despite this difference, our findings of reduced periprosthetic fractures and revision surgeries up to 2 years are corroborated by previous literature. Furthermore, the present study is unique in that it examines statin use among a national dataset in the setting of TKA. Although the reported periprosthetic fracture incidence is under 2.5%, they continue to be difficult to manage.[5] [6] [7] [8] As more orthopaedic surgeons shift to an alternative payment model, the postoperative complication profile will be of keener interest. Thus, statin therapy has the potential to play an influential role in fracture reduction, thereby reducing cost expenditures. Current guidelines limit statin's use in managing cardiovascular health, and they are not recommended in the setting of arthroplasty for their reported fracture-related benefits. However, the present findings are encouraging and may provide a framework for future examination of statin's role on fracture risk. Statin use is associated with a reduced periprosthetic fracture risk and revision surgery rate following TKA; however, the small, yet significant, differences between cohorts warrant further long-term examination.


#

Conclusion

Chronic statin exposure is associated with a reduced risk of 90-day,1-year, and 2-year periprosthetic fracture and revision surgery following TKA, as compared with the statin naïve. These findings are corroborated by a majority of the relevant experimental and clinical studies available; however, future high-level research is warranted for validation. The authors do not recommend administering statin therapy prior to TKA on the basis of its purported fracture reduction benefits alone, though these findings may guide postoperative patient expectations.


#
#

Conflict of Interest

None declared.

  • References

  • 1 Luckman SP, Hughes DE, Coxon FP, Graham R, Russell G, Rogers MJ. Nitrogen-containing bisphosphonates inhibit the mevalonate pathway and prevent post-translational prenylation of GTP-binding proteins, including Ras. J Bone Miner Res 1998; 13 (04) 581-589
    CrossrefPubMedGoogle Scholar
  • 2 Zhang X, Sun Y, Xie H, Liu J, Zhao Y, Xu Z. The effect of simvastatin on periprosthetic bone mineral density in the hypercholesterolaemic patients after total hip arthroplasty. Int Orthop 2018; 42 (01) 59-64
    CrossrefPubMedGoogle Scholar
  • 3 Woo JT, Kasai S, Stern PH, Nagai K. Compactin suppresses bone resorption by inhibiting the fusion of prefusion osteoclasts and disrupting the actin ring in osteoclasts. J Bone Miner Res 2000; 15 (04) 650-662
    CrossrefPubMedGoogle Scholar
  • 4 Sloan M, Premkumar A, Sheth NP. Projected volume of primary total joint arthroplasty in the U.S., 2014 to 2030. J Bone Joint Surg Am 2018; 100 (17) 1455-1460
    CrossrefPubMedGoogle Scholar
  • 5 Kim KI, Egol KA, Hozack WJ, Parvizi J. Periprosthetic fractures after total knee arthroplasties. Clin Orthop Relat Res 2006; 446: 167-175
    CrossrefPubMedGoogle Scholar
  • 6 Parvizi J, Jain N, Schmidt AH. Periprosthetic knee fractures. J Orthop Trauma 2008; 22 (09) 663-671
    CrossrefPubMedGoogle Scholar
  • 7 Ricci WM. Periprosthetic femur fractures. J Orthop Trauma 2015; 29 (03) 130-137
    CrossrefPubMedGoogle Scholar
