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SA Orthopaedic Journal

versão On-line ISSN 2309-8309
versão impressa ISSN 1681-150X

SA orthop. j. vol.18 no.1 Centurion Fev./Mar. 2019

http://dx.doi.org/10.17159/2309-8309/2019/v18n1a5 

HIP

 

Incidence and risk factors for extended post-operative length of stay following primary hip arthroplasty in a South African setting

 

 

Dlamini NFI; Ryan PVII; Moodley YIII

IMBChB(UCT), MMed, FC Orth (SA); Consultant orthopaedic surgeon, Department of Orthopaedics, Prince Mshiyeni Memorial Hospital, Durban; and Department of Orthopaedics, Nelson R Mandela School of Medicine, University of KwaZulu-Natal, Durban, South Africa
IIMBChB(UCT), MMed, FC Orth (SA); Consultant orthopaedic surgeon, Department of Orthopaedics, Inkosi Albert Luthuli Central Hospital, Durban, South Africa
IIIPhD; Research fellow, Department of Anaesthetics, Nelson R Mandela School of Medicine, University of KwaZulu-Natal, Durban, South Africa

Correspondence

 

 


ABSTRACT

BACKGROUND: This study sought to determine the incidence of extended post-operative length of stay (EPLoS) and its associated risk factors in South African primary hip arthroplasty patients
METHODS: This was a retrospective chart review study of 185 adults who underwent primary hip arthroplasty at a quaternary South African hospital. Data related to patient, clinical, and surgical characteristics were collected. Post-operative length of stay was calculated as the time (in days) between the dates of surgery and discharge from hospital. We defined EPLoS as any length of stay >75th percentile obtained for the entire study population. Data were analysed using univariate and multivariate statistical methods
RESULTS: The incidence of EPLoS was 28.1% (95% confidence interval - CI: 22.1-35.0%). Risk factors for EPLoS included: female sex (odds ratio - OR: 4.63, 95% CI: 1.74-12.34; p=0.002), patient's maximum walking distance <100 m (OR: 3.05, 95% CI: 1.05-8.89; p=0.041) and extended duration of surgery (OR: 3.62, 95% CI: 1.31-10.01; p=0.013
CONCLUSION: We provide a report of EPLoS and several associated risk factors in South African primary hip arthroplasty patients
Level of evidence: Level 4

Key words: primary hip arthroplasty, primary hip replacement, South Africa, extended length of stay, risk factors


 

 

Introduction

Increased global life expectancy has been linked to a higher burden of musculoskeletal conditions, including hip fracture and osteoarthritis.1 Untreated musculoskeletal conditions impact quality of life in afflicted patients and also have adverse consequences on healthcare expenditure and resource utilisation.1 These conditions would therefore have public health significance in resource-limited settings. Aside from non-communicable aetiologies, the global HIV epidemic has also been linked to the growing prevalence of orthopaedic disorders.2 Conservative medical therapy might not be effective in a large proportion of patients afflicted with orthopaedic hip conditions. Surgical intervention remains the only viable management option in these patients.3 The effectiveness of primary hip arthroplasty in reversing pain and loss of function associated with orthopaedic hip conditions is well described.3,4 Utilisation of primary hip arthroplasty as a surgical intervention for orthopaedic hip conditions has increased substantially over the past two to three decades, with this procedure now considered among the most common surgical procedures performed worldwide.4

A survey of orthopaedic surgeon members belonging to the South African Orthopaedic Association reported that each member in the country performed up to 43 hip arthroplasties each year.5 In addition, a lack of surgical expertise and other essential resources in surrounding countries has resulted in a number of patients from these countries being referred to South African hospitals for the procedure.6 In response to the increasing demand for primary hip arthroplasty, it is possible that many South African orthopaedic surgery units will in future adopt accelerated post-operative care pathways, in which the length of inpatient stay (and subsequent expenditure and resource utilisation for each patient) following surgery is reduced.7,8 An understanding of which patient, clinical, and surgical characteristics are associated with extended postoperative length of stay (EPLoS) in South African primary hip arthroplasty patients would have important future implications for the development of fast-track or accelerated surgical and recovery protocols implemented at orthopaedic surgery units in the country.

