Abstract
Aims
Deep surgical site infection (SSI) remains an unsolved problem after hip fracture. Debridement, antibiotic, and implant retention (DAIR) has become a mainstream treatment in elective periprosthetic joint infection; however, evidence for DAIR after infected hip hemiarthroplaty is limited.
Methods
Patients who underwent a hemiarthroplasty between March 2007 and August 2018 were reviewed. Multivariable binary logistic regression was performed to identify and adjust for risk factors for SSI, and to identify factors predicting a successful DAIR at one year.
Results
A total of 3,966 patients were identified. The overall rate of SSI was 1.7% (51 patients (1.3%) with deep SSI, and 18 (0.45%) with superficial SSI). In all, 50 patients underwent revision surgery for infection (43 with DAIR, and seven with excision arthroplasty). After adjustment for other variables, only concurrent urinary tract infection (odds ratio (OR) 2.78, 95% confidence interval (CI) 1.57 to 4.92; p < 0.001) and increasing delay to theatre for treatment of the fracture (OR 1.31 per day, 95% CI 1.12 to 1.52; p < 0.001) were predictors of developing a SSI, while a cemented arthroplasty was protective (OR 0.54, 95% CI 0.31 to 0.96; p = 0.031). In all, nine patients (20.9%) were alive at one year with a functioning hemiarthroplasty following DAIR, 20 (46.5%) required multiple surgical debridements after an initial DAIR, and 18 were converted to an excision arthroplasty due to persistent infection, with six were alive at one year. The culture of any gram-negative organism reduced success rates to 12.5% (no cases were successful with methicillin-resistant Staphylococcus aureus or Pseudomonas infection). Favourable organisms included Citrobacter and Proteus (100% cure rate). The all-cause mortality at one year after deep SSI was 55.87% versus 24.9% without deep infection.
Conclusion
Deep infection remains a devastating complication regardless of the treatment strategy employed. Success rates of DAIR are poor compared to total hip arthroplasty, and should be reserved for favourable organisms in patients able to tolerate multiple surgical procedures.
Cite this article: Bone Jt Open 2021;2(11):958–965.
Take home message
Debridement, antibiotic, and implant retention (DAIR) has a low chance of success after an infected hip hemiarthroplasty.
In patients failing to respond to the initial DAIR, or an unfavourable organism is cultured, then an excision arthroplasty should be performed, rather than recurrent washouts or stem exchange.
Deep infection remains an unsolved problem in this vulnerable patient cohort, and avoidance of infection remains key.
Introduction
Deep surgical site infection (SSI) after hip hemiarthroplasty is a devastating complication with high morbidity and mortality.1,2 Debridement, antibiotic therapy and implant retention (DAIR) has become a mainstay in the initial treatment of deep periprosthetic joint infection (PJI). There is a growing body of evidence to support DAIR for deep infection after an elective total hip arthroplasty (THA), with studies demonstrating implant survival of 75% to 90%.3 When DAIR fails to eradicate infection, patients may require a single or two-stage revision, and both approaches have been shown to have relatively high rates of success.4
Hemiarthroplasty is the most common treatment for elderly patients with displaced femoral neck fractures.5 Approximately 19,000 hemiarthroplasties are performed for hip fracture in England, Wales, and Northern Ireland each year.6 Rates of deep infection are high at up to 4.9% when compared to elective THA at 0.5%.7-9 Despite the high prevalence, there is paucity in quality evidence on the management of SSI after hemiarthroplasty. Prompt debridement and implant removal or excision arthroplasty has historically been a standard practice.10 In contrast to THA, many hemiarthoplasty stems are of a monoblock design, limiting options for bearing exchange.11 With widespread use of a tapered polished stem as an implant of choice for hip hemiarthroplasty, the stem exchange is also accepted as a part of thorough debridement. Hip fracture patients are often frailer than elective patients, and have the added insult of their injury further complicating their recovery.
The purpose of this study was to assess outcomes in patients undergoing treatment for deep SSI after hip hemiarthroplasty. We also aim to report the risk factors for developing SSI after hemiarthroplasty, and factors influencing success with treatment for deep SSI.
Methods
Data source and collection
A local prospective registry data of all hip fracture admissions to our institution formed the population for this study. All trauma patients admitted to our institution (Queen's Medical Centre, Nottingham, UK) are included within the registry, which monitors the process of care, return to theatre and outcomes; these records are maintained by the admitting clinical team with data entry supported by audit personnel.
