Introduction

Psychological stress is a normal human emotion associated with any disease. Most individuals confronting a diagnosis of a new disease are able to understand, accept, and move forward. Their ability to do this requires personal inner resources, as well as the support and understanding of their physicians, families, friends, and society. Musculoskeletal injuries often create a gamut of anxiety and fears related to future function and ability to remain active in everyday life. Among the many concerns are disabilities secondary to loss of a limb and unrepairable musculoskeletal injury, disfigurement secondary to the musculoskeletal injury, distress over finances and the ability to return to work, concerns about sexual function, and the ability to return to recreational activities. Patients frequently recover from the musculoskeletal injury uneventfully, but may never recover from the psychological comorbidity. Clinicians and researchers have considered psychological and physical injuries as distinct entities, but there is considerable evidence, both from military and civilian populations, that recovery from physical injuries is dramatically and adversely influenced by the presence of a variety of psychological and social comorbidities including depression, posttraumatic stress disorder (PTSD), or other psychiatric conditions.

It has become increasingly clear that as orthopaedic surgeons we must find a way to address the psychosocial needs of the patient and family so that we can do a better job of preventing a permanent disability and returning an individual to a fully functional member of society. Learning to actively seek out the concerns of our patients and families and validating and normalizing the common emotions associated with musculoskeletal injury creates a healthier psychological and social environment to assist recovery. Levin describes his daughter’s fear of being able to ski again after major musculoskeletal trauma. The fear, which was evident in his daughter’s mood, was only identified by inquiring why she appeared concerned. She expressed a fear that she would never be able to ski again and her mood immediately improved when it was predicted that she would definitely be able to ski. Active involvement of a patient’s family and friends during and after the hospitalization fills in the imperative psychosocial support that can only be supplied by an individual’s “loved ones,” and the orthopaedic surgeon should both encourage this involvement and guide the family in how they can be supportive.

The orthopaedic surgeon needs to be aware of numerous psychological and social sequelae associated with musculo­skeletal injury, be able to recognize the symptoms and identify patients and family members in need of help from a professional mental health provider. This chapter will review our present understanding of the psychosocial comorbidities that are associated with musculoskeletal trauma and how these disorders can prevent a successful functional recovery from trauma. We will review the present state of our understanding of these common psychological comorbidities and strategies to treat these conditions, with particular attention paid to the role of the orthopaedic surgeon.

Biomedical Versus Biopsychosocial Model of Medicine

The biomedical model of disease is based on a generally accepted belief among both patients and physicians that symptomatology (pain, general malaise, fever, etc.) is related to an identifiable chemical, physiologic, or structural abnormality that may or may not be correctable. Initially, when a patient presents with acute orthopaedic trauma, this is a relatively straightforward exercise. The patient has a grade IIIB open tibia fracture and we are going to “cure” him or her by placing an intramedullary rod in his or her tibia and performing a gastrocnemius rotation flap and a split-thickness skin graft (STSG). Unfortunately, we have learned from the Lower Extremity Assessment Project (LEAP) and other studies, that individuals with seemingly similar musculoskeletal injuries can have very disparate recoveries. We see the potential for disparate recovery among individuals with both severe as well as less severe injuries.

This observed dichotomy of successful treatment of an individual’s disease (fracture) and recovery led Engel to the introduction of the biopsychosocial model and practice of medicine. Engel believed that the biomedical model failed to recognize each patient’s individuality and humanity. He observed that a patient’s personality (individuality) along with the patient’s social support structure dramatically affected recovery. We frequently discuss this philosophy when we acknowledge that the practice of medicine is “art not science.” Clearly, science and scientific discovery comprise a major component in our dramatic successes in caring for the multiply injured patient. Despite this success, the failure to recognize human emotion and individuality can have a devastating effect on a person’s recovery.

In the discussion that follows, we will focus on posttraumatic stress and depression, two common conditions that are associated with the aftermath of physical trauma. It is important to keep in mind, however, that most patients will not be diagnosed with either of these conditions, even in the face of significant physical injuries. However, studies have shown that even subclinical symptoms of emotional stress and anxiety, if not adequately addressed, can impact recovery. We will also review our rapidly expanding understanding of both mild traumatic brain injury (mTBI) and more extensive traumatic brain injury (TBI), which often accompany skeletal injury, especially in the military. It is important for the orthopaedic surgeon to understand how TBI can impact the functional recovery of their patients.