Therefore, the objectives of this study were to:

1. Determine the incidence of EPLoS in a sample of South African primary hip arthroplasty patients

2. Determine which patient, clinical, and surgical characteristics are associated with EPLoS in a sample of South African primary hip arthroplasty patients.

 

Materials and methods

Study design, study setting, and study population

This was a retrospective chart review study involving consecutive adult patients who were admitted for primary hip arthroplasty through a dedicated arthroplasty unit at a quaternary level hospital in KwaZulu-Natal, South Africa, between 23 September 2014 and 28 July 2016. Inclusion/exclusion criteria for this study are presented in Table I. Potential participants were identified from theatre lists during the specified study period.

 

 

Data collection

The medical records of all patients included in this study were reviewed and data related to various patient (demographics), clinical (comorbidities, presenting diagnosis, Thomas test with fixed flexion deformity [FFD], etc.), and surgical characteristics (nature of surgery, anaesthesia, surgical approach, duration of surgery, and peri-operative blood transfusion) were collected using case report forms. We also collected data related to the occurrence of serious peri-operative complications, which we defined as a grade III or above peri-operative complication when using the Clavien-Dindo classification (includes: organ failure, critical care admission, re-operation, and mortality).9 Post-operative length of stay was calculated as the time (days) between the date of a patient's operation and the date that the patient was discharged from hospital.

The study outcome was EPLoS. This was defined as a postoperative length of stay >75th percentile calculated for the entire study population. This definition of EPLoS has been used in similar surgical studies conducted in overseas settings.10,11 Data were transferred from the case report forms to a Microsoft Excel® spreadsheet in preparation for analysis.

Data analysis

The median length of stay for the study population was calculated and is presented with an interquartile range. The incidence of EPLoS in this study was calculated using conventional epidemiological methods.12 The incidence of EPLoS in this study is presented as a percentage with 95% confidence intervals (95% CI). Potential associations between various patient, clinical, and surgical characteristics and EPLoS were investigated using univariate (χ2 test, or Fisher's exact test) and multivariate (binary logistic regression) statistical methods. Results for the univariate statistical analysis are presented as frequencies and percentages. Characteristics with p<0.100 in the univariate analysis were selected for inclusion in the multivariate statistical analysis. This purposeful selection of variables for inclusion in the multivariate analysis was done to obtain the most parsimonious model possible.13 Model fit was assessed using a Hosmer-Lemeshow test. Results for the multivariable statistical analysis are presented as odds ratios (OR) with 95% CI. A p-value of <0.050 was considered to be a statistically significant result. All statistical analyses were performed using the Statistical Package for the Social Sciences (SPSS) version 24.0 (IBM Corp, USA).

 

Results

Derivation of study population and incidence of EPLoS

The derivation of the study population and the incidence of EPLoS in this study is shown in Figure 1. Following the application of our study inclusion and exclusion criteria, our final study population consisted of 185 adult patients who underwent primary hip arthroplasty. The median post-operative length of stay for the study population was 5.0 days (interquartile range: 3.0-7.0 days). The 75th percentile for the study population post-operative length of stay was 7.0 days. A total of 52/185 patients experienced EPLoS following primary hip arthroplasty, with the calculated incidence of EPLoS being 28.1% (95% CI: 22.1-35.0%).

