Combined medical and surgical treatment after acute spinal cord injury: results of a prospective pilot study to assess the merits of aggressive medical resuscitation and blood pressure management

Central cord syndrome

Central cord syndrome is the most common type of incomplete spinal cord injury. This syndrome most often occurs in older persons with underlying cervical spondylosis caused by a hyperextension mechanism. It also occurs in younger persons who sustain trauma to the cervical spine and, less commonly, as a result of nontraumatic causes. The upper extremities are more affected than the lower extremities, with motor function more severely impaired than sensory function. Central cord syndrome presents a spectrum, from weakness limited to the hands and forearms with sensory preservation, to compete quadriparesis with sacral sparing as the only evidence of incomplete spinal cord injury. Historically, treatment has been nonsurgical, but recovery is often incomplete. Early surgical treatment of central cord syndrome remains controversial. However, recent studies have shown benefits, particularly of early surgery to decompress the spinal cord in patients with pathologic conditions revealed by radiography or MRI.

Development and validation of predictors of respiratory insufficiency and mortality scores: simple bedside additive scores for prediction of ventilation and in-hospital mortality in acute cervical spine injury

BACKGROUND

Numerous studies have developed a "severity score" or "risk index" for mechanical ventilation and mortality, but there are few to predict outcomes for cervical spine injury (CSI) patients. Our objective in this study was to develop a simple bedside additive predictive score for requirement for ventilation and early in-hospital mortality for patients with CSI.

METHODS

Multivariate logistic regression analysis of the data obtained from 101 patients (development set) after surgical stabilization of traumatic CSI was performed to identify independent predictors of the need for mechanical ventilation and of early in-hospital mortality. Predictors of respiratory insufficiency and mortality (PRIM) scores were developed separately for ventilation and mortality by using the coefficients of the logistic regression model. The model was validated using the receiver operating characteristics curve to test its discriminatory ability and by comparing the predicted and observed outcomes. Validation was performed on an independent data set of 87 consecutive patients (validation set) with traumatic acute CSI.

RESULTS

Mechanical ventilation was required in 16.8% of the patients, and the in-hospital mortality rate was 17.8% in the development set. Independent risk factors for mechanical ventilation were severe injury (American Spinal Injury Association Impairment Scale Grades A and B), breath-holding time, pulmonary infection, hemodynamic instability, and progressive neurologic deterioration. Scores of 15, 20, 25, 25, and 15 were assigned to these variables, respectively. Independent predictors of death were severe injury (American Spinal Injury Association Impairment Scale Grades A and B), hemodynamic instability, progressive neurologic deterioration, and mechanical ventilation. The scores assigned for each of the variables were 20, 20, 40, and 20, respectively. The PRIM scores for mechanical ventilation and mortality had excellent discrimination (area under receiver operating characteristics curve >0.75). There was good correlation between predicted and observed outcomes in the development set and the validation set.

CONCLUSION

PRIM scores enable accurate prediction of individual patient risk of need for mechanical ventilation and in-hospital mortality in association with acute CSI.

The efficacy of surgical decompression before 24 hours versus 24 to 72 hours in patients with spinal cord injury from T1 to L1--with specific consideration on ethics: a randomized controlled trial

Background

There is no clear evidence that early decompression following spinal cord injury (SCI) improves neurologic outcome. Such information must be obtained from randomized controlled trials (RCTs). To date no large scale RCT has been performed evaluating the timing of surgical decompression in the setting of thoracolumbar spinal cord injury. A concern for many is the ethical dilemma that a delay in surgery may adversely effect neurologic recovery although this has never been conclusively proven. The purpose of this study is to compare the efficacy of early (before 24 hours) verse late (24–72 hours) surgical decompression in terms of neurological improvement in the setting of traumatic thoracolumbar spinal cord injury in a randomized format by independent, trained and blinded examiners.

Methods

In this prospective, randomized clinical trial, 328 selected spinal cord injury patients with traumatic thoracolumbar spinal cord injury are to be randomly assigned to: 1) early surgery (before 24 hours); or 2) late surgery (24–72 hours). A rapid response team and set up is prepared to assist the early treatment for the early decompressive group. Supportive care, i.e. pressure support, immobilization, will be provided on admission to the late decompression group. Patients will be followed for at least 12 months posttrauma.

Discussion

This study will hopefully assist in contributing to the question of the efficacy of the timing of surgery in traumatic thoracolumbar SCI.

Trial Registration

RCT registration number: ISRCTN61263382

Autonomic function following cervical spinal cord injury

Spinal cord injury (SCI) is commonly associated with devastating paralysis. However, this condition also results in a variety of autonomic dysfunctions, primarily: cardiovascular, broncho-pulmonary, urinary, gastrointestinal, sexual, and thermoregulatory. SCI and the resultant unstable autonomic control are responsible for increased mortality from cardiovascular and respiratory disease among individuals with SCI. Injury level and severity directly correlate to the severity of autonomic dysfunctions following SCI. Following high cervical SCI, parasympathetic (vagal) control will remain intact, while the spinal sympathetic circuits will lose their tonic supraspinal autonomic control. On the other hand, in individuals with injury below the 5th thoracic segment, both the sympathetic and parasympathetic control of the heart and broncho-pulmonary tree are intact. As a result of injury level, individuals with quadriplegia versus those with paraplegia will have very different cardiovascular and respiratory responses. Furthermore, similar relationships can exist between the level of SCI and function of other organs that are under autonomic control (bladder, bowel, sweat glands, etc.). It is also important to appreciate that high cervical injuries result in significant respiratory dysfunctions due to the involvement of the diaphragm and a larger portion of the accessory respiratory muscles. Early recognition and timely management of autonomic dysfunctions in individuals with SCI are crucial for the long term health outcomes in this population.

Pharmacological management of hemodynamic complications following spinal cord injury

Damage from spinal cord injury (SCI) may be complicated by concomitant hemodynamic alterations within hours to months of the initial insult. Neurogenic shock, symptomatic bradycardia, autonomic dysreflexia, and orthostatic hypotension are specific conditions occurring commonly with SCI. Early recognition and appropriate management of each disorder may minimize secondary injury to the cord, avert systemic complications, and help alleviate patient discomfort.

