key: cord-0965241-5xed77ol
authors: Cheok, Tim; Jennings, Matthew; Aprato, Alessandro; Jayasekera, Narlaka; Jaarsma, Ruurd L
title: Safety of intraarticular corticosteroid injection preceding hip and knee arthroplasty: a systematic review and meta-analysis amid resolving COVID-19 arthroplasty restrictions
date: 2021-08-24
journal: J Hip Preserv Surg
DOI: 10.1093/jhps/hnab064
sha: efb453cfcf8c7e23f15504db586c4821605e0f32
doc_id: 965241
cord_uid: 5xed77ol

Intraarticular corticosteroid injection (ICSI) is a widely practiced management for hip and knee osteoarthritis. Imposed delays to arthroplasty during coronavirus disease 2019 pandemic have led us to postulate that many patients have opted for recent ICSI. We compared the odds of prosthetic joint infection (PJI) in patients who were or were not administered ICSI within 12 months prior to hip or knee arthroplasty. A systematic search of PubMed, Embase, The Cochrane Library and Web of Science was performed in February 2021, with studies assessing the effect of ICS on PJI rates identified. All studies, which included patients that received ICSI in the 12 months prior to primary hip and knee arthroplasty, were included. In total 12 studies were included: four studies with 209 353 hips and eight studies with 438 440 knees. ICSI administered in the 12 months prior to hip arthroplasty increased the odds of PJI [odds ratio (OR) = 1.17, P = 0.04]. This was not the case for knees. Subgroup analysis showed significantly higher odds of PJI in both hip [OR = 1.45, P = 0.002] and knee arthroplasty [OR = 2.04; P = 0.04] when ICSI was within the preceding 3 months of surgery. A significantly higher odds of PJI were seen in patients receiving ICSI within the 12 months prior to hip arthroplasty. Subgroup analysis showed increased odds of PJI in both hip and knee arthroplasty, in patients receiving ICSI within 3 months prior to their arthroplasty. We recommend delaying knee arthroplasty for at least 3 months after ICSI and possibly longer for hip arthroplasty. LEVEL OF EVIDENCE: Level III - Systematic Review of Level II and III Studies.

Prosthetic joint infection (PJI) affects between 0.76% and 1.24% of primary hips and knees in the Western world [1] . When PJI occurs, it has potentially devastating consequences, with associated morbidity and a 1-year mortality rate as high as 11% when arthroplasty is revised for PJI [2] . Treatment for PJI varies depending upon the patient profile and the severity of infection, which ranges from implant salvage procedures, such as liner exchange, to single or two-stage revision arthroplasties.

In recent decades, the demand for joint arthroplasty has increased and is projected to continue to rise further [3] . Recent studies project 3.5 million knee and 600 000 total hip arthroplasties will be performed in the USA by 2030 [4] . Accounting for the current incidence of PJI, we expect a disease burden of ∼50 000 PJIs annually. For all patients, arthroplasty is the best considered when non-operative measures have been exhausted. A recommended mode of symptom management in osteoarthritis is via intraarticular corticosteroid injections (ICSIs), often, as part of a multimodal pain management effort [5] [6] [7] [8] [9] , aiming to achieve symptom control by immunosuppression [10] . Injection into a native joint carries the inherent risk of intraarticular inoculation of pathogens.

It may be theorized that ICSI performed in the months leading up to arthroplasty may risk PJI although the precise time window for this remains unclear. Previous published systematic reviews and meta-analyses on this topic have conflicting results. Two of these meta-analyses concluded an increased risk of subsequent PJI following ICSI [11, 12] , while five other studies refuted this conclusion [13] [14] [15] [16] [17] . These studies have been criticized for their poor-quality study inclusion and high heterogeneity of their included studies. In this study, we provide an up-to-date systematic review and meta-analysis pertaining to the safe time interval between ICSI and arthroplasty. This is the first systematic review to investigate the temporal relationship between ICSI and odds of acquiring a PJI. Imposed delays to arthroplasty during coronavirus disease (COVID-19) pandemic and with many deferred patients reporting significant symptom progression [18] , we postulate that many may have opted for recent ICSI. After pandemic elective arthroplasty restrictions are lifted, most patients will be eager to undergo arthroplasty at the earliest opportunity [19] . This may potentially place them at a higher risk of PJI if our premise is correct.