Consecutive patients who underwent a primary hip hemiarthroplasty between August 2007 and August 2018 were identified. Patients were eligible to be included in the study if they had undergone a primary hemiarthroplasty for hip fracture. Patients were excluded if they were undergoing revision surgery for periproethetic fracture or dislocation. Patients who subsequently underwent surgery for deep infection were analyzed to assess success rates after DAIR or primary excision arthroplasty.
Demographic information, including age, sex, and medical comorbidities, were assessed to identify potential predictors of developing a SSI. Urinary tract infection (UTI) and pressure sores diagnosed either preoperatively or during the inpatient stay post-surgery were recorded. Variables within the paper were prospectively recorded within the registry during the index admission.
Each case of SSI that had been prospectively recorded was manually checked retrospectively by the authors (SC, JN) against the electronic patient record, microbiology laboratory results, and available radiological investigations to ensure data fidelity. Mortality data was cross-validated with data from the Office of National Statistics.12 Patient records were reviewed for readmission or revision surgery and mortality within one year of their index procedure.
Diagnosis of infection
Infection surveillance is prospective and conducted on a rolling basis, with each patient monitored for 12 months to document development of an infection. In addition to prospectively monitoring readmission and return to theatre data, surveillance is carried out in partnership with the microbiology team, who provide orthopaedics with a monthly line-listing of all positive microbiology samples that have occurred either within the trust or community settings. This line-listing is linked to the orthopaedic registry, and matched cases indicate an orthopaedic admission and a positive sample. Readmissions are prospectively reviewed by the audit team for evidence of SSI. Infection is defined and classified as deep or superficial as per the Centre for Disease Control (CDC) criteria.13 The pre-2013 criteria were used as the post-2013 criteria has been shown to exclude up to 10% of orthopaedic SSI.14 Our hospital (Queen's Medical Centre) is the only facility providing emergency care for our catchment population of approximately 750,000 people; infections presenting after discharge will present back to our unit and be collected in the database.
Bacteriology
Wound swabs were processed using a variety of selective media to identify aerobic and anaerobic pathogens. Samples of pus or tissue obtained during surgery were plated on non-selective agar for aerobic and anaerobic incubation, and also suspended in an enrichment broth culture. All microbiological samples were cultured for seven days.
Surgical technique
The majority of patients undergoing a hemiarthroplasty at our institution receive a cemented monoblock implant with gentamicin containing cement. It is our practice to use uncemented hip hemiarthroplasty in patients otherwise considered at high risk of developing cement implantation syndrome, or with other significant medical comorbidities. Since 2015, stem exchange without removal of the cement mantle has been advocated as part of DAIR, although this is still ultimately left to the discretion of the treating surgeon. This is a local unit policy and is based on anecdotal, rather than published, evidence.
Statistical analysis
Demographic differences between patients with and without SSI, and for patients undergoing DAIR and excision arthroplasty, were compared using Pearson’s chi-squared test and independent-samples Student’s t-test. Due to the large sample size, parametric tests were preferred, regardless of data skew. Binary multivariate logistic regression was used to adjust for potential confounders between the two groups when comparing risk factors for developing SSI and predictors of a successful DAIR at one year. A successful DAIR was defined as a retained implant in an alive patient, without the use of suppressive antibiotics, at one year post-surgery. Variables previously thought to potentially influence success of DAIR that were analyzed included time from index case to DAIR, cementation and organism, and stem exchange.15
Significance was defined as p-value < 0.05. Endpoints of both SSI and success of DAIR were used, along wiht mortality at one year. Regression analysis and multiple imputation was performed using SPSS version 24.0 (SPSS, USA). Kaplan-Meier curve estimators were produced using GraphPad Prism version 8 (GraphPad, USA).
Results
Sample
A total of 3,966 eligible patients were identified. The overall rate of SSI within the cohort was 1.74%; 51 patients (1.29%) were diagnosed with a deep infection, while 18 (0.45%) were treated for a superficial SSI. More patients with SSI also had a urinary tract infection (UTI) (427 (10.96%) vs 17 (24.64%); p < 0.001, chi-squared test), pressure sores (40 (1.03%) vs three (4.41%); p = 0.008, chi-squared test), and were less likely to have had a cemented hemiarthroplasty (2,940 (75.44%) vs 44 (63.77%); p = 0.026, chi-squared test) than patients without SSI. Demographics are shown in Table I.
