Patients’ risk factors for periprosthetic joint infection in primary total hip arthroplasty: a meta-analysis of 40 studies

Total hip arthroplasty (THA) has served as a successful elective surgical procedure that provides pain relief, restores joint function, and consequently enhances overall quality-of-life for millions of patients worldwide [1‐3]. Although most patients benefit significantly from this advanced technique, there is still a minority of patients may suffer with device failure and thereby need additional operations [4, 5].

Periprosthetic joint infection (PJI) is defined as infection involving the joint prosthesis and adjacent tissue. Its incidence is rare, which has been reported to range from 0.25 to 2.0% [6]. However, this morbidity may be devastating since it could jeopardize the results of the procedure, and even increase mortality [1, 7]. Currently, tremendous efforts have been implemented and improvements in prosthesis material and surgical technique have been achieved in THA [8]. However, the incidence of PJI is still increasing worldwide alongside the uprising prevalence of revision surgery, morbid obesity epidemic, and other comorbidities. Treatments for PJI usually comprise prolonged systemic antibiotic treatment, debridement and revision, which may pose substantial burden of compromised function and impaired quality of life to the patients [1, 6]. Moreover, patients with PJI are also associated with higher financial burden and greater medical resource utilization on the health care system [4, 9, 10]. Accordingly, identification of potential risk factors is of great importance for early detection and reduction of the deleterious consequence that attributed to PJI.

Nowadays, attention has been directed toward a plausible link between PJI and patients’ individual risk factors in addition to the surgical- and hospital-related factors. More recently, substantial studies regarding the patient-related risk factors for PJI, such as obesity [4, 11‐14], diabetes mellitus (DM) [14‐17], male gender [18], rheumatoid arthritis (RA) [19, 20], and pulmonary diseases [6, 21], have been reported. However, the power of these studies may be impaired due to limited numbers of recruited patients, controversial results and range of potential risk factor studies. Besides, many of these risk factors were updated and even revised in recent years, which may consolidate or oppose against the previous results. Moreover, optimization of modifiable risk factor for PJI should be emphasized in clinical practice, while only limited studies have separated the modifiable and non-modifiable risk factors to PJI. Given the limitations and remained discrepancies abovementioned, we took into account all the available literature and performed this updated meta-analysis, aiming to identify the potential individual risk factors for PJI undergoing primary THA.

Our meta-analysis focused on the patient-related factors associated with PJI, other than surgical- or hospital-related factors. The main finding of this meta-analysis was that the high BMI was the main risk factor for PJI. Additionally, DM and other comorbidities, such as AVN, RA, CVD, CPD, neurological disease, opioid use and IDA were also pivotal risk factors for PJI. In contrast, dysplasia or dislocation, OA were protective factors. Besides, female gender was protective after long follow-up duration (≥3 years). Moreover, age, smoking, alcohol abuse and other medical history such as previous joint surgery, renal disease, hypertension, cancer, steroid use and liver disease were not correlated with risk of PJI.

Obesity poses a major health challenge worldwide [1]. Consistent with previous finding [18, 61], our data showed that patients with a BMI greater than 40, 35, or 30 had a 2.99, 2.46, or 2.02–fold higher risk of PJI compared with those counterparts with less BMI, respectively. Obese patients are more prone to increased risk of PJI in the peri-operative setting, which may be attributed to prolonged operative and anesthetic time, higher colonization risk for C. avidum in the groin [11], longer hospital stay and high readmission rates within 30 days [9]. Besides, being obese is usually correlated with higher presence of other commodities including metabolic syndrome, wound dehiscence, and heart disease [1]. Notably, we found that the PJI risk increased exponentially along with BMI value. Similarly, Xu C et al. demonstrated that each one-unit increase in BMI was correlated with an 8% higher risk of PJI [4], thus the morbidly obese patients (BMI > 40 kg/m²) may have the highest likelihood of complications [13]. Another study also confirmed that all-cause revision rater after primary TJA doubled in patients with BMI ≥35 kg/m², and even tripled in morbidly obese patients when compared with the controls [7, 62]. Accordingly, the increased risk of obesity should be weighed against the benefits of THA [7].

The relationship between DM and PJI has been well-established with a projected increase for years [18, 61, 63]. Our study showed that, comparing with non-DM patients, those undergoing THA with DM carried 1.69-fold greater risk of PJI (1.69, 1.26–2.28). Further stratified analyses, such as location, study design or analyses method, did not alter the unfavorable predictive value of DM on PJI risk. Epidemiological studies have identified that DM predisposes patients to PJI, probably due to increased infection rate of bacteria, impaired immune response, and postoperative hyperglycemia [64]. HbA1c is a widely used biomarker for diagnosis and monitoring of type 2 DM [17]. Recently, Cancienne JM et al. reviewed 7736 patients who underwent THA, and identified that HbA1c of 7.5 mg/dl could serve as a threshold for prediction of PJI after THA [10].

