Operative management of acetabulum fractures in the obese patient: challenges and solutions

Introduction

With an incidence of ~3 out of every 100,000 patients per year, acetabular fractures are among the more challenging injuries presented to the orthopedic surgeon.¹ These challenges can be further increased in an obese patient. Presently, at least 35% of American adults aged ≥20 years are obese,² and current trends estimate that by 2030, obesity rates may increase to 51%.³ Additionally, morbid obesity (body mass index [BMI] ≥40) and super-obesity (BMI ≥50) quadrupled and quintupled in prevalence, respectively, between 1986 and 2000.⁴

Obesity reduces life expectancy and is associated with numerous medical and surgical comorbidities.⁵ Obesity increases the rate of perioperative complications regardless of injury, and postoperative mortality and morbidity rates are higher in obese patients.^6–11 Furthermore, obesity is associated with an increased likelihood of wound dehiscence, increased hospital length of stay, and postoperative respiratory complications.^7,8,12

As the rate of obesity in this country continues to rise, the need for well-defined literature guiding the fracture management in this patient population grows. The goal of this review is to identify the challenges that this specific patient population presents to the orthopedic surgeon in terms of patient characteristics, diagnosis, treatment, complications, and cost, with the hope to provide solutions in the management of acetabulum fractures in an obese patient.

Methods

An electronic database search was conducted to evaluate the current MEDLINE, EMBASE, and Ovid electronic databases for articles published before July 2016 relevant to acetabular fracture in the obese patient population. Articles published in languages other than English were excluded. The initial search strings utilized the Boolean “obes*” AND “acetabul*” AND “fract*”, which returned a total of 49 articles. These articles were then cross-referenced, which provided 39 additional sources. After reviewing all 88 articles, it was determined that only 29 studies were of high importance to our topic. High importance was defined as studies that provided sufficient information on surgical management, complications, and outcomes of the treatment of acetabular fractures in obese patient population. We defined obesity based on a BMI ≥30, which is calculated by dividing a patient’s weight in kilograms by the square of their height in meters (kg/m²).

Results

Patient characteristics

Acetabular fractures generally have a bimodal distribution with respect to age. The first peak represents fractures in young adults that result from high-energy trauma, while the second peak is in the elderly population who sustain fractures from low-energy mechanisms.¹³ Historically, these injuries have occurred more frequently in males than females, but this trend is slowly changing as females are representing a more balanced share of acetabular fractures.^1,13

Recently published data show that, in the setting of rising national obesity rates, the age-adjusted prevalence of obesity is 5.4% higher in women (40.4%) than men (35.0%), and for patients with BMI ≥40, the rate in women (9.9%) is almost double that in men (5.5%).¹⁴ On a whole, these trends suggest that orthopedic surgeons could manage more cases of acetabular fracture in the elderly, the obese, and female populations in future years.

A study by Karunakar et al showed the prevalence of obesity (BMI ≥30) and morbid obesity (BMI ≥40) in acetabular fracture patients treated with open reduction and internal fixation (ORIF) at a level-1 trauma center to be 44% and 12%, respectively (N=169 patients).¹¹ Another more recent study demonstrated that the obesity (BMI ≥30) and morbid obesity (BMI ≥40) rates in displaced acetabular fracture patients treated with ORIF were 38% and 9%, respectively (N=242 patients).¹⁵

Diagnosis

Radiographic assessment of the acetabulum can also be more challenging in obese populations. Larger soft tissue envelops increase X-ray scattering and decrease penetration, leading to low image contrast.¹⁶ To combat this, Bucky grids can be employed to reduce scatter, and increasing kV peak and mA improves X-ray penetration and hastens development speed, which boost image quality.¹⁶ All of these methods that provide better visualization in obese patients have the effect of significantly increasing the effective radiation dose to the patient.¹⁷

More practical barriers can also be encountered when imaging the obese. Standard X-ray cassette sizes may not be large enough to obtain a full view of the pelvis on a single image. Patient obesity also makes positioning to obtain proper Judet views more difficult.¹⁸ Intraoperative pelvic imaging using C arm fluoroscopy can be very difficult in patients with a large pannus, particularly with inlet views. Bowel gas, intravenous contrast, and parenteral contrast may also impede traditional imaging techniques. Also, some computed tomography (CT) scanners have girth limits and weight restrictions of 200 kg.⁶ If patients exceed those limits, imaging may require transfer to another medical facility with extra-large scanners. Hence, veterinary schools or zoos could be utilized.¹⁹