Table I.
Variable | No infection, n = 3,897, n (%) |
Any SSI, n = 69, n (%) | p-value | Deep SSI only, n = 51, n (%) | p-value |
---|---|---|---|---|---|
Urinary tract infection | 427 (10.96) | 17 (24.64) | < 0.001* | 11 (21.57) | 0.017† |
Pressure sore | 40 (1.03) | 3 (4.41%) | 0.008† | 2 (3.92) | 0.039† |
Cemented hemiarthroplasty | 2,940 (75.44) | 44 (63.77) | 0.026† | 33 (64.7) | 0.077† |
Days delayed before surgery, mean (SD) | 0.52 (1.01) | 0.96 (1.50) | 0.019* | 0.75 (1.26) | 0.213* |
Age, yrs, mean (SD) | 82.45 (8.89) | 82.20 (10.06) | 0.816* | 82.26 (10.83) | 0.900* |
Admission from institution | 808 (20.85) | 17 (24.6) | 0.443† | 13 (25.49) | 0.418† |
Female sex | 2,779 (71.01) | 49 (71.31) | 0.957† | 34 (66.67) | 0.467† |
Renal disease | 495 (12.7) | 8 (11.59) | 0.784† | 7 (13.73) | 0.827† |
Diabetes | 601 (15.42) | 16 (23.19) | 0.078† | 12 (23.53) | 0.112† |
Rheumatoid arthritis | 117 (3.0) | 1 (1.45) | 0.452† | 1 (1.96) | 0.664† |
Smoker | 358 (9.19) | 8 (11.59) | 0.493† | 6 (11.76) | 0.527† |
Steroids | 125 (3.21) | 0 (0.0) | 0.131† | 0 (0.0) | 0.194† |
Warfarin | 225 (5.77) | 5 (7.25) | 0.604# | 4 (7.84) | 0.530† |
Clopidogrel | 144 (3.61) | 3 (4.35) | 0.776† | 1 (1.96) | 0.513† |
Operative duration, mins, mean (SD) | 94.89 (33.85) | 92.20 (30.35) | 0.469* | 95.53 (30.51) | 0.882* |
Pathological fracture | 45 (1.16) | 1 (1.45) | 0.821† | 1 (1.96) | 0.594† |
AMT less than 7 | 1,373 (35.6) | 25 (36.23) | 0.913† | 18 (35.39) | 0.953† |
ASA grade, mean (SD) | 2.93 (0.71) | 2.96 (0.65) | 0.939* | 2.94 (0.583) | 0.889* |
-
*
Pearson’s independent-samples chi-squared test.
-
†
Students t-test.
-
AMT, Abbreviated Mental Test; ASA, American Society of Anaesthesiology; SD, standard deviation; SSI, surgical site infection.
Missing data
American Society of Anaesthesiology (ASA) grade had a high level of missing data (1,304 cases; 32.87%). Due to the likelihood of collinearity with other medical comorbidities, ASA was not used in the regression model.
Missing data for other variables was in general was low; 49 patients (1.24%) had at least one missing variable. Data was missing for admission source (22 cases; 0.56%), AMT (40 cases; 1.01%), and presence of a pressure sore (nine cases; 0.23%). Due to the low level of missing data for these variables, complete case analysis was performed rather than imputation.16 A complete dataset was available for all other covariables.
Risk factors for SSI
Delay in time to surgery (OR 1.32, 95% CI 1.13 to 1.54; p < 0.001), (OR 2.83, 95% CI 1.60 to 5.01; p < 0.001, multivariable logistic regression), presence of pressure sores (OR 3.49, 95% CI 1.00 to 12.17; p = 0.050, multivariable logistic regression), and UTI were predictors of SSI. Only 4/17 patients with SSI and UTI (23.53%) cultured the same organism in their urine as in their wound. A cemented arthroplasty was protective when compared to an uncemented implant (OR 0.55 95% CI 0.32 to 0.97; p = 0.037, multivariable logistic regression). Risk factors for SSI are summarized in Table II.
Table II.