  • 8 Abdel MP, Watts CD, Houdek MT, Lewallen DG, Berry DJ. Epidemiology of periprosthetic fracture of the femur in 32 644 primary total hip arthroplasties: a 40-year experience. Bone Joint J 2016; 98-B (04) 461-467
    CrossrefPubMedGoogle Scholar
  • 9 Ulrich SD, Seyler TM, Bennett D. et al. Total hip arthroplasties: what are the reasons for revision?. Int Orthop 2008; 32 (05) 597-604
    CrossrefPubMedGoogle Scholar
  • 10 Kasahara Y, Majima T, Kimura S, Nishiike O, Uchida J. What are the causes of revision total knee arthroplasty in Japan? Knee. In: Clinical Orthopaedics and Related Research. Vol 471. New York: Springer LLC; 2013: 1533-1538
    Google Scholar
  • 11 Thillemann TM, Pedersen AB, Mehnert F, Johnsen SP, Søballe K. The risk of revision after primary total hip arthroplasty among statin users: a nationwide population-based nested case-control study. J Bone Joint Surg Am 2010; 92 (05) 1063-1072
    CrossrefPubMedGoogle Scholar
  • 12 Scranton RE, Young M, Lawler E, Solomon D, Gagnon D, Gaziano JM. Statin use and fracture risk: study of a US veterans population. Arch Intern Med 2005; 165 (17) 2007-2012
    CrossrefPubMedGoogle Scholar
  • 13 Salami JA, Warraich H, Valero-Elizondo J. et al. National trends in statin use and expenditures in the US adult population from 2002 to 2013: insights From the Medical Expenditure Panel Survey. JAMA Cardiol 2017; 2 (01) 56-65
    CrossrefPubMedGoogle Scholar
  • 14 Sloan M, Sheth NP. Projected Volume of Primary and Revision Total Joint Arthroplasty in the United States, 2030-2060. Abstract submitted to: 2018 American Academy of Orthopaedic Surgeons Annual Meeting
    Google Scholar
  • 15 Grasser WA, Baumann AP, Petras SF. et al. Regulation of osteoclast differentiation by statins. J Musculoskelet Neuronal Interact 2003; 3 (01) 53-62
    PubMedGoogle Scholar
  • 16 Moon HJ, Kim SE, Yun YP. et al. Simvastatin inhibits osteoclast differentiation by scavenging reactive oxygen species. Exp Mol Med 2011; 43 (11) 605-612
    CrossrefPubMedGoogle Scholar
  • 17 Hughes A, Rogers MJ, Idris AI, Crockett JC. A comparison between the effects of hydrophobic and hydrophilic statins on osteoclast function in vitro and ovariectomy-induced bone loss in vivo. Calcif Tissue Int 2007; 81 (05) 403-413
    CrossrefPubMedGoogle Scholar
  • 18 Mundy G, Garrett R, Harris S. et al. Stimulation of bone formation in vitro and in rodents by statins. Science 1999; 286 (5446): 1946-1949
    CrossrefPubMedGoogle Scholar
  • 19 Maritz FJ, Conradie MM, Hulley PA, Gopal R, Hough S. Effect of statins on bone mineral density and bone histomorphometry in rodents. Arterioscler Thromb Vasc Biol 2001; 21 (10) 1636-1641
    CrossrefPubMedGoogle Scholar
  • 20 Pasco JA, Kotowicz MA, Henry MJ, Sanders KM, Nicholson GC. ; Geelong Osteoporosis Study. Statin use, bone mineral density, and fracture risk: Geelong Osteoporosis Study. Arch Intern Med 2002; 162 (05) 537-540
    CrossrefPubMedGoogle Scholar
  • 21 Scandinavian Simvastatin Survival Study Group. Randomised trial of cholesterol lowering in 4444 patients with coronary heart disease: the Scandinavian Simvastatin Survival Study (4S). Lancet 1994; 344 (8934): 1383-1389
    CrossrefPubMedGoogle Scholar
  • 22 Peña JM, Aspberg S, MacFadyen J, Glynn RJ, Solomon DH, Ridker PM. Statin therapy and risk of fracture: results from the JUPITER randomized clinical trial. JAMA Intern Med 2015; 175 (02) 171-177
    CrossrefPubMedGoogle Scholar