Anxiety Disorders and Posttraumatic Stress

Acute anxiety symptoms are common following a physical injury and acute stress disorder (ASD) is among the first forms of psychological pathology diagnosable postinjury. It is characterized by a sense of numbing or detachment, restlessness, anxiety, irritability, problems focusing or concentrating, flashbacks, and sleep disturbance. ASD is typically considered a short-term response to injury, with symptoms lasting between 2 and 30 days. A recent review of the literature found that signs and symptoms of ASD occurred in 23% to 45% of patents following physical trauma.

The anxiety disorder spectrum includes generalized anxiety disorder (GAD), panic disorder with and without agoraphobia, PTSD, obsessive-compulsive disorder (OCD), social anxiety disorder, and specific phobias. Of these, GAD, panic disorder, and PTSD are most likely to be related to physical injury. Overall, anxiety disorders are perhaps even more common than depression, and total direct and indirect costs are similar to those associated with depression.

Traumatic Brain Injury and Posttraumatic Stress Disorder

Many skeletal trauma patients also sustain a concomitant injury to the brain, although precise rates of co-occurrence are largely unknown. TBI can range from severe brain injuries with prolonged coma to a mild injury with no loss of consciousness and transient dazed feeling or confusion in the aftermath of a blow to the head. Differentiation of TBI severity remains a matter of considerable debate, but the DoD considers mTBI to include those with no more than 30 minutes loss of consciousness (LOC), moderate TBI including those with more than 30 minutes LOC but no more than 24 hours, and severe TBI limited to those with more than 24 hours LOC. Some reports claim more than 280,000 service members have experienced TBI in Iraq or Afghanistan, at least 80% of which are believed to be mild. TBI is frequently labeled the “signature injury” of Operation Iraqi Freedom (OIF) and Operation Enduring Freedom (OEF). The clinical presentations of mTBI and PTSD are often indistinguishable from each other, featuring impaired sleep, decreased concentration, and other symptoms. There is also evidence that these two disorders have some shared pathophysiology. The frequent co-occurrence of mTBI and PTSD, as well as the overlap in symptoms, has resulted in a growing controversy regarding the relationship between the two disorders and the implications for diagnosis and treatment, especially among veterans returning from OEF and OIF. More research is clearly needed to better understand how mTBI impacts recovery from PTSD and how mTBI might influence the response to various therapies for PTSD.

A self-completed mail survey of 2235 U.S. military personnel returning from Iraq and Afghanistan reported that 12% had a history consistent with mTBI, while 11% were positive for PTSD. Even when overlapping symptoms were removed from the PTSD score, PTSD was more closely related to residual TBI symptoms than anything else. A similar pattern is found in survivors of MVCs, indicating that postconcussive symptoms of mTBI may be mediated by the interaction of neurologic and psychological factors. Another study of MVC-related TBI found that 14% met criteria for ASD in the immediate aftermath of the TBI, and most of them went on to develop chronic PTSD, suggesting it was the psychological rather than physical impact that led to chronic symptoms. Mild TBI spectrum is particularly difficult to define, as some of the persistent symptoms that have been attributed to mTBI, including headaches, dizziness, memory problems, irritability, and sleep problems, are often reported by those with PTSD and other psychological conditions, and those with persistent symptoms after TBI usually seem to meet criteria for a mood or anxiety disorder.

The diagnosis of mTBI is a clinical diagnosis that should be made by a neurologist or medical practitioner experienced with TBI. Evaluation should include a detailed history, physical and neurologic examination and, most importantly, an assessment of cognitive function. The decision to obtain neuroimaging is based on the level of suspicion of skull fracture or intracranial hemorrhage. Clinically available neuroimaging (computed tomography [CT] or magnetic resonance imaging [MRI]) is not adequate to rule out mTBI, which is a clinical diagnosis. If a patient has persistent altered mental status, LOC, abnormal Glasgow Coma Scale (GCS) score, focal neurologic deficit(s), or is clinically deteriorating, then neuroimaging should be obtained.