Variable | Unadjusted odds ratio (95% CI) | p-value* | Adjusted odds ratio (95% CI) | p-value* |
---|---|---|---|---|
Cemented hemiarthroplasty | 0.57 (0.35 to 0.94) | 0.028 | 0.55 (0.32 to 0.97) | 0.037 |
Days before surgery | 1.29 (1.16 to 1.50) | 0.001 | 1.32 (1.13 to 1.54) | < 0.001 |
Pressure sore | 4.44 (1.34 to 14.72) | 0.015 | 3.49 (1.00 to 12.17) | 0.050 |
Urinary tract infection | 2.71 (1.55 to 4.73) | < 0.001 | 2.83 (1.60 to 5.01) | < 0.001 |
Age, yrs | 1.00 (0.97 to 1.02) | 0.816 | 0.99 (0.99 to 1.02) | 0.508 |
Admission from an institution | 1.24 (0.71 to 2.16) | 0.444 | 1.37 (0.70 to 2.65) | 0.357 |
Female sex | 0.99 (0.58 to 1.67) | 0.957 | 0.96 (0.56 to 1.67) | 0.895 |
Renal disease | 1.11 (0.53 to 2.33) | 0.784 | 0.74 (0.35 to 1.64) | 0.475 |
Diabetes | 1.66 (0.94 to 2.92) | 0.081 | 1.74 (0.97 to 3.12) | 0.063 |
Rheumatoid arhritis | 0.48 (0.065 to 3.45) | 0.462 | 0.63 (0.086 to 4.67) | 0.653 |
Smoker | 1.30 (0.62 to 2.73) | 0.495 | 1.07 (0.47 to 2.46) | 0.865 |
Steroids | 29,551,390.99 (0 to 99,999,999) | 1.00 | 0 (0 to 99,999,999) | 0.996 |
Warfarin | 1.28 (0.51 to 3.20) | 0.601 | 1.31 (0.50 to 3.48) | 0.584 |
Clopidogrel | 0.84 (0.26 to 2.72) | 0.776 | 1.27 (0.39 to 4.15) | 0.694 |
Operation duration, mins | 1.00 (0.99 to 1.01) | 0.51 | 1.00 (0.99 to 1.01) | 0.929 |
Pathological fracture | 1.26 (0.17 to 9.27) | 0.821 | 1.29 (0.17 to 9.99) | 0.807 |
AMT less than 7 | 1.03 (0.63 to 1.67) | 0.913 | 1.29 (0.71 to 2.35) | 0.412 |
-
*
OR calculated using binary logistic regression.
-
AMT, Abbreviated Mental Test; CI, confidence interval.
Management of deep infection
One patient died with a clinically diagnosed deep SSI before a formal debridement was undertaken, leaving 50 patients available for full analysis. In all, 43 patients had a DAIR procedure to treat their SSI; eight of these patients underwent a stem exchange as part of the DAIR.
Seven patients underwent a primary excision arthroplasty. Patients selected by their operating surgeon to undergo an excision arthroplasty were older (mean age 86.14 years (SD 6.07) vs 81.54 years (SD 11.28)), and more likely to have undergone an initial uncemented hemiarthroplasty (OR 6.46, 95% CI 1.10 to 37.92; p = 0.390, binary logistic regression). The details of these two groups is shown in Table III.
Table III.
Variable | DAIR, n = 43, n (%) | Excision arthroplasty, n = 7, n (%) | p-value |
---|---|---|---|
Cemented hemiarthroplasty | 31 (72.01) | 2 (28.57) | 0.024 † |
Age, yrs, mean (SD) | 81.54 (11.28) | 86.14 (6.07) | 0.130* |
Admission from an institution | 9 (20.93) | 3 (43.86) | 0.208† |
ASA grade, mean (SD) | 2.84 (0.58) | 3.25 (0.50) | 0.202* |
Female sex | 29 (67.44) | 5 (71.43) | 0.834† |
Renal disease | 5 (11.63) | 2 (11.63) | 0.231† |
Diabetes | 9 (20.93) | 2 (28.57) | 0.651† |
Rheumatoid arthritis | 1 (2.33) | 0 (0.0) | 0.684† |
Smoker | 6 (13.95) | 0 (0.0) | 0.292† |
Steroids | 0 (0.0) | 0 (0.0) | N/A |
Warfarin | 3 (6.98) | 1 (14.29) | 0.509† |
Clopidogrel | 1 (2.33) | 0 (0.0) | 0.684† |
Urinary tract infection | 10 (23.26) | 1 (14.28) | 0.576† |
Pressure sore | 2 (4.76) | 0 (0.0) | 0.556† |
Pathological fracture | 1 (2.33) | 0 (0.0) | 0.684† |
AMT less than 7 | 14 (32.56) | 4 (57.14) | 0.209† |
Time from index case to infection diagnosis, mean (SD) | 21.89 (27.37) | 24.29 (10.92) | 0.731* |
-
Significant differences are shown in bold.