While conventional radiographs are usually sufficient to characterize acetabular fracture type, CT imaging can capture the degree of articular comminution and impaction often present in these injuries.^20,21 As described by O’Toole et al, CT scans may provide higher accuracy when evaluating these fractures and with higher interobserver reliability.²² Further, CT scans eliminate the adverse imaging effects of adipose tissue and bowel, and they are as useful as plain radiographs for classifying acetabular fractures in obese patients.²³

Complications

In a seminal investigation conducted in 2003, Mears et al published a retrospective study about indicators of outcome for 411 consecutive, displaced acetabular fractures managed operatively.¹⁰ Of the 42 morbidly obese patients, 22 (53%) had fair or poor clinical results as determined by Harris hip score, which was significantly greater than the 97 other fair or poor clinical results out of 369 (26%) nonmorbidly obese population in the study (P<0.001).¹⁰ Also, all of the 10 deep, intra-articular wound infections occurred in morbidly obese patients subjected to extensile exposures and, in a similar way, all 13 of the Brooker Grade III and IV heterotopic bone ossification occurrences were in morbidly obese patients.¹⁰

Porter et al conducted a retrospective study of 41 morbidly obese (BMI ≥40) and 394 non-morbidly obese (BMI <40) patients who had operatively repaired acetabular fractures.¹² Postoperative complications and other variables such as intraoperative blood loss, operative time, and positioning time were assessed in the two groups.¹² The morbidly obese group required longer average positioning time, statistically significantly greater operative time, and longer hospital lengths of stay than the non-morbidly obese group.¹² Additionally, there were notably more total complications in the morbidly obese population than in the non-morbidly obese group, and the relative risk of complication in the morbidly obese group was 2.6 times that of the non-morbidly obese.¹² A significant difference was also appreciated in the development of wound healing complications. Morbidly obese patients were more likely to have wound healing complications, with the majority requiring operative debridement and irrigation of their wounds.¹² Furthermore, the morbidly obese group experienced a higher percentage of deep vein thrombosis (DVT), pulmonary embolism, sciatic or femoral nerve palsy, implant or fixation failure, symptomatic heterotopic ossification (HO), and death relative to the non-morbidly obese group; however, as these outcomes were individually rarer events, statistical significance was not observed.¹²

When BMI, measured as a continuous variable, was examined as a predictor of complications after ORIF for acetabular fracture, a significant relationship was found with DVT, wound infection, and surgical blood loss.¹¹ Further, the odds ratio for DVT was 2.6 times greater in obese than normal weight patients, and the odds ratio for wound infection was 5 times larger for morbidly obese patients.¹¹

A retrospective analysis of 244 high-energy acetabular and pelvic fracture patients supported previous studies showing longer hospitalizations and higher complication rates in the morbidly obese patient population compared to nonobese patients.²⁴ Obesity was demonstrated to be a significant risk factor for early complication in both the operatively and nonoperatively treated acetabular fracture groups; however, the sample size for this study was not large enough to show significance for any specific complication.²⁴ Risk was also shown to be scaled to BMI, with morbidly obese patients faring even worse than the obese group.²⁴

A strong connection exists between surgical wound infections and obesity. In a retrospective analysis of risk factors of surgical site infection (SSI) after ORIF of acetabular fracture involving 326 patients, BMI was found to have a highly significant association with SSI.²⁵ A 2015 Chinese study of similar size and methodology found the same result.²⁶ An early study of 131 displaced acetabular fractures treated with ORIF found that four of the seven major wound issues occurred in morbidly obese patients (five obese patients total), suggesting a link between SSI and obesity.²⁷ Another study that investigated risk factors for the development of deep postoperative wound infection following ORIF of acetabular fractures showed a significantly higher rate of obesity in the infected versus noninfected groups.²⁸

In addition to SSI, obese patients experience other unique surgical site complications. A study by Lawyer et al demonstrated that morbidly obese patients are more likely to develop post-traumatic osteoarthritis following acetabular fixation.²⁹ Twenty-six out of 38 morbidly obese patients (68%) developed post-traumatic arthritis out of a series of 299 acetabular fixations.²⁹ A retrospective study comparing the incidence of HO after operative treatment of acetabular fracture in morbidly obese patients (BMI >40) compared to those patients with a BMI ≤40 showed that only 18% (68/374) of nonobese patients developed HO, while 47% (21/45) of morbidly obese patients developed HO.³⁰

Another study also retrospectively examined morbidly obese (BMI ≥35) and non-morbidly obese (BMI <35) patients with traumatic acetabular fractures.³¹ It was reported that morbidly obese patients required longer positioning and operative times than non-morbidly obese patients.³¹ However, the study did not show worse perioperative outcomes in the morbidly obese group.³¹ The lack of statistically significant differences in perioperative outcomes may be a result of limited sample size, because the morbidly obese group consisted of only 20 patients.³¹

