Determining the Incidence of Concomitant Traumatic Brain Injury in Patients With Acute Spinal Cord Injury: A 10-Year Cross-sectional Study.

Monocenter case-control study. Effects of spinal surgical adverse events (SSAE) on clinical and functional outcome, length of stay, and treatment costs after traumatic cervical spinal cord injury (SCI). Traumatic SCI is a challenge for primary care centers because of the emergency setting and complex injury patterns. SSAE rates of up to 15% are reported for spine fractures without SCI. Little is known about SSAE after traumatic SCI and their outcome relevance. Acute traumatic cervical SCI patients were enrolled from 2011 to 2017. Cases with and without SSAE were compared regarding neurological recovery, functional outcome, secondary complications, mortality, length of stay, and treatment costs. Adjusted logistic regression and generalized estimating equation models were calculated for the endpoints ASIA impairment scale (AIS)-conversion and dysphagia. All analyses were run in the total and in a propensity score matched sample. At least one SSAE occurred in 37 of 165 patients (22.4%). Mechanical instability and insufficient spinal decompression were the most frequent SSAE with 13 (7.9%) or 11 (6.7%) cases, respectively. The regression models adjusted for demographic, injury, and surgery characteristics demonstrated a reduced probability for AIS-conversion related to SSAE (OR [95% CI] 0.14 [0.03-0.74]) and additionally to single-sided ventral or dorsal surgical approach (0.12 [0.02-0.69]) in the matched sample. Furthermore, SSAE were associated with higher risk for dysphagia in the matched (4.77 [1.31-17.38]) and the total sample (5.96 [2.07-17.18]). Primary care costs were higher in cases with SSAE (median (interquartile range) 97,300 [78,200-112,300]) EUR compared with cases without SSAE (52,300 [26,700-91,200]) EUR. SSAE are an important risk factor after acute traumatic cervical SCI with impact on neurological recovery, functional outcome, and healthcare costs. Reducing SSAE is a viable means to protect the limited intrinsic capacity for recovery from SCI.Level of Evidence: 4.

Concomitant traumatic brain injury as a determinant of survival, and neurological and functional outcomes after traumatic spinal cord injury: A retrospective cohort study.

Objective To evaluate the clinical value of susceptibility- weighted imaging(SWI) in detecting intramedullary hemorrhage of traumatic acute spinal cord injury. Methods From October 2012 to December 2014, 37 TSCI (traumatic spinal cord injuries) patients undergone the MRI scans including routine MRI and SWI were enrolled. Further according to ASIA classification standard, all patients were evaluated as ASIA A (n=4), ASIA B (n=4), ASIA C (n=19) and ASIA D (n=10). Referring to axial T2WI images at the same slice, the manifestations of hemorrhage in amplitude image, phase image and SWI were evaluated. At the slice with maximal size of hemorrhage area and its neighboring slices, the hemorrhage regions were manually drawn; and the total area was automatically calculated. The number of hemorrhage lesions was defined as the number of hemorrhage lesions at single slice × slice number. One-way ANOVA was used to compare the differences among different grading ASIA in terms of hemorrhage area and number. Meanwhile, the relations between hemorrhage area and ASIA grade; hemorrhage number and ASIA grade were evaluated by Spearman rank correlation. Results The hemorrhage was detected by SWI in 15 patients, including 4 ASIA A, 4 ASIA B, 7 ASIA C. Hemorrhage represents as isointense in T1WI and a slightly low signal intensity or isointense in the center companied by high intensity at circus in T2WI. In magnitude image and SWI hemorrhage appears as low signal intensity and low signal intensity in the center companied by high intensity at circus in phase image. In detecting the hemorrhage, SWI (98 lesions were detected) was 5.4 times of T2WI (19 lesion were detected). As for the number of hemorrhage, significant differences were found among ASIA grading A, B and C (grading A: 22.5±1.3, grading B: 19.5±1.3, grading C: 4.0±1.1; F= 38.720, P<0.01); Further the pairwise comparison showed statistical significance (P<0.05); besides, the number of hemorrhage lesions closely related with the ASIA grade (r=0.864, P<0.01). For the hemorrhage area, the calculated results of grading ASIA A, B and C were (23.5 ± 0.6), (21.8 ± 1.9), (3.9 ± 0.7) mm2, respectively; there were significant differences among the different ASIA grades (F=29.987, P<0.001); furthermore the hemorrhage area also showed closely relation with the ASIA grade (r=0.778, P<0.01). Conclusions SWI is more sensitive in detecting the hemorrhage in traumatic acute spinal cord injury. The more number and area of bleeding area suggest the more severe of the damage level. Key words: Spinal cord injuries; Magnetic resonance imaging; Hemorrhage