-
*
Pearson’s independent-samples chi-squared test.
-
†
Students t-test.
-
AMT, Abbreviated Mental Test; DAIR, debridement, antibiotic, and implant retention; SD, standard deviation.
Implant survival
Overall, DAIR with or without stem exchange as an initial strategy for infection clearance had a success rate of 20.93% (nine patients still alive and with a hemiarthroplasty in situ at one year). Only seven patients (16.28%) survived to one year with their original implant in situ (two patients of the nine DAIR successes had undergone a stem exchange). Of the original 43 DAIRs, 15 patients (34.88%) subsequently underwent an excision arthroplasty due to persistent infection after DAIR. Three of these patients (7.3%) were subsequently revised to either a THA (two patients) and cemented hemiarthroplasty (one patient). Overall, 8/43 DAIR patients underwent a stem exchange as part of their treatment, of which six patients (75%) had continuing infection requiring an eventual excision arthroplasty. Stem exchange was not significantly more successful in clearing infection than debridement alone (2/8 (25%) vs 7/35 (20%; p = 0.754, chi-squared test).
No patient who underwent an excision arthroplasty as the first revision surgery underwent re-insertion of an arthroplasty. The mean number of procedures for infection in the excision arthroplasty group was 1.14 (SD 0.380) compared to 1.74 (SD 0.93) in the DAIR group.
Factors influencing success of DAIR
The majority of causative organisms grown from deep tissue samples were gram-positive (77.8% of organisms cultured); 40.5% of infections were caused by a single gram-positive organism (n = 17; 27.8% success rate of DAIR). Isolated gram-negative infections were relatively uncommon (n = 5; 11.9%), but had a 100% failure rate.
Infection with methicillin-resistant Staphylococcus aureus (MRSA), Pseudomonas, or Enterobacter also had unfavourable outcome. Certain gram-positive organisms appeared to be more favourable; Citrobacter and Proteus infections both had cure rates of 100% following DAIR. The causative organisms and resulting success rates of DAIR and excision arthroplasty are shown in Table IV.
Table IV.
Organism | n | Success of DAIR, n (%) | Alive at one year, n (%) |
---|---|---|---|
DAIR | 43 | ||
Gram-positive organisms | |||
Methicillin-sensistive Staphylococcusaureus (MSSA) | 13 | 3 (23.07) | 6 (46.15) |
Methicillin-resistant Staphylococcus aureus (MRSA) | 4 | 0 (0.0) | 2 (50.0) |
Coagulase negative staphylococci | 13 | 5 (38.46) | 7(53.85) |
Streptococcus | 6 | 1 (16.67) | 2 (33.33) |
Citrobacter | 1 | 1 (100) | 1 (100) |
Corynebacterium | 3 | 1 (33.33) | 1 (33.33) |
Proteus | 2 | 2 (100) | 2 (100) |
Diptheroid | 7 | 1 (14.29) | 4 (57.14) |
Enterococcus | 7 | 2 (28.57) | 4 (57.14) |
Clostridium | 1 | 0 (0.0) | 0 (0.0) |
Gram-negative organisms | |||
Pseudomonas | 5 | 0 (0.0) | 2 (40.0) |
Coliform | 7 | 2 (28.57) | 5 (71.42) |
Klebsiella | 1 | 0 (0.0) | 0 (0.0) |
Enterobacter | 4 | 0 (0.0) | 0 (0.0) |
No growth | 2 | 0 (0.0) | 1 (50.0) |
Gram-positive organisms only | 27 | 8 (29.63) | 12 (44.44) |
Gram-positive only, excluding MRSA | 24 | 8 (33.33) | 11 (45.83) |
Gram-negative organisms only | 5 | 0 (0.0) | 2 (40.0) |
Mixed gram-positive and gram-negative | 11 | 2 (18.18) | 6 (54.54) |
Infection with any gram-negative organism (gram-negative or mixed) | 16 | 2 (12.50) | 8 (50.0) |
Excision arthroplasty | |||
MRSA | 2 | N/A | 0 (0.0) |
MSSA | 2 | N/A | 0 (0.0) |
Group B Streptococcus | 1 | N/A | 1 (100) |
Klebsiella | 1 | N/A | 1 (100) |
Cornyebacterium | 1 | N/A | 0 (0.0) |
Proteus | 1 | N/A | 0 (0.0) |
Pseudomonas | 1 | N/A | 0 (0.0) |
-
DAIR, debridement, antibiotics, and implant retention; N/A, not applicable.