The overarching theme in the literature is that obese patients have worse complications following surgical management of acetabular fracture, compared to nonobese patients. Broadly, obese patients undergoing ORIF of acetabular fractures have worse clinical results, as given by Harris hip scores,¹⁰ and experience higher postoperative complication rates.^11,12,24 SSI is a particularly common complication in this population.^{10–12,25–28} Other specific perioperative complications seen more frequently in this population are increased intraoperative blood loss, higher rate of DVT occurrence, and increased hospital length of stay.^11,12,24 Several studies have also noted increased incidence of post-traumatic osteoarthritis and HO in the obese population.^10,29,30

Costs and other considerations

Obesity is becoming an increasingly important factor in the cost of health care. In the USA, almost 150 billion dollars per year is attributable to obesity-related expenditures in health care, and obese adults have 36% higher annual medical expenditures than their normal-weight peers.^3,32,33 A higher incidence of comorbidities, including diabetes mellitus, stroke, hypertension, coronary artery disease, many cancers, and respiratory disorders, is present in obese adults.⁷

Complications from both medical comorbidities and those complications investigated in detail in the previous section can affect the health experience of obese adults receiving surgical treatment for acetabular fracture. As medical management of adverse events incurs costs, it can be anticipated that cost of care would be higher in a patient population that experiences more complications. Of the specific complications discussed in the prior section, increased hospital length of stay is likely to have direct impact on cost of care.^12,24 SSIs and delayed wound healing are major complications of ORIF of acetabular fracture in the obese.¹¹ The burden of costs associated with treatment of these complications is significant. Prolonged hospitalization, return to the operating room, and long-term antibiotics could drive cost upward. Other indirect contributors to increased cost might be the initial and subsequent management of DVT, post-traumatic arthritis, and HO, which present more frequently in obese patients.^10,29,30

Managing obese patients requires more physical resources as well. Successful surgery often relies on additional assistants to aid in soft tissue retraction. Depending on their level of obesity, patients may require larger scanners, special operating tables, the rigging of two tables together, and special surgical equipment such as retractors and guides in obese sizes.

Perioperative issues

Treatment

The approach and principles to surgical management of fractures of the acetabulum in patients who are obese are the same as those of nonobese. Appropriate fracture reduction, articular surface congruity, and stability must be achieved.

Obesity is an independent risk factor for cardiovascular disease, which increases the risk of perioperative complications.^34–36 Perioperative resuscitation of morbidly obese patients is of crucial importance. Patients undergoing fixation of acetabular fractures frequently endure significant amounts of blood loss. Patients who are morbidly obese have increased cardiac outputs proportional to their increased size. Large blood loss associated with preexisting increased cardiac output can overload the heart and increase the mortality risk for the patient.^37–39

In addition to cardiac risks, obese patients have significant pulmonary morbidity associated with surgery. Obese patients have a significant difficulty ventilating, especially when under anesthesia, because of their increased chest wall size, weak muscles of respiration, and decreased lung compliance.^35,40,41 Their size puts them at increased risk for pneumonitis, atelectasis, and aspiration pneumonia.

Obesity increases the risk for developing insulin resistance and type two diabetes.⁴² Complications and fracture outcomes are worse in diabetic patients compared with normoglycemic individuals, and hyperglycemia in the perioperative period, specifically, has been shown to raise surgical complication risk.^43,44

Surgical approach and patient positioning are most commonly determined by fracture pattern. It is important to recognize that positions which restrict chest and abdominal motion can compromise ventilation and are poorly tolerated by obese patients.¹⁸ The supine and prone positions can result in compression of the vena cava and the aorta as well as compression of the diaphragm, making ventilation more difficult.³⁵ The lateral decubitus is best tolerated by obese patients, because the weight of the panniculus is off the abdomen, allowing for greater diaphragmatic excursion. The lateral position might also prove beneficial at the surgical site as gravity pulls the excess soft tissues away improving access to the acetabulum; however, this position can pose a problem when attempting reduction, because of the medialization of the femoral head due to the weight of the leg.^35,45

There has been an overall increase in the incidence of total hip arthroplasty as a treatment modality for patients with acetabular fractures.^46,47 Current literature demonstrates reasonable functional outcomes in elderly osteoporotic acetabular fractures.⁴⁸ There is a paucity of literature demonstrating outcomes of this treatment modality in obese patients.