Intrathecal pressure monitoring and cerebrospinal fluid drainage in acute spinal cord injury: a prospective randomized trial

OBJECT

Ischemia is an important factor in the pathophysiology of secondary damage after traumatic spinal cord injury (SCI) and, in the setting of thoracoabdominal aortic aneurysm repair, can be the primary cause of paralysis. Lowering the intrathecal pressure (ITP) by draining CSF is routinely done in thoracoabdominal aortic aneurysm surgery but has not been evaluated in the setting of acute traumatic SCI. Additionally, while much attention is directed toward maintaining an adequate mean arterial blood pressure (MABP) in the acute postinjury phase, little is known about what is happening to the ITP during this period when spinal cord perfusion pressure (MABP - ITP) is important. The objectives of this study were to: 1) evaluate the safety and feasibility of draining CSF to lower ITP after acute traumatic SCI; 2) evaluate changes in ITP before and after surgical decompression; and 3) measure neurological recovery in relation to the drainage of CSF.

METHODS

Twenty-two patients seen within 48 hours of injury were prospectively randomized to a drainage or no-drainage treatment group. In all cases a lumbar intrathecal catheter was inserted for 72 hours. Acute complications of headache/nausea/vomiting, meningitis, or neurological deterioration were carefully monitored. Acute Spinal Cord Injury motor scores were documented at baseline and at 6 months postinjury.

RESULTS

On insertion of the catheter, mean ITP was 13.8 +/- 1.3 mm Hg (+/- SD), and it increased to a mean peak of 21.7 +/- 1.5 mm Hg intraoperatively. The difference between the starting ITP on catheter insertion and the observed peak intrathecal pressure after decompression was, on average, an increase of 7.9 +/- 1.6 mm Hg (p < 0.0001, paired t-test). During the postoperative period, the peak recorded ITP in the patients randomized to the no-drainage group was 30.6 +/- 2.3 mm Hg, which was significantly higher than the peak intraoperative ITP (p = 0.0098). During the same period, the peak recorded ITP in patients randomized to receive drainage was 28.1 +/- 2.8 mm Hg, which was not statistically higher than the peak intraoperative ITP (p = 0.15).

CONCLUSIONS

The insertion of lumbar intrathecal catheters and the drainage of CSF were not associated with significant adverse events, although the cohort was small and only a limited amount of CSF was drained. Intraoperative decompression of the spinal cord results in an increase in the ITP measured caudal to the injury site. Increases in intrathecal pressure are additionally observed in the postoperative period. These increases in intrathecal pressure result in reduced spinal cord perfusion that will otherwise go undetected when measuring only the MABP. Characteristic changes in the observed intrathecal pressure waveform occur after surgical decompression, reflecting the restoration of CSF flow across the SCI site. As such, the waveform pattern may be used intraoperatively to determine if adequate decompression of the thecal sac has been accomplished.

Cardiovascular complications after acute spinal cord injury: pathophysiology, diagnosis, and management

Cardiovascular complications in the acute stage following traumatic spinal cord injury (SCI) require prompt medical attention to avoid neurological compromise, morbidity, and death. In this review, the authors summarize the neural regulation of the cardiovascular system as well as the pathophysiology, diagnosis, and management of major cardiovascular complications that can occur following acute (up to 30 days) traumatic SCI. Hypotension (both supine and orthostatic), autonomic dysreflexia, and cardiac arrhythmias (including persistent bradycardia) are attributed to the loss of supraspinal control of the sympathetic nervous system that commonly occurs in patients with severe spinal cord lesions at T-6 or higher. Current evidence-based guidelines recommend: 1) monitoring of cardiac and hemodynamic parameters in the acute phase of SCI; 2) maintenance of a minimum mean arterial blood pressure of 85 mm Hg during the hyperacute phase (1 week after SCI); 3) timely detection and appropriate treatment of neurogenic shock and cardiac arrhythmias; and 4) immediate and adequate treatment of episodes of acute autonomic dysreflexia. In addition to these forms of cardiovascular dysfunction, individuals with acute SCIs are at high risk for deep venous thrombosis (DVT) and pulmonary embolism due to loss of mobility and, potentially, altered fibrinolytic activity, abnormal platelet function, and impaired circadian variations of hemostatic and fibrinolytic parameters. Current evidence supports a recommendation for thromboprophylaxis using mechanical methods and anticoagulants during the acute stage up to 3 months following SCI, depending on the severity and level of injury. Low-molecular-weight heparin is the first choice for anticoagulant prophylaxis in patients with acute SCI. Although there is insufficient evidence to recommend (or refute) the use of screening tests for DVT in asymptomatic adults with acute SCI, this strategy may detect asymptomatic DVT in at least 9.4% of individuals who undergo thromboprophylaxis using lowmolecular- weight heparin. Indications and treatment of DVT and acute pulmonary embolism are well established and are summarized in this review. Recognition of cardiovascular complications after acute SCI is essential to minimize adverse outcomes and to optimize recovery.

Prevention, identification, and treatment of perioperative spinal cord injury

OBJECT

In this report, the authors suggest evidence-based approaches to minimize the chance of perioperative spinal cord injury (POSCI) and optimize outcome in the event of a POSCI.

METHODS

A systematic review of the basic science and clinical literature is presented.

RESULTS

Authors of clinical studies have assessed intraoperative monitoring to minimize the chance of POSCI. Furthermore, preoperative factors and intraoperative issues that place patients at increased risk of POSCI have been identified, including developmental stenosis, ankylosing spondylitis, preexisting myelopathy, and severe deformity with spinal cord compromise. However, no studies have assessed methods to optimize outcomes specifically after POSCIs. There are a number of studies focussed on the pathophysiology of SCI and the minimization of secondary damage. These basic science and clinical studies are reviewed, and treatment options outlined in this article.

CONCLUSIONS

There are a number of treatment options, including maintenance of mean arterial blood pressure > 80 mm Hg, starting methylprednisolone treatment preoperatively, and multimodality monitoring to help prevent POSCI occurrence, minimize secondary damage, and potentially improve the clinical outcome of after a POSCI. Further prospective cohort studies are needed to delineate incidence rate, current practice patterns for preventing injury and minimizing the clinical consequences of POSCI, factors that may increase the risk of POSCI, and determinants of clinical outcome in the event of a POSCI.

Hyponatremia in the acute stage after traumatic cervical spinal cord injury: clinical and neuroanatomic evidence for autonomic dysfunction

STUDY DESIGN

Retrospective cohort study supplemented by analysis of postmortem spinal cord tissue.

OBJECTIVES

This study examines the frequency of hyponatremia in early stage (2 weeks) after cervical spinal cord injury (SCI), and the relationship between integrity of key autonomic pathways and hyponatremia.

SUMMARY OF BACKGROUND DATA

Interruption of key circuits in the spinal cord can induce autonomic dysfunction with disordered metabolic and physiologic homeostasis. Given that hyponatremia may be a common electrolyte disorder during the acute stage post-SCI, we hypothesized that disconnection of descending sympathetic renal spinal cord tracts may be associated with hyponatremia after SCI.