Staphylococcus aureus was the most common organism cultured in patients undergoing a primary excision arthroplasty (4/9; 44.44%). MRSA and Pseudomonas had a poor outcome, with 100% mortality at one year despite implant removal.
We were unable to identify a statically significant predictor of DAIR success. No DAIR was successful if performed over 32 days from the index procedure. Analyzed variables are reported in Table V.
Table V.
Variable | Unadjusted odds ratio (95% CI) | p-value* | Adjusted odds ratio (95% CI) | p-value* |
---|---|---|---|---|
Stem exchange | 1.33 (0.22 to 8.08) | 0.750 | 2.04 (0.26 to 16.33) | 0.501 |
Time between index procedure and DAIR, days | 0.97 (0.90 to 1.04) | 0.331 | 0.97 (0.90 to 1.05) | 0.487 |
Cemented hemiarthroplasty | 4.00 (0.44 to 36.15) | 0.217 | 3.62 (0.36 to 36.07) | 0272 |
Not multi-resistant or gram-negative organism | 5.60 (0.63 to 49.95) | 0.123 | 6.16 (0.65 to 58.84) | 0.114 |
-
*
Binary logistic regression.
-
CI, confidence interval.
Mortality
The overall mortality at one year after a deep SSI was 55.87%, compared to 24.9% for patients without infection (p < 0.0001, log rank test). Overall, 21/43 patients (48.84%) were alive at one year after an attempted DAIR compared to 2/7 (28.57%) after a primary excision arthroplasty (p = 0.0081, log rank test). Differences in survivorship of patients with no infection, DAIR and excision arthroplasty over one year following their index procedure are shown in Figure 1.
Fig. 1
Discussion
The most appropriate treatment of an infected hemiarthroplasty remains controversial.17 Overall, success rates for DAIR were lower in this study than those reported after elective hip arthroplasty.3 Success rates in the few small studies on DAIR after hemiarthroplasty range from 22% to 82%.17-19 This wide range of success rates may be due to variations in study design. Kazimoglou et al20 reported a success rate of 41% in 39 patients at one year, but counted death deemed not due to infection as a successful DAIR. The highest success rate (82%) was reported by Mellner et al,18 who also reported a high rate of deep SSI (4.5%). The onset of infection was earlier following the index surgery than in our study, with 26/28 patients treated with DAIR within seven days of the index procedure, whereas the average time to treatment for infection in our series was 22 days. This study also reported on hemiarthroplasty and THA, whereas we report on hemiarthroplasty alone.
Over the last decade, improvements in hip fracture care have led to improved outcomes.21 Disappointingly, outcomes after deep SSI do not appear to have improved over the same time.1,2 We found that deep infection significantly reduced survival at one year, with mortality rates after infection essentially unchanged in our unit since 2004.2 Mortality after an excision arthroplasty was higher than after DAIR; however, the excision arthroplasty patients were older and were more likely to have undergone an initial uncemented hemiarthroplasty, suggesting greater frailty.
We did not collect patient-reported outcomes in this study. Previous studies of deep SSI in THA have shown that patients who retain a functioning hip arthroplasty have higher patient-reported outcome scores.22,23 Following excision arthroplasty, patients report lower health status than after lower limb amputation or myocardial infarction.22
Factors influencing success of DAIR
Several factors, including time from index procedure to onset of infection, have previously been shown to influence success rates of DAIR within elective arthroplasty.24 We were unable to identify statistically significant predictors of a successful DAIR, perhaps partially due to the smaller sized cohort of deep infections available within our dataset. Stem exchange, leaving the cement mantle intact where present, demonstrated a marginally greater success rate compared to debridement and antibiotics alone; this difference was not statistically significant (7/34 (20.59%) vs 2/9 (22.22%); p = 0.915, chi-squared test). Multi-drug resistant organisms and polymicrobial infections have been shown to significantly reduce the rates of successful infection clearance, either by DAIR or two-stage revision.25 We found that success rates of DAIR after hip fracture may be influenced by the causative organism. Patients with certain gram-positive organisms had more favourable success rates of over 60% compared to patients with any gram-negative organism; in these cases, rates of success were around 12%. None of the patients with MRSA or Pseudomonas SSI had an implant at oneyear post-surgery.