Background Concomitant traumatic brain injury with spinal cord injury is likely to worsen prognosis and increase hospital length of stay. This study assessed the duration of in-patient rehabilitation and outcome in patients with both traumatic brain injury and spinal cord injury. Methods Retrospective study of all patients with concomitant traumatic brain injury and spinal cord injury over a 3-year period who had 5 years of subsequent follow-up at the Midlands Centre for Spinal Injuries. Results Twenty-seven patients had concomitant injuries of which five had severe traumatic brain injury, nine had moderate traumatic brain injury and the remaining thirteen had mild traumatic brain injury with spinal cord injury of grades A–D; commonest mechanisms of injury were motor vehicle collision (55%) and falls (37%). Thirteen (48%) had tetraplegia and 14 (52%) had paraplegia. Mean functional independence measure score at admission was 52.1 and 103.4 at 5 years. Patients with mild traumatic brain injury gained a mean functional independence measure score of 67.1; the moderate and severe traumatic brain injury patients gained mean functional independence measure score of 60.1 and 69.2, respectively. The mean length of stay was 138.3, 139.4 and 153.4 days for mild, moderate and severe traumatic brain injury, respectively. Conclusion Hospital length of stay and patient’s functioning at 5 years were not affected by traumatic brain injury severity in this subgroup; however, functional independence measure on its own may not be very sensitive to cognitive deficits.

To determine the frequency of missed acute care traumatic brain injury diagnoses in patients with traumatic spinal cord injury, and to examine risk factors for missed traumatic brain injury diagnosis. Prospective magnetic resonance imaging and neuro-psychological assessment plus retrospective medical record review, including computed tomography. Ninety-two adults with traumatic spinal cord injury recruited from a large, tertiary spinal cord injury program, initially referred from urban teaching hospitals with neurotrauma facilities. Diagnosis of traumatic brain injury made with clinical neurological indices (i.e., Glasgow Coma Scale, post-traumatic amnesia, and loss of consciousness), neuroimaging (computed tomography and structural magnetic resonance imaging), and neuropsychological tests of attention and speed of processing, memory, and executive function; all measures were validated on a case-by-case basis to rule out confounds. Missed traumatic brain injury diagnoses were made via acute care medical record review and were corroborated by patient/family report where possible. The frequency of missed traumatic brain injury diagnoses in our sample was 58.5%. Missed traumatic brain injury diagnoses were more frequent in injuries sustained outside of a motor vehicle collision (MVC), with 75.0% of acute care traumatic brain injury diagnoses missed in non-MVC patients vs. 42.9% missed in MVC patients. Among patients with non-MVC injuries, a comparable percentage of missed traumatic brain injury diagnoses were observed in patients with cervical (79%) and sub-cervical injuries (80%). In more than half of the traumatic spinal cord injury patients referred for in-patient rehabilitation, acute care diagnoses of traumatic brain injury were missed. A risk factor for missed diagnosis was an injury caused by a mechanism other than an MVC (e.g., falls, assaults), perhaps due to reduced expectations of traumatic brain injury in non-MVC patients. In our research study, we employed multiple assessments to aid diagnosis, which is particularly important for detecting the milder traumatic brain injuries often associated with spinal cord injury; unfortunately, limited resources may preclude a comprehensive diagnostic approach in clinical settings. Our findings point to the need to examine current acute care diagnostic protocols, and to increase vigilance in patients with traumatic injuries sustained outside of an MVC setting.

Hypothermia for spinal cord injury

Acute traumatic spinal cord injury (SCI) can result in severe, lifelong neurological deficits. After SCI, Rho activation contributes to collapse of axonal growth cones, failure of axonal regeneration, and neuronal loss. This randomized, double-blind, placebo-controlled phase 2b/3 study evaluated the efficacy and safety of Rho inhibitor VX-210 (9 mg) in patients after acute traumatic cervical SCI. The study enrolled patients 14–75 years of age with acute traumatic cervical SCIs, C4–C7 (motor level) on each side, and American Spinal Injury Association Impairment Scale (AIS) Grade A or B who had spinal decompression/stabilization surgery commencing within 72 h after injury. Patients were randomized 1:1 with stratification by age (<30 vs. ≥30 years) and AIS grade (A vs. B with sacral pinprick preservation vs. B without sacral pinprick preservation). A single dose of VX-210 or placebo in fibrin sealant was administered topically onto the dura over the site of injury during decompression/stabilization surgery. Patients were evaluated for medical, neurological, and functional changes, and serum was collected for pharmacokinetics and immunological analyses. Patients were followed up for up to 12 months after treatment. A planned interim efficacy-based futility analysis was conducted after ∼33% of patients were enrolled. The pre-defined futility stopping rule was met, and the study was therefore ended prematurely. In the final analysis, the primary efficacy end-point was not met, with no statistically significant difference in change from baseline in upper-extremity motor score at 6 months after treatment between the VX-210 (9-mg) and placebo groups. This work opens the door to further improvements in the design and conduct of clinical trials in acute SCI.