METHODS

Consecutive individuals with cervical spine trauma were included in our cohort of patients, which was divided into a SCI group and a control group (patients with spine trauma without SCI). Also, postmortem spinal cord sections from individuals with cervical, motor complete SCI, and control cases without CNS trauma were evaluated regarding the extent of axonal preservation within the descending vasomotor pathways, the descending renal sympathetic pathways (DRSPs), the corticospinal tracts, and the dorsal columns.

RESULTS

There were 21 SCI individuals (6 women, 15 men; ages, 17-83 years; mean, 57.1) and 12 patients in the control spine trauma group who did not have SCI (4 women, 8 men; ages 18-90 years; mean, 45.9). Patients had either motor complete (7/21) or motor incomplete (14/21) tetraplegia. Hyponatremia occurred in 85.7% after SCI, which was significantly more frequent than the control group. Postmortem analysis included 5 control cases and 6 SCI individuals of whom 3 developed hyponatremia. The number of preserved axons within the DRSPs from normonatremic SCI patients was significantly lower than the number of axons within DRSPs from hyponatremic SCI patients, but development of hyponatremia was not associated with the integrity of the descending vasomotor pathways. Hyponatremic SCI individuals also showed greater evidence of neurogenic hypotension than normonatremic SCI individuals.

CONCLUSION

Hyponatremia is common in the early stage post-SCI. Our results also suggest that hyponatremia is associated with the integrity of descending renal sympathetic circuits which mediate the renin-angiotensin response to neural injury, in the setting of neurogenic hypotension with cardiovascular dysfunction.

The effects of trauma center care, admission volume, and surgical volume on paralysis after traumatic spinal cord injury

OBJECTIVE

To evaluate compliance with American College of Surgeons (ACS) guidelines and whether trauma center designation, hospital traumatic spinal cord injury (TSCI) case volume or spinal surgery volume is associated with paralysis. We hypothesized a priori that trauma center care, by contrast to nontrauma center care, is associated with reduced paralysis at discharge.

SUMMARY BACKGROUND DATA

Approximately 11,000 persons incur a TSCI in the United States annually. The ACS recommends all TSCI patients be taken to a level I or II trauma center.

METHODS

We studied 4121 patients diagnosed with TSCI by ICD-9-CM criteria in the 2001 hospital discharge files of 7 states (Florida, Massachusetts, New Jersey, New York, Texas, Virginia, Washington), who were treated in 100 trauma centers and 601 nontrauma centers. We performed multivariate analyses, including a propensity score quintile approach, adjusting for differences in case mix and clustering by hospital and by state. We also studied 3125 patients using the expanded modified Medicare Provider Analysis and Review records for the years 1996, 2001, and 2006 to assess temporal trends in paralysis by trauma center designation.

RESULTS

Mortality was 7.5%, and 16.3% were discharged with paralysis. Only 57.9% (n = 2378) received care at a designated trauma center. Trauma centers had a 16-fold higher admission caseload (20.7 vs. 1.3; P < 0.001) and 30-fold higher surgical volume (9.6 vs. 0.3; P < 0.001). In the multivariate propensity analysis, paralysis was significantly lower at trauma centers (adjusted odds ratio 0.67; 95% confidence interval, 0.53-0.85; P = 0.001). Higher surgical volume, not higher admission volume, was associated with lower risk of paralysis. Indeed, at nontrauma centers, higher admission caseload was associated with worse outcome. There was no significant difference in mortality.

CONCLUSIONS

Trauma center care is associated with reduced paralysis after TSCI, possibly because of greater use of spinal surgery. National guidelines to triage all such patients to trauma centers are followed little more than half the time.

Effect of spinal cord injury on the respiratory system: basic research and current clinical treatment options

Spinal cord injury (SCI) often leads to an impairment of the respiratory system. The more rostral the level of injury, the more likely the injury will affect ventilation. In fact, respiratory insufficiency is the number one cause of mortality and morbidity after SCI. This review highlights the progress that has been made in basic and clinical research, while noting the gaps in our knowledge. Basic research has focused on a hemisection injury model to examine methods aimed at improving respiratory function after SCI, but contusion injury models have also been used. Increasing synaptic plasticity, strengthening spared axonal pathways, and the disinhibition of phrenic motor neurons all result in the activation of a latent respiratory motor pathway that restores function to a previously paralyzed hemidiaphragm in animal models. Human clinical studies have revealed that respiratory function is negatively impacted by SCI. Respiratory muscle training regimens may improve inspiratory function after SCI, but more thorough and carefully designed studies are needed to adequately address this issue. Phrenic nerve and diaphragm pacing are options available to wean patients from standard mechanical ventilation. The techniques aimed at improving respiratory function in humans with SCI have both pros and cons, but having more options available to the clinician allows for more individualized treatment, resulting in better patient care. Despite significant progress in both basic and clinical research, there is still a significant gap in our understanding of the effect of SCI on the respiratory system.

Autonomic Nervous System Dysfunction After Spinal Cord Injury

The autonomic nervous system (ANS) plays a key role in the regulation of many physiologic processes, mediated by supraspinal control from centers in the central nervous system. The role of autonomic dysfunction in persons with spinal cord injuries is crucial to understand because many aspects of the altered physiology seen in these individuals are directly caused by ANS dysregulation.

Single level arthrodesis as treatment for midcervical fracture subluxation: a cohort study

Although many different techniques exist for fusion of midcervical facet fracture dislocations, limiting arthrodesis to a single level could have a theoretical advantage: fewer fused segments could lessen long-term negative effects of fusion on adjacent segments. Therefore, we prospectively treated 22 consecutive patients with midcervical fracture dislocation without vertebral body fracture with single level arthrodesis even if anterior/posterior surgery were required. Twelve patients with unilateral facet subluxation underwent anterior cervical discectomy, distraction reduction with Caspar posts (AESCULAP, Tuttlingen, Germany) with allograft fusion and anterior cervical plating. Ten patients with any component of bilateral facet subluxation underwent anterior cervical discectomy, distraction reduction with Caspar posts, allograft fusion and plating followed by posterior lateral mass plating. No patients demonstrated worsening of nerve root or spinal cord function postoperatively. Interbody stability occurred in all cases. Only complications were 4 cases of pneumonia, 1 case of wound leakage, and 1 case of superficial wound infection. Good reduction was achieved for both unilateral and bilateral facet fractures. Single level interbody arthrodesis is safe and effective strategy with both unilateral and bilateral facet fractures. Single level arthrodesis may also offer long-term benefit compared with multilevel fusions.