The systematic review was performed based on the recommendations of Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA).

We performed a systematic search of the literature across PubMed, Embase, The Cochrane Library and Web of Science from the date of inception of each database through to February 2021. No 'grey literature' search was performed. The population of interest was patients with primary hip or knee arthroplasty.

Comparisons were made between patients who received ipsilateral ICSI to their native joint within the preceding 12 months of arthroplasty and those who did not. The outcome of interest was the diagnosis of PJI.

A literature search was performed using the following search terms and Boolean operators ('arthroplasty' OR 'joint replacement') AND ('injection' OR 'steroid' OR 'corticosteroid') AND ('prosthetic joint infection' OR 'periprosthetic infection' OR 'infection'). The title and abstracts were then screened by two reviewers independently (T.C. and M.J.) for relevance and consideration into a provisional list. The provisional list was then assessed independently by the two reviewers after reading full text for their potential inclusion. The two reviewers had a consensus on the included articles.

All articles comparing the two comparators on the patient population of interest were included. Studies that included patients who received ipsilateral ICSI more than 12 months prior to arthroplasty with sufficient data in their analysis for us to isolate the patient population of interest were included. Papers that 

Data extraction was performed by the first reviewer (T.C.) and validated by the second reviewer (M.J.). The individual study characteristics and outcomes of interest were assessed. Studies were grouped and assessed separately whether hip or knee arthroplasty. The methodological quality of studies included was assessed independently by both reviewers using the National Institute of Health Quality Assessment Tool for Observational Cohort and Cross-Sectional Studies. Publication bias was assessed using funnel plots.

The outcome of interest was the number of PJI in each group. Further subgroup analysis was performed, where study data allowed, regarding the incidence of PJI where ICSI was in the preceding 3 months of arthroplasty. Subgroup analysis was compared against the wider cohort if no readily matched cohort was available. Continuous variables were expressed as mean ± standard error of the mean. Where values were not readily available, this was calculated from the data provided. Statistical analysis was performed using the Mantel-Haenszel method, utilizing either a fixed effect model if the heterogeneity is <50% or a random-effects model if the heterogeneity is >50%. Odds ratio (OR) was used to illustrate the effects of each treatment arm on Forest plots. The corresponding 95% confidence interval (95% CI) and heterogeneity of data (I 2 ) are also illustrated in both Forest plots and full text. I 2 is a scale from 0 to 100% where higher values are associated with greater heterogeneity [20] . The statistical software used in this study was RevMan 5.4 (The Cochrane Collaboration, 2020).

Four hundred and seventy-two studies were identified with the initial search strategy. Fifty duplicate studies were removed. From the remainder, a further 392 studies were excluded by screening titles and abstracts. Twelve studies were included in the final analysis, of which four described PJI in hip arthroplasty [21] [22] [23] [24] , and the remaining eight described PJI in knee arthroplasty, [25] [26] [27] [28] [29] [30] [31] [32] each following intra-articular injections into native joints. The results of our literature search are displayed in Fig. 1 .

Four studies with a cumulative sample size of 209 353 hips described the odds of PJI in patients receiving ICSI within 12 months prior to ipsilateral hip arthroplasty [21] [22] [23] [24] , of which 9188 were in the ICSI group and 200 165 were in the control group. The baseline characteristics of the studies are outlined in Table I . There was no significant heterogeneity between the studies [I 2 = 0%, P-value = 0.86], and hence, a fixed-effect model was used. There was a significant difference in rates of PJI between the two arms [OR = 1.17, 95% CI = 1.01-1.36, P-value = 0.04]. The Forest plots for this are shown in Fig. 2a .

Two studies [23, 24] with 202 758 hips, of which 2992 were in the ICSI group and 199 766 were in the control group, analyzed the effect of ICSI on the odds of PJI within the 3 months prior to ipsilateral hip arthroplasty. There was no heterogeneity between the studies [I 2 = 0%, P-value = 0.67], and hence, a fixed-effect model was used. There was a significantly increased rate of PJI in patients who received an ICSI in 3 months preceding hip arthroplasty [OR = 1.45, 95% CI = 1.15-1.83, P-value = 0.002]. The results of the Forest plots are shown in Fig. 2b . 