There is serious concern that reliance on self-reporting of symptoms to establish a diagnosis of mTBI is problematic and thus unreliable. This is both expected and obvious. After all, by definition, these patients are brain injured with alteration of consciousness and memory dysfunction. This is especially true of patients who suffer other severe injuries such as concomitant skeletal trauma. A recent report reviewed the reliability of mTBI diagnosis based on self-reported history of aberration of consciousness in patients suffering complex injuries requiring medical evacuation from the war theater. Patients diagnosed with mTBI had normal neuroimaging, higher Injury Severity Scale (ISS) scores, and longer lengths of stay than those without mTBI. Patients with higher ISS scores and longer lengths of stay are more likely at the time of injury to require pain medication and suffer from hypoxia, hypotension, metabolic derangement, and other conditions that could affect awareness and consciousness. As these disorders can alter consciousness in the absence of TBI, their impact on the diagnostic criteria in patients with severe injuries, especially extremity trauma, cannot be ruled out, which renders the TBI diagnosis unreliable. The paradoxical finding that further supports this conclusion is that patients who reported LOC actually had a lower incidence of abnormalities on neuroimaging.

Findings from studies conducted at Walter Reed National Military Medical Center, have led to similar conclusions. In these investigations, self-report of feeling dazed or confused at the time of injury captures large numbers of individuals who experience PTSD and depression related to blast exposure regardless of whether there is any physical injury or PTSD. This is true also in civilian clinical practice. A study of hospitalized civilian trauma victims that compared 90 patients initially diagnosed with mTBI to 85 non–brain-injured trauma patients found identical rates of postconcussional syndrome (PCS) in both groups. These results suggest no relationship between the diagnosis of mTBI and subsequent PCS symptomatology; moreover, the strongest predictor of PCS was in fact a prior mood or anxiety disorder, with an odds ratio of 5.76.

Although many patients will recover fully following mTBI, some may develop postconcussional disorder (PCD) or PCS. These have persistent symptoms analogous to psychological disorders. PCD was initially codified in the Diagnostic and Statistical Manual of Mental Disorders, Fourth Edition (DSM-IV) as an area requiring further research, with insufficient data to fully support it as a diagnostic entity. PCD criteria require the history of a head trauma, followed by the onset of at least three of the following symptoms, which were not present prior to the trauma and have persisted at least 3 months: fatigue, headache, sleep disturbance, dizziness, irritability, anxiety or depression, personality changes, or apathy. By comparison, the World Health Organization’s (WHO) International Classification of Diseases, Tenth Edition (ICD-10) includes criteria for PCS that are less restrictive, only requiring a history of TBI and three or more of the following eight symptoms: (1) headache, (2) dizziness, (3) fatigue, (4) irritability, (5) insomnia, (6) difficulty with concentration, (7) memory problems, and (8) intolerance of stress, emotion, or alcohol. Because PCD criteria require that the head trauma cause significant cerebral concussion, along with quantifiable impairment in memory or attention, it is not surprising that a study directly comparing the two sets of criteria in mTBI found that the ICD-10 criteria were met three times more frequently. However, neither set of criteria is ready for clinical use without further research. In fact, WHO acknowledges in the description of PCS that

These symptoms may be accompanied by feelings of depression or anxiety, resulting from some loss of self-esteem and fear of permanent brain damage. Such feelings enhance the original symptoms and a vicious circle results. Some patients become hypochondriacal, embark on a search for diagnosis and cure, and may adopt a permanent sick role. The etiology of these symptoms is not always clear, and both organic and psychological factors have been proposed to account for them. The nosological status of this condition is thus somewhat uncertain. There is little doubt, however, that this syndrome is common and distressing to the patient. (p. 67)

Perhaps as a result, most researchers continue to simply refer to the overall, albeit ill-defined, category of TBI, rather than using either PCS or PCD.

As the diagnosis of mTBI based on self-report is problematic, there is a broad effort to employ point-of-care screening tools. For these to be effective, it must first be recognized that most TBI patients are typically unaware that they are injured and thus do not seek medical attention. For this reason, it is incumbent on colleagues, leaders, coaches, and sideline officials to have heightened sensitivity that an individual may be at risk of having suffered an mTBI or concussion and to then institute screening, sometimes in the face of protestations by the victim that he or she is uninjured. There are a number of available point-of-injury clinical screening tools, such as the Standardized Assessment of Concussion (SAC) and Sports Concussion Assessment Tool, version 3 (SCAT3). The military uses the Defense and Veterans Brain Injury Center’s (DVBIC) Military Acute Concussion Evaluation (MACE). Embedded in the MACE is the SAC. The MACE collects history and symptoms and uses the SAC to test four cognitive domains: orientation, immediate recall, concentration, and memory. By regulation through the DoD Directive-Type Memorandum (DTM) 09-033, which is a general order that affects all service members, the MACE is administered to any service member to be at risk of having suffered an mTBI. “At risk” is defined as involvement in a vehicle blast event, collision, or rollover, presence within 50 meters of a blast (inside or outside of a vehicle), a direct blow to the head, or witnessed LOC. If screening is positive, the victim is referred to an advanced medical provider for further evaluation and diagnosis.