[Spontaneous spinal epidural haematoma during pregnancy]

Spontaneous spinal epidural haematomas are quite rare. We report here the case of a 27-year-old woman, without previous history of relevant medical disorder, who presented with acute paraplegia at 36 weeks of gestation. MRI performed in emergency revealed a T8 epidural haematoma. The management consisted in an emergency Caesarean section under general anaesthesia, followed immediately by a T8 laminectomy allowing the spinal cord decompression 14 hours after the first symptoms. Neurologic recovery was rapid and complete, except for bladder dysfunction persisting one month later. Spontaneous spinal epidural haematomas require a prompt diagnosis because neurologic prognosis essentially depends on the interval of time between onset of symptoms and surgical decompression. Obstetrical management especially depends on the term of pregnancy. For the anaesthesiologist, the difficulty is the management of both pregnant condition (full stomach general anaesthesia) and spinal cord compression (maintenance of spinal cord perfusion pression and limitation of ischaemia and oedema).

Hemodynamic parameters and timing of surgical decompression in acute cervical spinal cord injury

BACKGROUND/OBJECTIVES

To evaluate the relationship between the severity of cervical spinal cord injury (SCI) (American Spinal Injury Association [ASIA] grade), presence of neurogenic shock, and timing of surgical intervention. This is a post-hoc analysis from the Sygen multicenter randomized controlled trial.

METHODS

Blood pressure (BP) and heart rate (HR) data were collected when patients were first assessed in the emergency room (Time A) and at the time of randomization (Time B). Individuals were subdivided by ASIA grade and by the level of the systolic BP (SBP).

RESULTS

Only individuals with cervical SCI from the Sygen trial (n = 577) were evaluated. Severe complete SCI (ASIA grade = A) was established in 57% of these patients. A total of 74 (13%) patients with neurogenic shock (SBP < 90 mmHg) at Time A were identified. The SBP increased significantly from Time A to Time B (P < 0.0001). The median time from SCI to surgical intervention, for ASIA A, was 80.9 hours for patients with initial SBP < 90 mmHg and 58 hours for patients with initial SBP > or = 90 mmHg (P = 0.025). Multivariable analysis after adjusting for confounders revealed a statistically significant difference in the time to surgical intervention based on SBP for ASIA A (P = 0.026), yet not for ASIA B or C/D.

CONCLUSIONS

The presence of neurogenic shock was associated with a delay in the timing of surgical intervention in patients with cervical SCI. Detailed evaluation of autonomic dysfunctions following SCI including cardiovascular instability could improve our understanding of the complexities of clinical presentations and possible neurological outcomes.

Infarction of the cervical spinal cord following multilevel transforaminal epidural steroid injection: case report and review of the literature

BACKGROUND/OBJECTIVE

Transforaminal epidural steroid injection is a widely utilized nonsurgical strategy for the management of cervical radicular and axial pain. The technique has been shown to be efficacious in relieving the patients' symptoms. Although effective, there are a range of possible complications associated with this procedure. We report the case of a patient with an acute infarction of the cervical spinal cord after a multilevel transforaminal epidural steroid injection.

METHODS

We performed a retrospective chart review of a single case.

RESULTS

The patient suffered an acute brainstem and cervical spinal cord infarction despite the use of many techniques to minimize the occurrence of vascular injury during the procedure. The patient regained some function after medical and physical therapy.

CONCLUSIONS

This complication, to our knowledge, has only been reported in the literature on 2 other occasions and serves as a reminder of the potentially devastating consequences of performing procedures in proximity to the nervous system.

REVIEW OF TREATMENT TRIALS IN HUMANSPINAL CORD INJURY

OBJECTIVE

To provide a comprehensive review of the treatment trials in the field of spinal cord injury, emphasizing what has been learned about the effectiveness of the agents and strategies tested and the quality of the methodology. The review aims to provide useful information for the improvement of future trials. The review audience includes practitioners, researchers, and consumers.

METHODS

All publications describing organized trials since the 1960s were analyzed in detail, emphasizing randomized, prospective controlled trials and published Phase I and II trials. Trials were categorized into neuroprotection, surgery, regeneration, and rehabilitation trials. Special attention was paid to design, outcome measures, and case selection.

RESULTS

There are 10 randomized prospective control trials in the acute phase that have provided much useful information. Current neurological grading systems are greatly improved, but still have significant shortcomings, and independent, trained, and blinded examiners are mandatory. Other trial designs should be considered, especially those using adaptive randomization. Only methylprednisolone and thyrotropin-releasing hormone have been shown to be effective, but the results of the former are controversial, and studies involving the latter involved too few patients. None of the surgical trials has proven effectiveness. Currently, a multitude of cell-based Phase I trials in several countries are attracting large numbers of patients, but such treatments are unproven in effectiveness and may cause harm. Only a small number are being conducted in a randomized or blinded format. Several consortia have committed to a promise to improve the conduct of trials.

CONCLUSION

A large number of trials in the field of spinal cord injury have been conducted, but with few proven gains for patients. This review reveals several shortcomings in trial design and makes several recommendations for improvement.

Assessment of three year experience of a strategy for patient selection and timing of operation in the management of acute thoracic and lumbar spine fractures: a prospective study

BACKGROUND

The purpose of this article is to report experience gained over three years of the use of a protocol for patient selection and timing of operation for acute thoracic and lumbar fractures.

METHOD

At admission, all patients underwent neurological and imaging exams. All patients with a spinal cord lesion scored as ASIA A at any level inferior to T10 and as ASIA B, C or D at any level, were categorized as emergency and operated on within eight hours from trauma. ASIA A cases in the T1-T10 tract and ASIA E cases at any level were treated in the ordinary operative work schedule.

FINDINGS

Ninety-four patients with surgically treated lumbar or thoracic fractures took part in this study. On the imaging studies, 12 patients were classified as A, 50 as B and 32 as C following the AO classification. At the neurological exam, 39 patients were scored as ASIA A, nine as B, six as C, two as D and 38 as E. At follow-up, of the 39 patients scored as ASIA A, 13 (33%) improved at least one grade and of the 17 scored as ASIA B, C or D, 11 (64.7%) improved. None of the 38 patients scored as ASIA E deteriorated.

CONCLUSIONS

The findings show that the strategy in the protocol was safe and followed by satisfactory rates of neurological outcome. Larger prospective studies, preferably randomized, are needed to establish definitively its place in the management of patients with spinal injury.

Management of spinal injury

Spinal injury often affects young adults and results in debilitating neurological status, which in turn places a significant burden on society. This review article describes the current practice and controversies surrounding the management of spinal injury. General principles of pre-hospital management, resuscitation, medical treatment, surgical intervention and future advancement are reviewed.

The timing of surgical intervention in the treatment of spinal cord injury: a systematic review of recent clinical evidence

STUDY DESIGN

Evidence-based literature review.