Eight studies that enrolled a total of 438 440 cases described the rates of PJI of knee arthroplasty patients who received ICSI within 12 months prior to knee arthroplasty [25] [26] [27] [28] [29] [30] [31] [32] , of which 107 981 were in the ICSI group and 330 459 were in the control group. The baseline characteristics of these studies are outlined in Table II . There was significant heterogeneity [I 2 = 99%, P-value < 0.00001] between studies, and hence, a random effect model was used. There was no significant difference in rates of PJI between those patients who had and those who had not received ICSI within 12 months prior to their knee arthroplasty [OR = 1.96, 95% CI = 0.97-3.96, P-value = 0.06].

The results of the Forest plots are shown in Fig. 3a .

Six of those eight studies with a total of 309 283 knees, of which 35 600 were in the ICSI group and 273 683 were in the control group, described the rates of PJI in patients who received ICSI within 3 months prior to arthroplasty [25-27, 29, 30, 32] . There was significant heterogeneity [I 2 = 97%, P-value < 0.00001] between studies, and hence, a random effect model was used. There was a significantly increased odds of PJI in those who had received ICSI within 3 months prior to arthroplasty, compared to those who had not [OR = 2.04, 95% CI = 1.05-3.97, P-value = 0.04]. The Forest plots are shown in Fig. 3b .

Risk of bias in individual studies was analyzed using the National Institute of Health Quality Assessment Tool for Observational Cohort and Cross-Sectional Studies. The results are displayed in Table III . No studies provided any justification for sample size or the number of ICSI. Concerningly, a study by Amin et al. categorized patients into one of three groups: no injection, steroid injection or viscosupplementation injection. However, the group classification was based upon which injection the patient last had, which may have led to significant bias in the results [25] . It was unclear from all studies whether outcome assessors were blinded to the exposure status of the participants.

Funnel plots were constructed to assess the risk of publication bias. There was symmetry in the hip arthroplasty studies (Fig. 4a) , suggesting a low risk of publication bias. Knee arthroplasty studies on the other hand demonstrated asymmetry, suggesting significant publication bias (Fig. 4b) .

The results of our systematic review and meta-analysis showed that there were increased odds of PJI when ICSI was administered within 12 months prior to hip arthroplasty. In knee arthroplasty, the odds of PJI were increased, although not significantly, when ICSI was administered 12 months prior to arthroplasty and should be interpreted with caution given high heterogeneity. Further subgroup analysis revealed significantly increased odds of PJI for both hip and knee arthroplasty when ICSI was administered within 3 months prior to arthroplasty. In hip arthroplasty, there appeared to be a temporal relationship, whereby the odds of PJI decreased from 1.45 at 3 months prior to 1.17 within 12 months prior to their arthroplasty. We postulate our significant findings to be due to the immune-modulatory effects of steroids or the inherent risk of inadvertent inoculation of pathogens at ICSI [32] [33] [34] [35] . Both these possible scenarios warrant wider investigation. Furthermore, we believe a broader Table III . Risk of bias analysis using the National Institute of Health assessment tool for observational cohort and cross-sectional studies Was the research question or objective in this paper clearly stated?

Was the study population clearly specified and defined?

Was the participation rate of eligible persons at least 50%?

Were all the subjects selected or recruited from the same or similar populations (including the same time period)? Were inclusion and exclusion criteria for being in the study prespecified and applied uniformly to all participants? Was loss to follow-up after baseline 20% or less?