Moderate to severe TBI is a life-threatening medical condition. Point-of-injury care is focused on the “ABCs” of airway, breathing, and circulation. A GCS score determination should be made. In the field, care focuses on maintaining oxygen saturation higher than 92%, partial pressure of oxygen (PO ₂ ) higher than 60 mm Hg, partial pressure of carbon dioxide (PCO ₂ ) at 40 mm Hg, and systolic blood pressure higher than 90 mm Hg. Hyperventilation is reserved for those patients who are exhibiting clinical signs of cerebral herniation. Rapid transport to the nearest level 1 trauma center with neurosurgical and neurology critical care is essential. There, care is primarily dictated by neurology specialists if there is isolated TBI or with the general trauma surgery service if there are also complex injuries, including skeletal.

There is an elevated risk of developing depression or other psychiatric disorders among moderate to severe TBI survivors similar to that of other serious medical conditions, such as stroke or myocardial infarction. Several studies demonstrate that at least one-quarter to one-half of those with TBI have major depression. However, moderate to severe TBI may, at least initially, provide some “protection” against the development of PTSD by obscuring the memory of the traumatic event. Further evaluation is necessary to better delineate the relationship between the severity of TBI and the risk of PTSD. In addition, it is important to emphasize the need for close attention to, and repeated formal assessment for, the potential evolution of PTSD symptoms as rehabilitation progresses and memory improves in individuals with moderate to severe TBI. A combination of serial neuropsychological testing, along with the use of validated instruments such as CAPS for PTSD, and Beck Depression Inventory or PHQ for depression, is advisable to best sort out improvement in TBI and potential onset of psychological disorders.

TBI and PTSD commonly occur together. Explosive blast patients who experience significant persistent and recalcitrant symptoms should have a thorough evaluation for PTSD and other psychological sequelae. This may be particularly beneficial to the individual patient, because there are specific treatments for PTSD, depression, and related conditions. Hoge and colleagues identified a significant association between mTBI and psychiatric symptoms, including PTSD in more than 40% of those who had LOC. These investigators noted that the high rates of physical symptoms reported by soldiers could be attributed to PTSD and depression. When these conditions were included in the analyses, there was no direct relationship between mTBI and physical health problems except for headache. It should be noted that the diagnosis for mTBI in this study was based on self-reporting of alteration of consciousness.

Magnetic resonance spectroscopy (MRS) may be better than traditional MRI for identifying mTBI and differentiating it from PTSD. A study by Hetherington and colleagues of veterans exposed to explosive blast and suffering persistent memory impairment associated with mTBI revealed decreased N-acetylaspartate (NAA)/choline (Ch) and NAA/creatinine (Cr) ratios in the anterior hippocampus when compared to patients exposed to blast but did not have these impairments. The hippocampus in affected TBI patients was also reduced in size. When compared to patients with PTSD, TBI patients had anterior hippocampus metabolic ratios that were significantly lower. PTSD patients exposed to blast had no difference in their anterior hippocampus NAA : Ch and NAA : Cr ratios when compared to blast-exposed patients who did not have PTSD. The metabolic ratios in the anterior hippocampus were also not different between blast patients with PTSD and PTSD patients who had no blast exposure. Furthermore, these metabolic ratios did not vary with patients diagnosed with depression or anxiety.

Proper clinical management for mTBI begins with immediately removing the victim from further play or activity. This is to avoid reinjury before the brain has adequately recovered. An injury during the vulnerable period results in further compromised autoregulation of cerebral blood flow, rapid development of cerebral edema, intracranial hypertension (elevated intracranial pressure), and neurologic deterioration to coma and, possibly, death.

Mild TBI treatment begins by allowing the patient to rest with minimal cognitive burden. Symptoms are managed using evidence-based clinical practice guidelines. Unfortunately, there is presently no clinically available pharmacologic agent that will facilitate or hasten the brain’s recovery from TBI.