OBJECTIVE

To provide updated evidence-based recommendations regarding spinal cord decompression in patients with acute spinal cord injury (SCI).

SUMMARY OF BACKGROUND DATA

It is controversial whether early decompression following SCI conveys a benefit in neurologic outcome.

METHODS

MEDLINE search of experimental and clinical studies showing the effect of decompression on neurologic outcome following SCI. We focused on articles published within the last 10 years, with a particular emphasis on research conducted within the past 5 years.

RESULTS

A total of 66 articles were retrieved. Animal studies consistently show that neurologic recovery is enhanced by early decompression. There was 1 randomized controlled trial that showed no benefit to early (<72 hours) decompression. Several recent prospective series suggest that early decompression (<72 hours) can be performed safely and may improve neurologic outcomes. A recent systematic review showed that early decompression (<24 hours) resulted in statistically better outcomes compared to both delayed decompression and conservative treatment.

CONCLUSIONS

There are currently no standards regarding the role and timing of decompression in acute SCI. We recommend urgent decompression of bilateral locked facets in a patient with incomplete tetraplegia or in a patient with SCI with neurologic deterioration. Urgent decompression in acute cervical SCI remains a reasonable practice option and can be performed safely. There is emerging evidence that surgery within 24 hours may reduce length of intensive care unit stay and reduce post-injury medical complications.

Strategies of medical intervention in the management of acute spinal cord injury

STUDY DESIGN

: Literature review.

OBJECTIVE

: The purpose of this paper is to review clinical treatment strategies and future developments in the treatment of acute spinal cord injury.

SUMMARY OF BACKGROUND DATA

: The treatment of acute spinal cord injury continues to be supportive. The search for specialized pharmacologic agents to prevent secondary injury and promote repair or regeneration remains heated.

METHODS

: Medline search from 1996 to present limited to clinical research and basic science review articles in the English Language.

RESULTS

: Steroids continue to be administered in the clinical setting of acute spinal cord injury primarily out of peer pressure and fear of litigation. Basic science experiments suggest that modulation of post-traumatic inflammation may provide the best opportunity to arrest the secondary injury cascade. Protein kinase and metalloproteinase inhibition are promising treatment strategies. Regeneration techniques are concentrating on cell transplantation and manipulating glial receptors and protein production. Clinical investigations are limited to Phase III trials on a very select few of these drugs.

CONCLUSIONS

: While many advances in the basic science of spinal cord injury provide optimism for future treatments, clinical science lags. At present, there are no pharmacologic strategies of proven benefit. Although steroids continue to be given to patients with spinal cord injury in many institutions, evidence of deleterious effects continues to accumulate. Current standard of care management includes support of arterial oxygenation and spinal cord perfusion pressure.

The clinical problems in cardiovascular control following spinal cord injury: an overview

On a daily basis, individuals with cervical and upper thoracic spinal cord injury face the challenge of managing their unstable blood pressure, which frequently results in persistent hypotension and/or episodes of uncontrolled hypertension. This chapter will focus on the clinical issues related to abnormal cardiovascular control in individuals with spinal cord injury, which include neurogenic shock, autonomic dysreflexia and orthostatic hypotension. Blood pressure control depends upon tonic activation of sympathetic preganglionic neurons by descending input from the supraspinal structures (Calaresu and Yardley, 1988). Following spinal cord injury, these pathways are disrupted, and thus spinal circuits are solely responsible for the generation of sympathetic activity (Osborn et al., 1989; Maiorov et al., 1997). This results in a variety of cardiovascular abnormalities that have been well documented in human studies, as well as in animal models (Osborn et al., 1990; Mathias and Frankel, 1992a, b; Krassioukov and Weaver, 1995; Maiorov et al., 1997, 1998; Teasell et al., 2000). However, the recognition and management of these cardiovascular dysfunctions following spinal cord injury represent challenging clinical issues. Moreover, cardiovascular disorders in the acute and chronic stages of spinal cord injury are among the most common causes of death in individuals with spinal cord injury (DeVivo et al., 1999).

Spinal cord injury (SCI)--prehospital management

Up to 20,000 patients annually suffer from spinal cord injury (SCI) and 20% of these die before being admitted to the hospital in the United States as well as in the European Union. Prehospital management of SCI is of critical importance since 25% of SCI damage may occur or be aggravated after the initial event. Prehospital management includes examination of the patient, spinal immobilisation, careful airway management (intubation, if indicated, using manual in-line stabilisation), and cardiovascular support (maintenance of mean arterial blood pressure above 90 mm Hg) and blood glucose levels within the normal range. It is still not known whether additional specific therapy is useful. Studies have not demonstrated convincingly that methylprednisolone (MPS) or other pharmacological agents really have clinically significant and important benefits for patients suffering from SCI. Recently published statements from the United States also do not support the therapeutic use of MPS in patients suffering from SCI in the prehospital setting any more. Moreover, at this stage, it is not known whether therapeutic hypothermia or any further pharmacological intervention has beneficial effects or not. Therefore, networks for clinical studies in SCI patients should be established, as a basic requirement for further improvement in outcome in such patients.

Spontaneous acute thoracic epidural hematoma causing paraplegia in a patient with severe preeclampsia in early labor

This is a case of acute spontaneous thoracic epidural hematoma in a laboring patient at term who presented with severe preeclampsia and acute spinal cord compression, paraplegia, and sensory loss below T8. In early labor, at home, the patient experienced sudden lumbar back pain that progressed to mid-scapular pain leading to paraplegia and T8 sensory loss within one hour of onset of pain. Her symptoms were caused by a spontaneous thoracic epidural hematoma. Upon arrival at the first hospital, the correct presumptive diagnosis was made in the emergency room, magnesium sulfate was administered, and the patient was transferred to our medical center. Her hypertension was not treated despite severe preeclampsia in order to maintain spinal cord perfusion pressure. Following cesarean section under general anesthesia, thoracic laminectomy was performed and an epidural hematoma compressing the spinal cord to 2-3 mm was evacuated 13 h after the onset of symptoms. After approximately three months of paraplegia, five months with quad-walker and cane use, the patient can now walk with a cane or other minimal support but has remaining bowel and bladder problems. The conflicting anesthetic management objectives of severe preeclampsia and acute paraplegia secondary to spinal epidural hematoma required compromise in the management of her preeclampsia in order to preserve spinal cord perfusion.