Risk factors for SSI
Given the overall poor outcomes after deep infection, prevention of SSI remains a priority in hip fracture care. We identified several potential risk factors for the development of SSI.
Pressure sores offer an entry site for bacteria, with a resulting risk of sepsis and haemataological spread to the new implant.26 UTI has previously been reported as a risk for infection in elective arthroplasty.27 Cemented arthroplasties had a lower risk of infection; antibiotic eluting bone cement, which is standard in our unit for cemented hemiarthroplasty, has been shown to be protective of SSI.28 We hypothesize that delay to theatre may allow patients to be colonized by resistant organisms, or can reflect times when the surgical case intensity is high. By addressing the identified risk factors, we would hope to be able to reduce rates of infection further.
Limitations
We detected differences in the demographics of patients undergoing DAIR and excision arthroplasty. Selection bias in treatment allocation is always possible in a retrospective and non-randomized study. While deep infection after hemiarthroplasty is devastating, the incidence was low in our cohort. The lower number of DAIRs limited the number of variables that could be included within the regression analysis. Some patients may have moved out of our institution’s catchment area during the study period; these patients would be missing from the subsequent analysis if they presented with infection to a different institution. Also, only variables recorded accurately and with sufficient detail within the prospective registry were available for analysis. It is possible that other variables, not analysis, in this study may be significant predictors of infection. Lastly, it could be argued that our criteria for a “success” as an alive patent with a functioning implant at one year was too ambitious. For many hip fracture patients after deep infection, survival in comfort and discharge from hospital may be sufficient. Cause of death was not available for patients within the study. Using a shorter follow-up period to be infection-free would potentially miss recurrent or persistent infection and artificially inflate the success of DAIR, while longer-term follow-up was limited by the already poor long-term survival after infection.29
Recommendations
Our study suggests that DAIR may best be used for patients with a favourable organism and the physiological reserve to tolerate repeat surgeries. As DAIR does not appear to negatively affect mortality when compared to excision arthroplasty, it would seem reasonable to perform as an initial treatment in the presence of suspected deep SSI. Should the patient fail to respond to the initial DAIR, or an unfavourable organism is cultured (gram-negative or multi-drug resistant), then an excision arthroplasty should be performed rather than recurrent washouts or stem exchange. If infection clearance is achieved, reimplantation may be safely performed in select patients. Patients and relatives should be counselled as to the catastrophic effects of PJI after hemiarthroplaty, and the significant risk of the patient ending up with no implant. Unless otherwise contraindicated, cemented arthroplasty should be preferred to reduce rates of SSI. These recommendations are, however, greatly limited by the relatively low sample size and retrospective nature of the analysis in this study.
In conclusion, DAIR has a low chance of success after an infected hip hemiarthroplasty compared to the rates reported in elective practice. The outcome of PJI deep SSI following a hip hemiarthroplasty is poor at one year, regardless whether implant retention is attempted or not. Should the patient fail to respond to the initial DAIR, or an unfavourable organism is cultured, then an excision arthroplasty should be performed rather than recurrent washouts or stem exchange. Deep infection remains an unsolved problem in this vulnerable patient cohort, and avoidance of infection remains key.
References
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Author contributions
S. Craxford: Data curation, Formal analysis, Visualization, Writing – original draft.
B. A. Marson: Formal analysis, Writing – review & editing.
J. Nightingale: Investigation, Formal analysis.
A. Ikram: Investigation, Writing – original draft.
Y. Agrawal: Visualization, Writing – original draft.
D. Deakin: Visualization, Writing – original draft.
B. Ollivere: Visualization, Writing – original draft.
Funding statement
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.
ICMJE COI statement
B. A. Marson declares grants/grants pending for a NIHR doctoral fellowship, which is unrelated to this work.
Open access funding
The authors report that the open access funding for this manuscript was self-funded.
Ethical review statement
Ethical approval was not required for this study.
© 2021 Author(s) et al. This is an open-access article distributed under the terms of the Creative Commons Attribution Non-Commercial No Derivatives (CC BY-NC-ND 4.0) licence, which permits the copying and redistribution of the work only, and provided the original author and source are credited. See https://creativecommons.org/licenses/by-nc-nd/4.0/