Outcomes comparative analysis of concurrent traumatic brain injury and traumatic spinal cord injury versus isolated traumatic brain injury and isolated traumatic spinal cord injury.

The first objective was to identify a method for early prediction of independent outdoor functional walking 1 yr after a traumatic spinal cord injury using the motor and sensory function derived from the International Standards for Neurological Classification of Spinal Cord Injury assessment during acute care. Then, the second objective was to develop a clinically relevant prediction rule that would be accurate, easy to use, and quickly calculated in clinical setting. A prospective cohort of 159 traumatic spinal cord injury patients was analyzed. Bivariate correlations were used to determine the assessment method of motor strength and sensory function as well as the specific dermatomes and myotomes best associated with independent outdoor functional walking 1 yr after injury. An easy-to-use clinical prediction rule was produced using a multivariable linear regression model. The highest motor strength for a given myotome (L3 and L5) and preserved light touch sensation (dermatome S1) were the best predictors of the outcome. The proposed prediction rule displayed a sensitivity of 84.21%, a specificity of 85.54%, and a global accuracy of 84.91% for classification. After an acute traumatic spinal cord injury, accurately predicting the ability to walk is challenging. The proposed clinical prediction rule aims to enhance previous work by identifying traumatic spinal cord injury patients who will reach a mobility level that fosters social participation and quality of life in the chronic period after the injury. Complete the self-assessment activity and evaluation online at http://www.physiatry.org/JournalCME. Upon completion of this article, the reader should be able to: (1) Revise the different motor and sensory function assessment methods used for prognostication of walking after an acute traumatic spinal cord injury; (2) Identify clinical factors that are significantly associated with functional walking 1 yr after a traumatic spinal cord injury; and (3) Accurately estimate the likelihood of reaching independent outdoor functional walking in the chronic phase after an acute traumatic spinal cord injury. Advanced. The Association of Academic Physiatrists is accredited by the Accreditation Council for Continuing Medical Education to provide continuing medical education for physicians. The Association of Academic Physiatrists designates this Journal-based CME activity for a maximum of 1.0 AMA PRA Category 1 Credit(s)™. Physicians should only claim credit commensurate with the extent of their participation in the activity.

Retrospective cohort study. To assess the impact of concomitant traumatic brain injury (TBI) on demographic data, injury characteristics, management choices, access to optimal care, and clinical, neurological and functional outcomes after acute traumatic spinal cord injury (tSCI). 18 acute care centers and 12 rehabilitation facilities across Canada. Data for the study was selected from the Rick Hansen Spinal Cord Injury Registry (RHSCIR) from 2004 to 2020 in Canada. The tSCI-alone group was compared with the tSCI+TBI group regarding injury epidemiology, management, and outcomes post-tSCI. There were 966 individuals with tSCI+TBI and 3520 individuals with tSCI alone. The latter included older and more predominantly White individuals who typically sustained a less severe tSCI, less often at cervical levels due to falls. While need for surgical spinal cord decompression and spine stabilization was more common in the tSCI-alone group (p = 0.0087), mechanical ventilation was more often required in the tSCI+TBI group (p < 0.0001). In-hospital mortality rate, length of stay in the acute care and rehabilitation centers were greater in the tSCI+TBI group (p < 0.0001). However, both groups had similar changes in the motor scores from admission to discharge from the hospital (p = 0.6096). While both groups had similar frequencies of pain (p = 0.9848), spasticity was more frequent in the tSCI+TBI group (p < 0.0001). Our results underscore significant differences between the tSCI+TBI group and the SCI-alone group regarding the injury epidemiology, management and outcomes. Those results suggest that concomitant TBI should be considered a major potential confounder in future SCI research studies.