The role and timing of early decompression for cervical spinal cord injury: update with a review of recent clinical evidence

It remains controversial whether early decompression following spinal cord injury conveys a benefit in neurological outcome. The goal of this paper is to provide evidence-based recommendations regarding spinal cord decompression in patients with acute spinal cord injury. We performed a Medline search of experimental and clinical studies reporting on the effect of decompression on neurological outcome following spinal cord injury. Animal studies consistently show that neurological recovery is enhanced by early decompression. One randomized controlled trial showed no benefit to early (<72 h) decompression, however, several recent prospective series suggest that early decompression (<12 h) can be performed safely and may improve neurological outcomes. A recent meta-analysis showed that early decompression (<24 h) resulted in statistically better outcomes compared to both delayed decompression and conservative management. Currently, there are no standards regarding the role and timing of decompression in acute spinal cord injury. We recommend urgent decompression of bilateral locked facets in patients with incomplete tetraplegia or in patients with spinal cord injury experiencing neurological deterioration. Urgent decompression in acute cervical spinal cord injury remains a reasonable practice option and can be performed safely.

[Prehospital management of spinal cord injuries]

In both the United States and Europe about 10,000 patients suffer from spinal cord injury (SCI) each year and 20% die before being admitted to hospital. Prehospital management of SCI is very important since 25% of SCI damage may occur after the initial event. Emergency treatment includes examination of the patient, spinal immobilization, careful airway management, cardiovascular stabilization (maintenance of mean arterial blood pressure above 90 mmHg) and glucose levels within the normal range. From an evidence-based point of view, it is still not known whether additional specific therapy is useful and studies have not convincingly demonstrated that methylprednisolone (MPS) or other substances have clinically important benefits. Recently published statements from the US do not support the therapeutic use of MPS in patients suffering from SCI in the prehospital setting. Moreover, it is not known whether hypothermia or any other pharmacological interventions have beneficial effects. Networks for clinical studies in SCI patients should be established as a basic requirement for further improvement in outcome in these patients.

Efficacy of surgical decompression in the setting of complete thoracic spinal cord injury

BACKGROUND/OBJECTIVE

An assessment of neurological improvement after surgical intervention in the setting of traumatic thoracic spinal cord injury (SCI).

METHODS

A retrospective evaluation of a nonconsecutive cohort of patients with a thoracic SCI from T2 to T11. The analysis included a total of 12 eligible patients. The neurologic and functional outcomes were recorded from the acute hospital admission to the most recent follow-up. Data included patient age, level of injury, neurologic examination according to the Frankel grading system, the performance of surgery, and the mechanism of the time-related SCI decompression.

RESULTS

All patients had a complete thoracic SCI. The median interval from injury to surgery was 11 days (range, 1-36 days). Decompression, bone fusion, and instrumentation were the most common surgical procedures performed. The median length of follow-up was 18 months after surgery (range, 9-132 months). Motor functional improvement was seen in 1 patient (Frankel A to C).

CONCLUSION

Surgical decompression and fusion imparts no apparent benefit in terms of neurologic improvement (spinal cord) in the setting of a complete traumatic thoracic SCI. To better define the role of surgical decompression and stabilization in the setting of a complete SCI, randomized, controlled, prospective studies are necessary.

Does early decompression improve neurological outcome of spinal cord injured patients? Appraisal of the literature using a meta-analytical approach

STUDY DESIGN

Definitive and unequivocal evidence to support the practice of early or late surgery is still lacking in clinical studies. Accordingly, meta-analysis is one of the few methods that offer a rational, statistical approach to management decision. A review of the clinical literature on spinal cord injury with emphasis on the role of early surgical decompression and a meta-analysis of results was performed.

OBJECTIVES

To determine whether neurological outcome is improved in traumatic spinal cord-injured patients who had surgery within 24 h as compared with those who had late surgery or conservative treatment.

METHODS

A Medline search covering the period 1966-2000, supplemented with manual search, was used to locate studies containing information on indication, rationale and timing of surgical decompression after spinal cord injuries. The analysis included a total of 1687 eligible patients.

RESULTS

Statistically, early decompression resulted in better outcome compared with both conservative (P<0.001) and late management (P<0.001). Nevertheless, analysis of homogeneity showed that only data regarding patients with incomplete neurological deficits who had early surgery were reliable.

CONCLUSIONS

Although statistically the percentage of patients with incomplete neurological deficits improving after early decompression appear 89.7% (95% confidence interval: 83.9, 95.5%), to be better than with the other modes of treatment when taking into consideration the material available for analysis and the various other factors including clinical limitations; early surgical decompression can only be considered as practice option for all groups of patients.

Experimental spinal cord ischemia: Model characterization and improved outcome with arterial hypertension*

OBJECTIVE

Paraplegia from spinal cord ischemia is a devastating complication of thoracoabdominal aortic aneurysm repair. Perioperative hypoperfusion of the spinal cord is a critical determinant of residual neurologic deficits. We determined if functional and histologic outcome is dependent on systemic blood pressure in a rat model of spinal cord ischemia.

DESIGN

Randomized, controlled, prospective study.

SETTING

Research laboratory at a university teaching hospital.

SUBJECTS

Adult male Wistar rats.

INTERVENTIONS

Endotracheally intubated adult male Wistar rats (300-450 g) anesthetized with halothane underwent a thoracotomy and placement of a clip across the descending aorta for 27 mins. Mean proximal arterial blood pressure (MPABP) was monitored with a cannula placed in the left common carotid artery. Halothane was adjusted (1.25-1.5%) to maintain MPABP between 70 and 90 mm Hg (n = 20) or 140 and 150 mm Hg (n = 20). Shamoperated rats (n = 10) had a thoracotomy without aortic clamping at an MPABP of 70-90 mm Hg. Following 1, 24, 48, and 72 hrs of recovery from anesthesia, motor function of the hind paws was scored as follows: 0, no evidence of deficit; 1, toes flat under body when walking but with ataxia; 2, knuckle walks; 3, movements in hind limbs but unable to knuckle walk; 4, no movement, drags hind limbs. Body temperature was maintained between 37 and 38 degrees C throughout the experiment.

MEASUREMENTS AND MAIN RESULTS

All sham operated rats with MPABP 70-90 mm Hg recovered without neurologic deficits, whereas those that underwent aortic occlusion with MPABP between 70 and 90 mm Hg emerged from anesthesia with grade 3 and 4 deficits and remained in this condition without improvement at 72 hrs. Histopathology at 72 hrs demonstrated moderate to severe neuronal loss with involvement of dorsal, intermediate, and ventral horns. Only eight of 20 rats that underwent aortic occlusion with MPABP between 140 and 150 mm Hg had grade 1 and 2 deficits on emergence but had no neurologic deficit after 1 hr. Most of the surviving neurons in these animals appeared normal histologically, particularly motor neurons around the periphery of the ventral horn.

CONCLUSIONS

Systemic blood pressure is a critical determinant of outcome following spinal cord ischemia, and controlled peri-operative blood pressure augmentation may ameliorate neurologic deficits in patients who undergo thoracoabdominal vascular procedures and are at risk for spinal cord hypoperfusion.