Were key potential confounding variables measured and adjusted statistically for their impact on the relationship between exposure(s) and outcome(s)? Fig. 4 . investigation may be warranted into the benefit, risk and complication of intraarticular platelet-rich plasma (PRP) or bone marrow aspirate concentrate (BMAC) injection to the arthritic hip and knee joint, a rapidly embraced clinic treatment in this particular patient population [36, 37] . Although there is weak evidence for the use of BMAC and PRP in hip or knee osteoarthritis [38, 39] , the infection rates of each of these treatment modalities are yet to be established. This study is even more relevant at present, with critical demands placed upon overstretched healthcare systems across the world amidst the current COVID-19 pandemic; there has been significant disruption to elective arthroplasty schedules around the world. To appreciate the magnitude of this backlog, an estimated 30 000 primary and 3000 revision hip and knee arthroplasty procedures were cancelled in each week of imposed elective surgery restrictions within the United States alone [40] . During the early stages of the pandemic, there was an initial widespread abandonment of ICSI; however, as the pandemic progressed, there have been peak body recommendations and multiple other studies advocating the safe utility of ICSI in hip and knee osteoarthritis [18, [41] [42] [43] [44] . Brown et al. surveyed over 800 patients across 15 institutions in the USA, each planned for elective hip or knee arthroplasty but rescheduled due to the pandemic. They found that 54% of respondents reported worsening arthritis symptoms during this period and 87% respondents remained eager to have their arthroplasty soonest deemed safe [19] . In this setting, it is highly likely that such patients with daily intrusive pain of arthritis may opt to temporize symptoms with ICSI [42] . This may risk patients having ICSI in narrow and unsafe timeframes in relation to their rescheduled arthroplasty. Clinicians and patients should be educated and alerted to this potential risk and be vigilant when rescheduling long-awaited arthroplasty.

Varied case definition for PJI between studies is seen in Tables I and 2 . Some of the large studies utilized coding systems, either state-wide [23, 30] or insurance based [24, 26, 32] , to identify patients with PJI. These systems, although efficient, are prone to potential erroneous under-reporting of cases of PJI. Other studies analyzed cases on individual merit and utilized variations of the Musculoskeletal Infection Society (MSIS) criteria. Our study has inherent limitations by virtue of design and inclusion criteria. Our study cohorts may have included those with undeclared confounding interventions with potential to influence PJI. These modalities may have included intraarticular synovial fluid supplementation [45] , intraarticular injectable cellular therapies (such as PRP or BMAC) [46] and potentially acupuncture [47] . Additionally, the number of ICSI provided in the study period was unclear in most studies. Additionally, variation of follow-up intervals (ranging from 6 to 131 months) in included studies may have affected their reported rates of PJI.

Only two of the 12 studies included in our final analysis were prospective cohort studies. The remaining studies were either retrospective cohort studies or retrospective matched cohort studies, which provided Level III evidence. There were no randomized controlled trials that were identified in this systematic review. There was also potentially significant publication bias in the knee arthroplasty studies, as evidenced by the funnel plot analysis in Fig. 4b , despite our attempt to limit publication bias by including wider databases, such as Web of Science. Other causes for funnel plot asymmetry, such as selective outcome reporting and selective analysis reporting may also be present [48] . Future systematic reviews and meta-analysis of this topic should consider obtaining unpublished data to help reduce publication bias. Lastly, there may be the introduction of bias in our subgroup analyses, as our comparator group was not a matched cohort in all studies apart from Kurtz et al. [30] . A singular definition of PJI and higher-quality prospective studies should provide more robust data to enhance future best practice.

In conclusion, within the confines of our study, ICSI performed within 3 months prior to arthroplasty significantly increased the odds of PJI in both hip [OR = 1.45, P-value = 0.002] and knee arthroplasty [OR = 2.04; P-value = 0.04] and, thus, best avoided. There was a significant increase in odds of PJI when ICSI was administered 12 months prior to hip arthroplasty [OR = 1.17, P-value = 0.04]. Patients considering hip arthroplasty within 12 months of ICSI should be appropriately counseled based on this finding. This is of particular importance in the months ahead, if we are to collectively and safely guide the prompt delivery of arthroplasty once COVID-19 pandemic arthroplasty restrictions are lifted. Higher-quality prospective studies with a standardized definition of PJI may reliably enhance our future understanding of the implications and safety of ICSI.