 

 

Distribution of patient, clinical, and surgical characteristics in the study population

The distribution of patient, clinical, and surgical characteristics in the study population is shown in Table II. A total of 43/185 patients were elderly (23.2%). There was a higher proportion of female patients versus male patients in the study population (55.1% versus 44.9%, respectively). With regard to comorbidity, 38.4% (71/185) of the study population were classified as having severe systemic disease (an American Society of Anesthesiologists score of >3). The most prevalent comorbidities in the study population were hypertension (n/N=86/185, 46.5%), obesity (n/N=84/185, 45.4%), and anaemia (n/N=53/185, 28.6%). Osteoarthritis was the most common presenting diagnosis (n/N=80/185, 43.2%), followed by osteonecrosis (n/N=61/185, 33.0%) and other miscellaneous orthopaedic diagnoses (n/N=44/185, 23.8%). The most frequent miscellaneous diagnoses reported were hip dysplasia (11/44 patients 25.0%), fracture (9/44 patients, 20.5%), ankylosis (8/44 patients 18.2%), and rheumatoid arthritis (7/44 patients, 15.9%). Fixed flexion deformity (as per the Thomas test) was established for 138/185 patients (74.6%). Overall, 13.5% of the study population were classified as having severe hip deformation (FFD >30 degrees). A total of 138/185 patients (74.6%) used an assistive device for mobilisation. Pain scores (visual analogue score - VAS) could only be established for 121/185 patients (65.4%). A total of 99/185 patients had a VAS >7 (53.5%). We could only establish maximum walking distance for 58.4% (n/N=108/185) of the study population. A total of 52/185 patients (28.1%) could not walk 100 m or more. The median duration of surgery for the study population was 100.0 minutes (interquartile range: 75.0-125.0 minutes). Urgent/ emergent surgical procedures were rare in the study population (n/N=3/185, 1.6%). Surgery was performed under general anaesthesia in 96/185 patients (51.9%). The standard posterior approach was used in 123/185 procedures (66.5%). Thirty-five patients (18.9%) experienced surgery of extended duration, which we defined as a surgery with a duration >75th percentile calculated for the entire study population. Twenty-six patients in the study population required a peri-operative blood transfusion (14.1%). Serious peri-operative complications were rare (n/N=5/185, 2.7%).

 

Results of the univariate statistical analysis

The results of the univariate statistical analysis are also shown in Table II. The proportions of several characteristics were statistically similar (p>0.050) between patients who experienced EPLoS and patients who did not experience EPLoS. These characteristics included: elderly age (p=0.130), American Society of Anesthesiologists Score (p=0.306), current smoker (p=0.061), cardiovascular disease (p=0.999), chronic obstructive pulmonary disease (p=0.327), HIV (p=0.764), diabetes (p=0.999), anaemia (p=0.970), obesity (p=0.807), hypertension (p=0.056), mobilisation with an assistive device (p=0.937), VAS (p=0.774), urgent/emergent surgery (p=0.560), general anaesthesia (p=0.739), and posterior surgical approach to the hip (p=0.216). The proportions of the remaining characteristics were statistically different (p<0.050) between patients who experienced EPLoS and patients who did not experience EPLoS. These characteristics included: sex (p<0.001), presenting diagnosis (p=0.011), FFD (p<0.011), patient's maximum walking distance (p=0.009), extended duration of surgery (p=0.003), peri-operative blood transfusion (p<0.001), and serious perioperative complications (p=0.023). We were unable to compute statistics for the characteristic 'renal impairment', as we found that no patients in our study population had this characteristic.

Results of the multivariable statistical analysis

The results of the multivariable statistical analysis are shown in Table III. Only nine of the characteristics investigated in the univariate analysis met the criteria of p<0.100 for inclusion in the multivariable analysis. These characteristics were sex, being a current smoker, hypertension, presenting diagnosis, FFD, patient's maximum walking distance, extended duration of surgery, peri-operative blood transfusion, and serious peri-operative complications. Of these characteristics, only three were found to be independently associated with EPLoS. These characteristics were female sex (when compared with males, OR: 4.63, 95% CI: 1.74-12.34; p=0.002), patient's maximum walking distance <100 m (when compared with the reference of walking distance >100 m, OR: 3.05, 95% CI:1.05-8.89; p=0.041), and extended duration of surgery (when compared with surgery duration <75th percentile obtained for the entire study population, OR: 3.62, 95% CI: 1.31-10.01; p=0.013). The result for the Hosmer-Lemeshow test indicated adequate model fit (p>0.050).