Both two studies reported the association between AVN or femoral neck fracture and PJI, and the pooled results indicated a 1.65 or 1.75-times increased risk of PJI than non-group, respectively. In contrast, four studies demonstrated the relationship between OA and PJI risk, and the calculated RR with corresponding CI was 0.70 (0.62–079), suggesting a protective role of OA in PJI. It is generally accepted that patients underwent THA for AVN are more likely to have readmission and surgical complications including bleeding transfusion [65]. Meanwhile, patients with femoral neck fracture undergoing THA also confer to higher rate of dislocation, infection and reoperation [66], which may be accountable for the increased risk of PJI [67]. OA refers to a common degenerative joint disease, and contribute to a majority cause for THA. However, compared with other commodities, patients with OA seem to have decreased occurrence of PJI after surgery. Another meta-analysis consisting of 37 studies reached a similar conclusion, showing that OA was protective factor in predicting PJI after THA/TKA [18]. Besides, Mayers W et al. searched the patients’ profiles with primary THA in US from 2001 to 2010, and found that patient underwent THA for OA have lesser medical complications and lower incidence for myocardial infarction than those with AVN [68].

RA and CVD have been reported as independent risk factors for PJI [3, 69]. Consistently, our results showed that PJI incidence were 1.37 or 1.34 times higher in patients reporting a history of RA or CVD, respectively. Patients with RA are more susceptible to PJI thought to be secondary to immune-suppressive therapies and poor nutritional conditions [18, 20]. Meanwhile, patient with CVD are recommended to receive aggressive anticoagulation therapy, such as aspirin or warfarin, may markedly increases risk of bleeding and wound hematoma after THA [1, 69], and thereby increase PJI rate [18].

Moreover, our study showed that patients with chronic pulmonary disease had 1.22–fold higher risk and with neurological disease had 1.19-fold higher risk (1.19, 1.05–1.35) of PJI when compared with non-group, which is in accordance with the published literature [3, 18, 69]. A meta-analysis conducted by Resende VAC et al. [18] showed that chronic lung disease significantly increased the risk for PJI after TJA. In addition to THA/TKA, another large multi-institutional retrospective study comprising 6977 patients also revealed a significant positive association between chronic lung disease and total ankle arthroplasties (TAA) [70]. More recently, a meta-analysis with eight studies enrolled further confirmed that increased risk of PJI following TAA for patients with lung disease [71].

Gender shows conflicting results among the selected studies. A number of studies have demonstrated that male patients are more vulnerable to PJI compared to women [18, 67]. Whereas other studies have refuted this, claiming women had an elevated risk of deep infection than men [48, 72]. Our results showed that gender was markedly correlated with PJI risk (1.17, 1.03–1.32) and female maybe a protective factor of PJI after THA. It is worth noting that male patients seem to coincide with higher incidence of unfavorable behavioral factors, which may result in increased risk of PJI.

The impact of age has been controversial among the enrolled studies. In general, older patients are more prone to postoperative infection caused by less competent immunity [5], malnutrition status [64] and complex medical comorbidities [8]. On the contrary, a multi-center analysis of 623,253 joint replacements claimed that younger age was closely correlated with elevated PJI [40], which may be attributed to active use cycles of implants, higher possibility of infection and revision surgery [64]. Besides, another meta-analysis with 2,470,827 patients also demonstrated older age was a protective factor in TJA [18]. Interestingly, we found that age had not direct influence on risk rate of PJI (0.85, 0.71–1.01), which was consistent with the results concluded by Kunutsor SK et al [73]. Recently, a single-center retrospective study comprising 23,966 patients also demonstrated that age alone was not a risk factor for PJI after adjusting for confounding variables [8], indicating that other covariates should be taken into account for assessing the relationship between age and PJI. Future studies are needed to further address these findings by adequately controlling the confounders.