Descending Vasomotor Pathways in Humans: Correlation between Axonal Preservation and Cardiovascular Dysfunction after Spinal Cord Injury

Cardiovascular dysfunction is common after cervical spinal cord injury (SCI) in humans. At least three spinal cord elements involved in cardiovascular control have been identified: descending vasomotor pathways (DVPs), sympathetic preganglionic neurons, and spinal afferents. However, little is known about the localization of the DVPs within the human spinal cord, which limits our understanding of the mechanisms of cardiovascular dysfunction after SCI. This study was undertaken to examine the association of cardiovascular abnormalities after SCI in humans with the severity of degeneration and axonal loss within the DVPs. A detailed chart review and histopathological examination of postmortem spinal cord tissue was conducted in individuals with cervical SCI (n = 7) and control individuals with an intact central nervous system (n = 5). Individuals with SCI were divided into group 1 (severe cardiovascular abnormalities) and group 2 (no/minor cardiovascular disturbances). The area of degeneration and the number of preserved axons within different areas of the spinal cord were quantitated using EMPIX imaging software. Two areas of possible localization of DVPs were investigated: area I, within the dorsal aspects of the lateral funiculus; and area II, within the white matter adjacent to the dorsolateral aspect of the lateral horn. Comparison of the extent of axonal degeneration in both SCI groups demonstrated that individuals in group 1 had more extensive axonal degeneration than those in group 2. The number of intact axons within areas I and II in individuals from group 1 was significantly lower than those from group 2 or control cases (p = 0.029; p = 0.028). The most dramatic axonal loss was observed within area I in individuals with cardiovascular dysfunction. We conclude that loss and degeneration of DVPs, which are localized within the dorsolateral aspects of the human spinal cord, contributes to abnormal cardiovascular control after SCI. This information adds to our knowledge of pathobiology of cardiovascular dysfunction after human SCI and may ultimately suggest novel therapeutic strategies as regenerative and reparative approaches become translated to the clinic.

Critical care and perioperative management in traumatic spinal cord injury

Traumatic spinal cord injury is frequently associated with brain injury and with alterations in respiratory and cardiovascular function that require critical care management. Complications include respiratory failure, atelectasis, pneumonia, neurogenic shock, autonomic dysreflexia, venous thromboembolism, and sepsis. While complications may be managed with supportive care, the goal of ameliorating neurologic outcome has proved elusive. Methylprednisolone, when instituted <8 hours after traumatic spinal cord injury, was associated in two clinical trials with statistically significant improvements in motor scores at 6 months and 1 year; however, critical reappraisal of these data raises questions about their validity and clinical relevance. Until more evidence of clinically effective therapies is available, acute management must be driven by pathophysiologic principles, with emphasis on interventions that attenuate secondary neurologic injury; these include the rational use of immobilization, cautious airway management, and promotion of cord perfusion and oxygenation with the appropriate level of hemodynamic and respiratory support. Clinical trials of pharmacologic neuroprotection have yielded disappointing results, but the ongoing elucidation of spinal cord repair and regenerative mechanisms suggests new therapeutic prospects.

Current concepts in neurocritical care

The current concepts in neurocritical care including advancement in therapeutic interventions and monitoring modalities are covered for four entities: stroke, subarachnoid hemorrhage, traumatic brain injury and spinal cord injury. Although therapies were mainly supportive in the past, acute ischemic stroke may now be treated with tissue plasminogen activator if inclusion and exclusion criteria are met. The management of subarachnoid hemorrhage including cerebral vasospasm is discussed in detail. Traumatic brain injury and spinal cord injury with prevention of secondary injury to limit further sequelae are also covered. Medical complications which increase morbidity and mortality are also presented.

Cervical spine trauma associated with moderate and severe head injury: incidence, risk factors, and injury characteristics

OBJECT

Diagnosing and managing cervical spine trauma in head-injured patients is problematic due to an altered level of consciousness in such individuals. The reported incidence of cervical spine trauma in head-injured patients has generally ranged from 4 to 8%. In this retrospective study the authors sought to define the incidence of cervical injury in association with moderate or severe brain injury, emphasizing the identification of high-risk patients.

METHODS

The study included 447 consecutive moderately (209 cases) or severely (238 cases) head injured patients who underwent evaluation at two Level 1 trauma centers over a 40-month period. Of the 447 patients, 24 (5.4%) suffered a cervical spine injury (17 men and seven women; mean age 39 years; median Glasgow Coma Scale [GCS] score of 6, range 3-14). Of these 24 patients, 14 (58.3%) sustained spinal cord injuries (SCIs), 14 sustained injuries in the occiput-C3 region, and 10 underwent a stabilization procedure. Of the 14 patients with SCIs, nine experienced an early hypotensive and/or hypoxic insult. Regarding the mechanism of injury, cervical injuries occurred in 21 (8.2%) of 256 patients involved in motor vehicle accidents (MVAs), either as passengers or pedestrians, compared with three (1.6%) of 191 patients with non-MVA-associated trauma (p < 0.01). In the subset of 131 MVA passengers, 13 (9.9%) sustained cervical injuries. Patients with an initial GCS score less than or equal to 8 were more likely to sustain a cervical injury than those with a score higher than 8 (odds ratio [OR] 2.77, 95% confidence interval [CI] = 1.11-7.73) and were more likely to sustain a cervical SCI (OR 5.5, 95% CI 1.22-24.85). At 6 months or more postinjury, functional neurological recovery had occurred in nine patients (37.5%) and eight (33.3%) had died.

CONCLUSIONS

Head-injured patients sustaining MVA-related trauma and those with an initial GCS score less than or equal to 8 are at highest risk for concomitant cervical spine injury. A disproportionate number of these patients sustain high cervical injuries, the majority of which are mechanically unstable and involve an SCI. The development of safer and more rapid means of determining cervical spine integrity should remain a high priority in the care of head-injured patients.

Management of acute spinal cord injuries in an intensive care unit or other monitored setting

STANDARDS

There is insufficient evidence to support treatment standards.

GUIDELINES

There is insufficient evidence to support treatment guidelines.

OPTIONS

Management of patients with acute spinal cord injury, particularly patients with severe cervical level injuries, in an intensive care unit or similar monitored setting is recommended. Use of cardiac, hemodynamic, and respiratory monitoring devices to detect cardiovascular dysfunction and respiratory insufficiency in patients after acute cervical spinal cord injury is recommended.

Management of acute central cervical spinal cord injuries

STANDARDS

There is insufficient evidence to support treatment standards.

GUIDELINES

There is insufficient evidence to support treatment guidelines.