 

Discussion

The median post-operative length of stay in our South African study population was much shorter than that reported for British, American, and Pakistani patient populations undergoing primary hip arthroplasty (median of five days in our study population versus seven to eight days in the other primary hip arthroplasty populations).10,14-16 South Africa is severely impacted by high levels of non-communicable disease,17 trauma/injury,18 and HIV infection,19 all of which are associated with the development of musculoskeletal/orthopaedic disease.20-23 This has resulted in a growing demand for hip arthroplasty in the country.6 However there are staffing and economic challenges in running orthopaedic surgical units in the public sector,24 and the availability of beds in these public hospitals might also be a concern.25 In order to cope with the higher demand for hip arthroplasty, some hospitals are beginning to implement fast-track protocols which are aimed at reducing post-operative length of stay while minimising the rate of post-discharge complications in suitable patients who undergo the surgical procedure.26 This might possibly explain the difference in median post-operative length of stay following primary hip arthroplasty between South African and overseas populations.10,14-16 With regard to EPLoS following hip arthroplasty, the literature is scant. However, there is one American study which reported EPLoS in this surgical population.10 In that study, the 75th percentile for the population post-operative length of stay was 14.0 days, which is twice that reported for our study.10 Furthermore, one-third of the American study population experienced EPLoS.10 As with our findings for median post-operative length of stay, the discrepancy in EPLoS between the American study population and our South African study population must be viewed in the context of a growing demand for hip arthroplasty in South Africa and the disproportionate availability of healthcare resources between South African and American settings.27

We found statistically significant univariate associations between several characteristics (including: sex, presenting diagnosis, FFD, patient's maximum walking distance, extended duration of surgery, peri-operative blood transfusion, and serious post-operative complications). These findings are not unique to our study. Other overseas studies have reported univariate statistical associations between these/similar characteristics and post-operative length of stay in hip arthroplasty patients.14,16 We found three characteristics to be independently associated with EPLoS (including: sex, patient's maximum walking distance and extended duration of surgery). Female sex was found to be associated with an almost five-fold increase in the risk of experiencing EPLoS following primary hip arthroplasty. Abbas et al., reported an almost two-fold increase in the risk of EPLoS for women undergoing hip arthroplasty in a Pakistani setting.16 Dall et al., also reported a multivariate statistical association (without describing the magnitude of risk) between female sex and longer post-operative length of stay a British hip arthroplasty population.14 Therefore, our findings for female sex appear, in general, to be in agreement with the published literature. However, the difference in the magnitude of odds ratios for female sex obtained in our study and the study of Abbas et al.16requires further investigation. The characteristics of patient's maximum walking distance have not been specifically investigated as potential risk factors for EPLoS following hip arthroplasty in the published literature. However, these characteristics are components of the pre-operative Harris Hip Score,28 which has been shown by Dall et al.,14to be associated with length of stay following hip arthroplasty. Specifically, these characteristics appear to be associated with mobility and functional status in patients with hip conditions.28 Therefore, our findings highlight the potential importance of pre-operative functional status and ambulation on the post-operative recovery period in South African primary hip arthroplasty patients. Lastly, we found extended duration of surgery to be associated with an almost four-fold higher risk of experiencing EPLoS. This is somewhat in agreement with the British study of Foote et al., who also report extended duration of surgery to be independently associated with a higher risk of EPLoS.15 However, as with the patients' sex, there appears to be a difference in the magnitude of odds ratios for surgery duration between our study and the study of Foote and colleagues.15 Attempts to should be made to reduce the duration of hip arthroplasty in our setting, possibly through the application of benchmarks and optimisation of surgical technique.

The risk factors identified in our study can be incorporated into future risk stratification systems for EPLoS in South African orthopaedic units. Similar risk stratification systems based on identified risk factors for EPLoS following primary hip arthroplasty have been proposed by Abbas et al.,16and Foote et al.15These risk stratification systems are required to be developed and validated for performance in a separate surgical cohort.29 This step is beyond the scope of the dataset used in our study and requires further research.