Previous meta-analyses have demonstrated that smoking and alcohol abuse may result in increased risk PJI. Therefore, it is of great importance to encourage smoking and alcohol cessation during peri-operation period, and some reports suggested a 4–6 week cessation prior to surgery may be effective [1]. Specifically, excessive smoking was documented as to increase incidence of infection, mainly due to impaired wound-healing capacity, disrupted immune response, as well as nicotine or carbon monoxide-mediated vasoconstriction, soft-tissue hypo-perfusion, hypoxia, and thrombi formation [1]. While alcohol could affect the immune system and contribute to impaired phagocytic function [64]. In addition, alcohol abuse is a deleterious factor for developing cirrhosis, which may in turn increase risk of infection [64]. Intriguing, our pooled results showed that smoking and alcohol abuse were not correlated with PJI following THA. However, it should be noted that smoking may contribute to synergistic effect on elevated risk of PJI (3.54-fold) for patients with obesity [4, 74]. Accordingly, caution is still warranted when considering a THA in tobacco and alcohol users. More trials are still needed to extensively elucidate the underlying mechanism between smoking/ alcohol abuse and PJI.

It is imperative that both the surgeons and patients understand and identify the modifiable risk factors prior to THA so that they could make prudent decisions in the perioperative management, mitigate the risk of PJI, and therefore decrease the enormous financial and social burden of PJI [1, 9]. The findings in this meta-analysis, along with advanced diagnostic and treatment approaches, will allow the development of prevention strategies and increase the adherence to the clinical practice. Taken together, these results may offer help in developing guidelines on prevention of PJI after THA, and eventually establishing strategies to control it.

In addition to the factors discussed above, preoperative and intraoperative factors also play important roles. Nasal Staphylococcus aureus (S. aureus) decolonization by the strategies of antibiotic prophylaxis has been widely used to prevent PJI before THA. The influence of preoperative decolonization on PJI was discussed in a recent meta-analysis including 36,000 cases of primary THA and TKA. S. aureus screening and decolonization prior to primary THA were associated with a significantly decreased risk of surgical site infections and PJI [75]. Moreover, whether the fixation method influences the risk of PJI following THR is still controversial. A recent meta-analysis reported that all kinds of cemented fixations including plain, antibiotic and hybrid were each associated with an increased PJI risk when compared with uncemented fixations. In cemented fixations group, plain cemented fixations increased PJI risk compared to antibiotic-loaded cemented fixations [76, 77]. Furthermore, different prosthetic bearing surface materials may influence the risk of PJI after THA. A previous meta-analysis comprised 11 randomized controlled trials and six observational studies until September 2016 compared the rate of PJI between metal-on-polyethylene (MoP), ceramic-on-polyethylene (CoP), and ceramic-on-ceramic (CoC) bearings. It showed no significant difference between the three bearing combinations in terms of risk of PJI [78]. Although no bearing surfaces can deny the risk currently, subsequent articles containing large amounts of data have found that ceramic surfaces could reduce risk are convincing [40, 79, 80]. In addition, a prospective observational cohort study analyzing 623 253 primary THA investigated lateral surgical approach was associated with the increased risk of PJI from 3 months onwards patients compared to posterior surgical approach, due to the increased tissue damage and bleeding, probably [40].

However, it should be noted that some limitations remain to be addressed. First, most of the studies were retrospective, giving rise to a comparative low quality of evidence as per the NOS score. In addition, high proportion of retrospective studies would lead to inherent bias inevitably [81]. Second, number of included hips among the selected studies ranged from 33 to 1,158,742, the inclusion of these studies may lead to bias and confounding within our results. Third, some of the comparison like AVN of femoral head, femoral neck fracture, chronic pulmonary disease, IDA, dysplasia or dislocation of hip, cancer and liver disease included 2 studies only, respectively. It might limit the meaning of these pooled result. Fourth, the RRs were not adjusted to include more participants. Fifth, the follow-up time was heterogeneous among studies with a range from 0.25 to 10 years and did not differentiate time of onset of infection after primary arthroplasty. Sixth, the included studies were performed between 1983 to 2020. The THA operation technology in different period was significantly different, especially in two studies in 1983 and 1984.This maybe a reason for the bias of this meta-analysis. Seventh, the races vary among the selected studies, which may lead to discrepancies between various studies [64]. Lastly, another relevant issue and potential confounder of the results was the different diagnostic tools for PJI used in the original studies and the lack of a risk factor definition in the eligible studies, except for obesity was defined as BMI.

Taken together, this meta-analysis identified significant risk factors for PJI associated with THA are high BMI, DM, AVN, femoral neck fracture, RA, CVD, chronic pulmonary disease, neurological disease, opioid use and IDA while protective factors include female gender, OA and dysplasia/ dislocation. We therefore suggest optimization of modifiable risk factors such as BMI for reducing the risk of PJI in clinical practice.