Address for correspondence

Ronald E. Delanois, MD
Rubin Institute for Advanced Orthopedics, Sinai Hospital of Baltimore
2401 West Belvedere Avenue
Baltimore, MD 21215

Publication History

Received: 26 February 2022

Accepted: 19 June 2022

Article published online:
09 August 2022

© 2022. Thieme. All rights reserved.

Thieme Medical Publishers, Inc.
333 Seventh Avenue, 18th Floor, New York, NY 10001, USA

  • References

  • 1 Luckman SP, Hughes DE, Coxon FP, Graham R, Russell G, Rogers MJ. Nitrogen-containing bisphosphonates inhibit the mevalonate pathway and prevent post-translational prenylation of GTP-binding proteins, including Ras. J Bone Miner Res 1998; 13 (04) 581-589
    CrossrefPubMedGoogle Scholar
  • 2 Zhang X, Sun Y, Xie H, Liu J, Zhao Y, Xu Z. The effect of simvastatin on periprosthetic bone mineral density in the hypercholesterolaemic patients after total hip arthroplasty. Int Orthop 2018; 42 (01) 59-64
    CrossrefPubMedGoogle Scholar
  • 3 Woo JT, Kasai S, Stern PH, Nagai K. Compactin suppresses bone resorption by inhibiting the fusion of prefusion osteoclasts and disrupting the actin ring in osteoclasts. J Bone Miner Res 2000; 15 (04) 650-662
    CrossrefPubMedGoogle Scholar
  • 4 Sloan M, Premkumar A, Sheth NP. Projected volume of primary total joint arthroplasty in the U.S., 2014 to 2030. J Bone Joint Surg Am 2018; 100 (17) 1455-1460
    CrossrefPubMedGoogle Scholar
  • 5 Kim KI, Egol KA, Hozack WJ, Parvizi J. Periprosthetic fractures after total knee arthroplasties. Clin Orthop Relat Res 2006; 446: 167-175
    CrossrefPubMedGoogle Scholar
  • 6 Parvizi J, Jain N, Schmidt AH. Periprosthetic knee fractures. J Orthop Trauma 2008; 22 (09) 663-671
    CrossrefPubMedGoogle Scholar
  • 7 Ricci WM. Periprosthetic femur fractures. J Orthop Trauma 2015; 29 (03) 130-137
    CrossrefPubMedGoogle Scholar
  • 8 Abdel MP, Watts CD, Houdek MT, Lewallen DG, Berry DJ. Epidemiology of periprosthetic fracture of the femur in 32 644 primary total hip arthroplasties: a 40-year experience. Bone Joint J 2016; 98-B (04) 461-467
    CrossrefPubMedGoogle Scholar
  • 9 Ulrich SD, Seyler TM, Bennett D. et al. Total hip arthroplasties: what are the reasons for revision?. Int Orthop 2008; 32 (05) 597-604
    CrossrefPubMedGoogle Scholar
  • 10 Kasahara Y, Majima T, Kimura S, Nishiike O, Uchida J. What are the causes of revision total knee arthroplasty in Japan? Knee. In: Clinical Orthopaedics and Related Research. Vol 471. New York: Springer LLC; 2013: 1533-1538
    Google Scholar
  • 11 Thillemann TM, Pedersen AB, Mehnert F, Johnsen SP, Søballe K. The risk of revision after primary total hip arthroplasty among statin users: a nationwide population-based nested case-control study. J Bone Joint Surg Am 2010; 92 (05) 1063-1072
    CrossrefPubMedGoogle Scholar
  • 12 Scranton RE, Young M, Lawler E, Solomon D, Gagnon D, Gaziano JM. Statin use and fracture risk: study of a US veterans population. Arch Intern Med 2005; 165 (17) 2007-2012
    CrossrefPubMedGoogle Scholar
  • 13 Salami JA, Warraich H, Valero-Elizondo J. et al. National trends in statin use and expenditures in the US adult population from 2002 to 2013: insights From the Medical Expenditure Panel Survey. JAMA Cardiol 2017; 2 (01) 56-65
    CrossrefPubMedGoogle Scholar
  • 14 Sloan M, Sheth NP. Projected Volume of Primary and Revision Total Joint Arthroplasty in the United States, 2030-2060. Abstract submitted to: 2018 American Academy of Orthopaedic Surgeons Annual Meeting
    Google Scholar
  • 15 Grasser WA, Baumann AP, Petras SF. et al. Regulation of osteoclast differentiation by statins. J Musculoskelet Neuronal Interact 2003; 3 (01) 53-62
    PubMedGoogle Scholar
  • 16 Moon HJ, Kim SE, Yun YP. et al. Simvastatin inhibits osteoclast differentiation by scavenging reactive oxygen species. Exp Mol Med 2011; 43 (11) 605-612
    CrossrefPubMedGoogle Scholar
  • 17 Hughes A, Rogers MJ, Idris AI, Crockett JC. A comparison between the effects of hydrophobic and hydrophilic statins on osteoclast function in vitro and ovariectomy-induced bone loss in vivo. Calcif Tissue Int 2007; 81 (05) 403-413
    CrossrefPubMedGoogle Scholar
  • 18 Mundy G, Garrett R, Harris S. et al. Stimulation of bone formation in vitro and in rodents by statins. Science 1999; 286 (5446): 1946-1949
    CrossrefPubMedGoogle Scholar
  • 19 Maritz FJ, Conradie MM, Hulley PA, Gopal R, Hough S. Effect of statins on bone mineral density and bone histomorphometry in rodents. Arterioscler Thromb Vasc Biol 2001; 21 (10) 1636-1641
    CrossrefPubMedGoogle Scholar
  • 20 Pasco JA, Kotowicz MA, Henry MJ, Sanders KM, Nicholson GC. ; Geelong Osteoporosis Study. Statin use, bone mineral density, and fracture risk: Geelong Osteoporosis Study. Arch Intern Med 2002; 162 (05) 537-540
    CrossrefPubMedGoogle Scholar
  • 21 Scandinavian Simvastatin Survival Study Group. Randomised trial of cholesterol lowering in 4444 patients with coronary heart disease: the Scandinavian Simvastatin Survival Study (4S). Lancet 1994; 344 (8934): 1383-1389
    CrossrefPubMedGoogle Scholar
  • 22 Peña JM, Aspberg S, MacFadyen J, Glynn RJ, Solomon DH, Ridker PM. Statin therapy and risk of fracture: results from the JUPITER randomized clinical trial. JAMA Intern Med 2015; 175 (02) 171-177
    CrossrefPubMedGoogle Scholar

   Permissions and Reprints