There were several characteristics which were not found to be associated with EPLoS during the univariate statistical analysis, or following inclusion in the multivariable statistical analysis. There are two explanations for the lack of statistical association between these characteristics and EPLoS in our study. First, it might be possible that these characteristics, while identified as risk factors in overseas settings, are genuinely not associated with EPLoS in South African hip arthroplasty patients. Discordance in clinical risk factors between overseas/South African surgical populations and other post-operative outcomes has been described elsewhere.30 It might be worthwhile to involve overseas collaborators with access to overseas patient data in future research such that valid comparisons of risk factors between our settings can be made. Secondly, it is possible that a larger sample size than 185 patients would be required to investigate the impact of these characteristics on EPLoS. A potential solution to this would be a collaborative study involving as many hospitals which offer orthopaedic surgical services as possible.

Our study had several strengths. Our study is, to the best of our knowledge, the only South African study which specifically investigates EPLoS following primary hip arthroplasty. Another strength of our study is that we included data on HIV infection in our statistical analyses. This is important as the prevalence of HIV is usually much lower in American and British populations,19 and so our study provides important information on the impact of this characteristic in settings with a high burden of HIV infection. The final strength of our study is that while our sample size appeared modest, it still allowed for us to perform a multivariable statistical analysis to determine independent risk factors for EPLoS without any serious violation of statistical rules of thumb.31 Our study also had several limitations. First, as this study was conducted at a single, dedicated arthroplasty unit in a quaternary level hospital with standardised pre- and post-operative protocols in place, it might be argued that our study findings lack generalisability. As for our solution for the challenge related to the lack of statistical association between several characteristics and EPLoS, we recommend that collaborative studies involving hospitals at various levels of service delivery are conducted to determine the generalisability of our study findings. In addition, we were unable to investigate the impact of the Harris Hip Score in our study due to poor documentation of this characteristic in the patient medical records. We did, however, find that components of the Harris Hip Score were statistically associated with EPLoS, and it is therefore possible that the composite Harris Hip Score might also be associated with EPLoS. Prospective research wherein data collection for the Harris Hip Score is standardised is required. Finally, we did not report the impact of EPLoS on healthcare expenditure or post-discharge complications. These outcomes can only be appropriately investigated through the conduct of prospective research studies.

In conclusion, we found several risk factors for EPLoS following primary hip arthroplasty in South African patients. These risk factors included sex, patient's maximum walking distance, and extended duration of surgery. Further research is required to confirm our study findings, as well as address the limitations identified in our study.

Ethics statement

This study was approved by the University of KwaZulu-Natal Biomedical Research Ethics Committee (Protocol: BE526/17). No benefits of any form have been received from a commercial party related directly or indirectly to the subject of this article.

Declarations

The authors declare authorship of this article and that they have followed sound scientific research practice. This research is original and does not transgress plagiarism policies.

Author contributions

This study formed part of the postgraduate medical studies of NFD. NFD conceptualised the research idea, executed the research protocol, and wrote the manuscript. PVR was involved in the conceptualisation of the research idea and provided a critical review of the manuscript. YM was involved in the conceptualisation of the research idea, performed the statistical analysis, and provided a critical review of the manuscript.

ORCID

Diamini NF http://orcid.orq/0000-0003-2154-0199

Ryan PV http://orcid.org/0000-0002-0957-6482

Mood ley Y http://orcid.org/0000-0002-4119-1734

 

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Correspondence:
Dr NF Dlamini
Department of Orthopaedic Surgery, King Edward Hospital
Private BagX02, Congella 4013, South Africa
email: nkanyiso.dlamini@gmail.com; tel: +27723875344

Received: October 2017
Accepted: September 2018
Published: March 2019

 

 

Funding: None
Conflict of interest: All authors declare that there are no conflicts of interest regarding this research.

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