Despite the challenges of operating in a deeper hole, no difference has been found in the ability to achieve adequate reduction between those who are of normal weight and those who are morbidly obese.¹⁸ Porter et al investigated obese (BMI ≥30) and nonobese patients (BMI <30) treated with ORIF for displaced acetabular fracture who were evaluated for reduction quality by radiograph and CT.¹⁵ Importantly, their study showed no statistically significant difference in reduction quality between either the obese group (93 patients) and the nonobese group (149 patients) or the morbidly obese group (BMI ≥40; 21 patients) and the non-morbidly obese patients (BMI <40; 221 patients) based on BMI.¹⁵ It is important to note that to achieve exposure and reduction, alternative retractors and reduction clamps might be necessary.

Discussion

Obesity is a complex disease that causes significant pathophysiologic and anatomic changes to the patient. These changes can be seen across a spectrum of patients, and it is therefore important that obesity is clearly defined. All of the literature currently reviewed defines obesity in terms of BMI. Within this definition, BMI is discussed as a continuous variable, a categorical variable (overweight, obese, morbidly obese), and a binary variable. Category cutoffs are not always assigned in a uniform way. In addition, BMI does not account patients with increased muscle to fat ratios, which mathematically give them greater BMIs that may incorrectly assign them to the obese category.⁴⁹ Given the imperfect definition of obesity using BMI, the question arises as to what is the most clinically meaningful way to define obesity.

The observation of a scaling effect of BMI suggests that a binary definition might not be the most effective. Karunakar et al found that higher BMI confers greater risk of complications and adverse outcome for obese patients undergoing ORIF for acetabular fracture. They showed a significant direct relationship of increased estimated blood loss, SSI, and DVT occurrence with higher BMI measured as a continuous variable.¹¹ Other studies that used categorical definitions of obesity reported similar findings in which obese patients do worse than healthy weight patients but not as poorly as morbidly obese patients.²⁴ This demonstrates that continuous and categorical BMI data show an important trend that may seem intuitive; the higher the BMI is above a threshold denoting obesity, the worse is the surgical risk and the outcome profile.

It is well established that obese trauma patients may have elevated mortality and morbidity rates.^9,50–52 Obese patients experience an increase in infection rates and overall complication rates. Obese patients have a higher probability of requiring mechanical ventilation, experiencing multisystem organ failure, wound complications, longer length of stay in the intensive care unit, and increased perioperative and postoperative complications.^{8,10–12,24–30,52–55} In addition to increased complication rates, obese patients undergoing ORIF of acetabular fractures may have worse postoperative functional results and clinical outcomes.¹⁰

Often, studies of perioperative complications in this patient population are not powered to examine topics far beyond total complication rate, such as pulmonary embolism and sciatic or femoral nerve palsy. A meta-analysis could be a helpful technique to examine these less-common outcomes. Areas in which conflicting results exist, such as obesity’s effect on operative time, positioning, and blood loss, might be made clearer through meta-analysis.

Knowledge of the increased risks facing obese patients undergoing ORIF of an acetabular fracture is important, but the lack of experimental studies on this population leaves surgeons without strong guidance to mitigate those risks. Further experimental research can help surgeons better manage the expected complications.

As obesity continues to rise in the USA, we can only expect to see more obese patients requiring surgical treatment of acetabular fractures. While acetabular fractures resulting from high-energy mechanisms are far more common in younger males, the trend is slowly shifting to include more elderly, more female, and more obese patients. Diagnostic imaging of acetabular fractures can be more challenging in the morbidly obese patients, even with the use of CT as scanners have weight and size limits. When considering surgical technique, patient positioning and surgical approach should also be determined by fracture pattern, although patient obesity may present difficulties with ventilation, resuscitation, and decubitus ulcers. Last, while it is understood that obesity lays a greater financial burden on health care in the USA, it does not change reimbursement for treating morbidly obese patients undergoing surgical fixation of acetabular fractures compared to normal-weight patients. In addition, the use of the Current Procedural Terminology Modifier 22 code has not been shown to change mean reimbursement for the morbidly obese patients surgically treated for acetabular fracture.²⁷

Conclusion

Obese patients represent a unique set of challenges compared with their nonobese counterparts. The orthopedic community should be aware of this in light of the projected rise in American obesity rates. In the future, the need for studies examining practical ways in which the complication profile can be decreased in this population is vital.

Acknowledgment

This manuscript submitted represents original work and has not been previously published or simultaneously submitted elsewhere for publication.

Author contributions

All authors contributed toward data analysis, drafting and revising the paper and agree to be accountable for all aspects of the work.

Disclosure

All authors have provided full disclosure regarding any relevant relationships, financial, and otherwise. All authors report no conflicts of interest in this work.

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