Return to work and type of work is guided by clinical improvement. The DoD DTM 09-033 and the American Academy of Neurology’s 2013 sports concussion guidelines each recommend that patients be prescribed rest without exposure to excess cognitive stimulation. Both physical and cognitive activities should be gradually increased as the patient tolerates, that is, without exacerbation of symptoms. When the patient can tolerate normal activities, then a provocative test can be performed. This provocative test is exertional physical activity (e.g., run) followed by cognitive testing. If the patient does not have symptoms recurrence and performs well on testing, then he or she may return to full play or work. Many states now have laws that require at least 24 hours’ recovery and written permission from a neurologist or other medical practitioner skilled in managing concussion before return to play or work.

Treatment of mTBI is symptoms focused. In 2009, the U.S. Department of Veterans Affairs in conjunction with the DoD published a set of clinical practice guidelines for the management of concussion and mTBI. These are evidence-based recommendations for which pharmacologic and nonpharmacologic options are provided for each major symptom. For example, headache is to be treated with acetaminophen or nonsteroidal antiinflammatory agents, insomnia with sleep hygiene and nonbenzodiazepine soporific agents acutely, dizziness with physical therapy, and so forth. The American Academy of Neurology’s guidelines note that there is no specific treatment for accelerating or improving recovery from mTBI. The goals are to allow sufficient time for the brain to heal, to minimize risk of reinjury, and treat symptoms.

Recovery from mTBI is a gradual process with the majority of the cognitive recovery occurring in the first 6 months, and approximately 70% to 80% of individuals having few postinjury problems. However, the remaining 20% to 30% have impaired function from residual symptoms that are usually psychiatric. While depression, anxiety, and behavioral problems are commonly identified following TBI, it is exceedingly difficult to discern whether persistent emotional and behavioral symptoms are directly related to the neurologic damage, a secondary reaction to the cognitive deficits of the injury, or a comorbid psychological complication of the trauma itself.

Belanger and colleagues conducted a meta-analysis that raises doubts that persistent postconcussive syndrome symptoms are attributable solely to the injury. This work revealed greater cognitive sequelae of mTBI in “convenience samples,” that is, those seeking medical care for their symptoms, and those involved in litigation, as opposed to unselected or prospective samples. Litigation in particular was associated with stable or worsening cognitive function over time, which is perhaps not surprising; whether subconscious or not, functional improvement would presumably lessen reimbursement from pending litigation, serving as a disincentive to recovery.

In contrast, the investigators also found that studies with unselected populations or prospective designs had no evidence of residual neuropsychological impairment 3 months after their injury. In an exception, one longitudinal study of veterans compared long-term neuropsychological outcomes in those with self-reported mTBI after a motor vehicle accident, to those who had a motor vehicle accident without TBI, and another group who had not had an accident, at an average of 8 years after the accident. Comprehensive neuropsychological testing identified no significant differences between the three groups, although the authors argued that minor, borderline differences on the Paced Auditory Serial Addition Test (PASAT) and California Verbal Learning Test (CVLT) suggested potential subtle attentional problems in the mTBI population. While this finding might indicate potential long-term adverse neuropsychological effects of mTBI, it is quite conceivable that such differences are entirely due to psychiatric comorbidity, which should be carefully assessed in any studies that evaluate the impact of mTBI. Regardless of the pathogenesis, it is clear that the residual emotional and behavioral changes have a significant impact on adjustment, including employment and social relationships. Several factors influence this adjustment such as injury severity, social support, premorbid functioning, and coping styles. For example, coping strategies, such as avoidance, wishful thinking, worry, and self-blame, are associated with higher levels of depression and anxiety in TBI patients. Coping strategies are an area that can be targeted for treatment intervention.

There is an expectation that the military’s social structure can assist soldiers who are struggling with poor concentration, attention, and memory. Having clear responsibilities, belonging to a group and a defined chain of command can provide needed support and structure to a recovering mTBI patient. However, the military can also be relatively unforgiving of mistakes, forgetfulness, or poor attention to detail, leading to soldiers receiving a counseling statement (i.e., an administrative warning) or an Article 15 (i.e., nonjudicial military discipline) for infractions related to their symptoms. This punitive response can lead to increased psychosocial stress, which exacerbates existing symptoms and may contribute to further maintenance of TBI symptoms. Rank structure can be an additional complication as military hierarchy demands more from those of higher rank. Anecdotally, some higher ranking soldiers have reported trying to “pass” as if they are not having difficulties in order to preserve pride and to meet expectations they believe are being placed on them. Intervention research may also need to include specific education for military leaders in how to handle TBI symptoms in the workplace as more soldiers resume their military duties.