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Retrospective cohort study. To evaluate influence of age after traumatic spinal cord injury (TSCI). 13 specialized hospitals with neurosurgical departments of Saint Petersburg, Russia. Charts of all patients admitted with TSCI to the city hospitals 2012-2016. Demographic and clinical characteristics, surgical interventions, complications, mortality rate, and hospital stays were recorded. 311 patients with TSCI were included. TSCI was more common in younger age. Mean age (SD) was 42.4 (16.8) years. Patients were divided into four age groups: 18-29, 30-44, 45-59 and ≥60 years. The group ≥60 years had the lowest percentage of concomitant traumatic brain injury (TBI), 25%, versus 43% in TSCI < 60 years, p < 0.05. Low falls were the most frequent cause in patients aged 60 years and older, and led to less severe neurological deficits (p < 0.05). Complications were most frequent in motor complete TSCI (AIS A and AIS B) and in persons with combined TSCI and TBI at older age. Total complication rate was 67% at the age of ≥60 years versus 38% <60 years in TSCI with TBI (p < 0.05). Respiratory complications occurred in 67% ≥45 years versus 45% <45 years, p < 0.05. In-hospital mortality rate after TSCI was higher in the oldest age group. Respiratory complications are common and the in-hospital mortality is higher among elderly people. Older patients with TSCI and TBI are at high risk for complications.

Growing evidence supports prompt surgical decompression for patients with traumatic spinal cord injury (tSCI). Rates of concomitant tSCI and traumatic brain injury (TBI) range from 10% to 30%. Concomitant TBI may delay tSCI diagnosis and surgical intervention. Little is known about real-world management of this common injury constellation that carries significant clinical consequences. This study aimed to quantify the impact of concomitant TBI on surgical timing in a national cohort of patients with tSCI. Patient data were obtained from the National Trauma Data Bank (2007-2016). Patients admitted for tSCI and who received surgical intervention were included. Delayed surgical intervention was defined as surgery after 24 hours of admission. Multivariable hierarchical regression models were constructed to measure the risk-adjusted association between concomitant TBI and delayed surgical intervention. Secondary outcome included favorable discharge status. We identified 14 964 patients with surgically managed tSCI across 377 North American trauma centers, of whom 2444 (16.3%) had concomitant TBI and 4610 (30.8%) had central cord syndrome (CCS). The median time to surgery was 20.0 hours for patients without concomitant TBI and 24.8 hours for patients with concomitant TBI. Hierarchical regression modeling revealed that concomitant TBI was independently associated with delayed surgery in patients with tSCI (odds ratio [OR], 1.3; 95% CI, 1.1-1.6). Although CCS was associated with delayed surgery (OR, 1.5; 95% CI, 1.4-1.7), we did not observe a significant interaction between concomitant TBI and CCS. In the subset of patients with concomitant tSCI and TBI, patients with severe TBI were significantly more likely to experience a surgical delay than patients with mild TBI (OR, 1.4; 95% CI, 1.0-1.9). Concomitant TBI delays surgical management for patients with tSCI. This effect is largest for patients with tSCI with severe TBI. These findings should serve to increase awareness of concomitant TBI and tSCI and the likelihood that this may delay time-sensitive surgery.

Retrospective cohort study. We studied complications during early rehabilitation and their relation to length of stay (LOS) in the hospital as well as to survival in people with traumatic spinal cord injury (TSCI). All specialized hospitals of Saint Petersburg. We analysed all charts of patients admitted with acute TSCI to the city hospitals, 2012-2016. Patient characteristics, complications, time and cause of death, and LOS were recorded. Mean values with standard deviations and t-tests were used. We analysed mortality rate using the Kaplan-Meier method and calculated relative risks (RRs). A total of 311 patients with TSCI were included. Complications occurred in 34% of patients; most were respiratory complications and pressure ulcers. Complications occurred more often in those with concomitant traumatic brain injury (TBI) (RR = 1.4, 95% CI: 1.2-1.8). All complications prolonged LOS (median, 11 days) and increased mortality in the acute phase (p < 0.001). In the early phase, 15% died, with a median time to death of 13 days. Respiratory complications markedly increased the death rate (RR = 18, 95% CI: 15-22). Mortality rate correlated also with age, TSCI severity and level, and concomitant TBI. Alcohol/drug consumption before TSCI increased the likelihood for complications (RR = 1.7, 95% CI: 1.3-2.1) and mortality (RR = 2.2, 95% CI: 1.6-3.1). Focus on prevention as well as early and optimal treatment of complications, together with no or low alcohol/drug consumption may reduce mortality in the early phase after TSCI and at the same time shorten LOS.

Results of Early and Late Surgical Decompression and Stabilization for Acute Traumatic Cervical Spinal Cord Injury in Patients with Concomitant Chest Injuries