OPTIONS

Intensive care unit (or other monitored setting) management of patients with acute central cervical spinal cord injuries, particularly patients with severe neurological deficits, is recommended. Medical management, including cardiac, hemodynamic, and respiratory monitoring, and maintenance of mean arterial blood pressure at 85 to 90 mmHg for the first week after injury to improve spinal cord perfusion is recommended. Early reduction of fracture-dislocation injuries is recommended. Surgical decompression of the compressed spinal cord, particularly if the compression is focal and anterior, is recommended.

Spinal cord injury medicine. 1. Etiology, classification, and acute medical management

This self-directed learning module highlights basic management and approaches to intervention-both established and experimental. The revised American Spinal Injury Association classification (2000) of spinal cord injury (SCI) further defines the examination and classification guidelines. The incidence of traumatic SCI remains at approximately 10,000 cases per year, with 32 years the average age at injury. Initial management includes establishment of oxygenation, circulation (mean blood pressure >85 mm Hg), radiographic evaluations for spine instability, intravenous methylprednisolone, and establishment of spinal alignment. Prevention measures for medical complications include pressure relief for skin, thromboembolism prophylaxis, prevention of gastric ulcers, Foley catheter drainage to prevent urine retention, and bowel care to prevent colonic impaction. Nontraumatic SCI from spinal stenosis, neoplastic compression, abscess, or multiple sclerosis becomes more common with aging. Experimental treatments for SCI include antibodies to block axonal growth inhibitors, gangliosides to augment neurite growth, 4-aminopyridine to enhance axonal conduction through demyelinated nerve fibers, and fetal tissue to fill voids in cystic spinal cord cavities. Early comprehensive rehabilitation at a SCI center prevents complications and enhances functional gains.

OVERALL ARTICLE OBJECTIVE

To summarize the comprehensive evaluation and management of a newly injured individual.

Blood pressure management after acute spinal cord injury

STANDARDS

There is insufficient evidence to support treatment standards.

GUIDELINES

There is insufficient evidence to support treatment guidelines.

OPTIONS

Hypotension (systolic blood pressure <90 mmHg) should be avoided if possible or corrected as soon as possible after acute spinal cord injury. Maintenance of mean arterial blood pressure at 85 to 90 mmHg for the first 7 days after acute spinal cord injury to improve spinal cord perfusion is recommended.

Immediate spinal cord decompression for cervical spinal cord injury: feasibility and outcome

BACKGROUND

The effect of immediate surgical spinal cord decompression on neurologic outcome after spinal cord injury is controversial. Experimental models strongly suggest a beneficial effect of early decompression but there is little supportive clinical evidence. This study is designed to evaluate the feasibility and outcome of an immediate spinal cord decompression treatment protocol for cervical spinal cord injury in a tertiary treatment center.

METHODS

To address this issue, 91 consecutive patients with acute, traumatic cervical spinal cord injury (1990-1997) were prospectively studied. Sixty-six patients (protocol group) underwent emergency magnetic resonance imaging (MRI) to determine the presence of persistent spinal cord compression followed, if indicated, by immediate operative decompression and stabilization. Twenty-five patients were managed outside the treatment protocol because of contraindication to magnetic resonance imaging, need for other emergency surgical procedures, or admitting surgeon preference (reference group). The protocol and reference groups had similar sex and age distributions, admitting Frankel grades, levels of neurologic injury, and Injury Severity Scores.

RESULTS

Twenty-seven percent of patients seen were not enrolled in the treatment protocol because of the need for other emergent surgical treatment, contraindication to MRI, and specific surgeon bias regarding the "futility" of emergent treatment. The neurologic outcome for the patients in the reference group were similar to that in the previously reported literature. Fifty percent of protocol patients, compared with only 24% of reference patients, improved from their admitting Frankel grade. Eight protocol patients (12%), but no reference patients, improved from complete motor quadriplegia (Frankel grade A or B) to independent ambulation (Frankel grade D or E). Protocol patients required shorter intensive care unit stays, and shorter total hospital stays than reference patients. In the treatment protocol group, spinal cord decompression, confirmed by MRI, was achieved with immediate spinal column alignment and skeletal traction in 32 patients (46%). Thirty-four patients (54%) required emergent operative spinal cord decompression because of MRI-documented persistent spinal cord compression.

CONCLUSION

We conclude that immediate spinal column stabilization and spinal cord decompression, based on magnetic resonance imaging, may significantly improve neurologic outcome. The feasibility of such a treatment protocol in a tertiary treatment center is well demonstrated. Additional multicenter trials are necessary to achieve definitive conclusions regarding clinical efficacy.

Critical care of spinal cord injury

STUDY DESIGN

Review article.

OBJECTIVES

To review the pathophysiology and management of the pulmonary and hemodynamic derangements that occur after acute spinal cord injury.

SUMMARY OF BACKGROUND DATA

Acute spinal cord injury is often associated with alterations in pulmonary and cardiovascular function that require treatment in the intensive care unit.

METHODS

Review of published reports.

RESULTS/CONCLUSION

Careful attention to the support of the pulmonary and cardiovascular systems can reduce the morbidity associated with acute spinal cord injury. Pulmonary function decreases markedly in the immediate postinjury period but improves in the subsequent weeks, allowing most patients with injury levels at C4 and below to be weaned from ventilatory support. Bradycardia and hypotension often accompany acute spinal cord injury, and management strategies are reviewed. The prophylaxis and diagnosis of thromboembolic disease are reviewed.

The role and timing of decompression in acute spinal cord injury: what do we know? What should we do?

The management of acute spinal cord injury has traditionally concentrated on preventative measures as well as, for the better part of the previous century, conservative care. Pharmacologic interventions, in particular intravenous methylprednisolone therapy, have shown modest improvements in clinical trials and are still undergoing evaluation. More recent interest has focused on the role of surgical reduction and decompression, particularly "early" surgery. A review of the current evidence available in the literature suggests that there is no standard of care regarding the role and timing of surgical decompression. There are insufficient data to support overall treatment standards or guidelines for this topic. There are, however, Class II data indicating that early surgery (<24 hours) may be done safely after acute SCI. Furthermore, there are Class III data to suggest a role for urgent decompression in the setting of 1) bilateral facet dislocation and 2) incomplete spinal cord injury with a neurologically deteriorating patient. Whereas there is biologic evidence from experimental studies in animals that early decompression may improve neurologic recovery after SCI, the relevant time frame in humans remains unclear. To date, the role of decompression in patients with SCI is only supported by Class III and limited Class II evidence and accordingly can be considered only a practice option. Accordingly, there is a strong rationale to undertake prospective, controlled trials to evaluate the role and timing of decompression in acute SCI.