Infection burden in total hip and knee arthroplasties: an international registry-based perspective

Increased mortality after prosthetic joint infection in primary THA

The projected burden of primary total knee and hip replacement for osteoarthritis in Australia to the year 2030

Timing of rehabilitation on length of stay and cost in patients with hip or knee joint arthroplasty: a systematic review with meta-analysis

Intra-articular corticosteroid treatment in osteoarthritis

Inflammatory characteristics on ultrasound predict poorer longterm response to intraarticular corticosteroid injections in Knee Osteoarthritis

Symposium: evidence for the use of intra-articular cortisone or hyaluronic acid injection in the hip

Outcomes of intraarticular corticosteroid injections for adolescents with hip pain

Outcomes of intraarticular corticosteroid injections for adolescents with hip pain

Intraarticular injections (corticosteroid, hyaluronic acid, platelet rich plasma) for the knee osteoarthritis

Dose intraarticular steroid injection increase the rate of infection in subsequent arthroplasty: grading the evidence through a meta-analysis

Intra-articular steroid injections and risk of infection following total hip replacement or total knee replacement: a meta-analysis of cohort studies

Does intra-articular corticosteroid injection in the pre-operative period increase the risk of joint infection following hip or knee arthroplasty? A systematic review and meta-analysis

Does previous intra-articular steroid injection increase the risk of joint infection following total hip arthro plasty or total knee arthroplasty? A meta-analysis

Do intra-articular steroid injections increase infection rates in subsequent arthroplasty? A systematic review and meta-analysis of comparative studies

Intra-articular steroid injection for osteoarthritis of the hip prior to total hip arthroplasty is it safe? A systematic review

Total joint arthroplasty following intra-articular steroid injection: a literature review

Unintended consequences of COVID-19 safety measures on patients with chronic knee pain forced to defer joint replacement surgery

The effect of the COVID-19 pandemic on hip and knee arthroplasty patients in the United States: a multicenter update to the previous survey

Quantifying heterogeneity in a metaanalysis

Recent intraarticular steroid injection may increase infection rates in primary THA

Is the infection rate in primary THA increased after steroid injection?

Preoperative hip injections increase the rate of periprosthetic infection after total hip arthroplasty

The timing of total hip arthroplasty after intraarticular hip injection affects postoperative infection risk

The risk of a deep infection associated with intraarticular injections before a total knee arthroplasty

The John N. Insall award do intraarticular injections increase the risk of infection after TKA?

Does timing of previous intra-articular steroid injection affect the post-operative rate of infection in total knee arthroplasty?

Does intraarticular steroid infiltration increase the rate of infection in subsequent total knee replacements?

Do prior intra-articular corticosteroid injections or time of administration increase the risks of subsequent periprosthetic joint infections after total knee arthroplasty?

Intra-articular corticosteroid or hyaluronic acid injections are not associated with periprosthetic joint infection risk following total knee arthroplasty

Infection in knee replacements after previous injection of intra-articular steroid -reply

Comparison of infection risk with corticosteroid or hyaluronic acid injection prior to total knee arthroplasty

Systemic effects of intra-articular corticosteroids

Injections through skin colonized with Staphylococcus aureus biofilm introduce contamination despite standard antimicrobial preparation procedures

Inadvertent introduction of tissue coring into joints during arthrocentesis: an experimental study

Comparison between intraarticular infiltrations of placebo, steroids, hyaluronic and PRP for knee osteoarthritis: a Bayesian network meta-analysis

Concentrated bone marrow aspirate for the treatment of chondral injuries and osteoarthritis of the knee: a systematic review of outcomes

The use of biologics to improve patient-reported outcomes in hip preservation

Biologic therapies for the treatment of knee osteoarthritis

Total joint arthroplasty during the COVID-19 pandemic: a scoping review with implications for future practice

Should I use steroid injections to treat shoulder pain during the COVID-19 pandemic?

FPM response to concern related to the safety of steroids injected as part of pain procedures during the current COVID-19 virus pandemic

United Kingdom: British Orthopaedic Association, Association of Chartered Physiotherapists in Orthopaedic medicine and injection therapy, British Association of Spinal Surgeons and the British Society for Rheumatology

Intra-articular hyaluronic acid injections less than 6 months before total hip arthroplasty: is it safe? A retrospective cohort study in 565 patients

Ethical and practical considerations for integrating cellular ("stem cell") therapy into clinical practice

Acupuncture needleassociated prosthetic knee infection after total knee arthroplasty

Recommendations for examining and interpreting funnel plot asymmetry in meta-analyses of randomised controlled trials

Not Applicable.

We would like to acknowledge the contribution of Dr Sonia Hines for her valuable input into the statistical analysis and interpretation of collated data