Injuries to the spinal cord may be associated with increased healing of fractures. This can be of benefit, but excessive bone growth can also cause considerable adverse effects. We evaluated two groups of patients with fractures of the spinal column, those with neurological compromise (n = 10) and those without (n = 15), and also a control group with an isolated fracture of a long bone (n = 12). The level of transforming growth factor-beta (TGF-β), was measured at five time points after injury (days 1, 5, 10, 42 and 84). The peak level of 142.79 ng/ml was found at day 84 in the neurology group (p < 0.001 vs other time points). The other groups peaked at day 42 and had a decrease at day 84 after injury (p ≤ 0.001). Our findings suggest that TGF-β may have a role in the increased bone turnover and attendant complications seen in patients with acute injuries to the spinal cord

We have reviewed 59 patients with injury to the spinal cord to assess the predictive value of the sparing of sensation to pin prick in determining motor recovery in segments which initially had MRC grade-0 power. There were 35 tetraplegics (18 complete, 17 incomplete) and 24 paraplegics (19 complete, 5 incomplete), and the mean follow-up was 29.6 months. A total of 114 motor segments initially had grade-0 power but sparing of sensation to pin prick in the corresponding dermatome. Of these, 97 (85%) had return of functional power (≥ grade 3) at follow-up. There were 479 motor segments with grade-0 power but no sparing of sensation to pin prick and of these only six (1.3%) had return of functional power. Both of the above associations were statistically significant (chi-squared test, p < 0.0001). After injury to the spinal cord, the preservation of sensation to pin prick in a motor segment with grade-0 power indicated an 85% chance of motor recovery to at least grade 3

Injury to the spinal cord without radiological abnormality often occurs in the skeletally immature cervical and thoracic spine. We describe four adult patients with this diagnosis involving the cervical spine with resultant quadriparesis. The relevant literature is reviewed. The implications for initial management of the injury, the role of MRI and the need for a high index of suspicion are highlighted

Summary Statement. The spinal cord showed marked sensibility to acute compression causing complete and irreversible injury. On the contrary, the spinal cord has more ability for adaptation to slow progressive compression mechanisms having the possibility of neural recovery after compression release. Introduction. The aim of this experimental study was to establish, by means of neurophysiologic monitoring, the degree of compression needed to cause neurologic injury to the spinal cord, and analyze whether these limits are different making fast or slow compression. Material and Methods. Spinal cord was exposed from T7 to T11 in 5 domestic pigs with a mean weight of 35 kg. The T8 and T9 spinal roots were also exposed. A pair of sticks, attached to a precise compression device, was set up to both sides of the spinal cord between T8 and T9 roots. Sequentially, the sticks were approximated 0.5 mm every 2 minutes causing progressive spinal cord compression. An acute compression of the spinal cord was also reproduced by a 2.5 mm displacement of the sticks. Cord to cord motor evoked potentials were obtained with two epidural catheters, stimulating proximal to T6 and recording below the compression level, distal to T10, for each sequential approach of the sticks. Results. The mean width of the dural sac was 7.1 mm. For progressive compression, increasing latency and decreasing amplitude of the evoked potentials were observed after a mean displacement of the sticks of 3.2 ± 0.9 mm, the evoked potential finally disappearing after a mean displacement of 4.6 ± 1.2 mm. The potential returned 16.8 ± 3.2 minutes after the compression was stopped in every case. The evoked potentials immediately disappeared after an acute compression 2.5 ± 0.3 mm, without any sign of recovering after 30 minutes. Conclusion. The proposed experimental model replicates the mechanism of a spinal cord injury caused by medially displaced screws into the spinal canal, causing therefore lateral compression to the spinal cord. The spinal cord showed marked sensibility to acute compression, which caused complete and irreversible injury. On the contrary, the spinal cord has more ability for adaptation to progressive and slow compression mechanisms. From a clinical point of view, it seems mandatory to avoid maneuvers of rapid mobilization or acute, even minimal, contusions of the thoracic cord

There are many causes of paraspinal muscle weakness which give rise to the dropped-head syndrome. In the upper cervical spine the central portion of the spinal cord innervates the cervical paraspinal muscles. Dropped-head syndrome resulting from injury to the central spinal cord at this level has not previously been described. We report two patients who were treated acutely for this condition. Both presented with weakness in the upper limbs and paraspinal cervical musculature after a fracture of C2. Despite improvement in the strength of the upper limbs, the paraspinal muscle weakness persisted in both patients. One ultimately underwent cervicothoracic fusion to treat her dropped-head syndrome. While the cause of the dropped-head syndrome cannot be definitively ascribed to the injuries to the spinal cord, this pattern is consistent with the known patho-anatomical mechanisms of both injury to the central spinal cord and dropped-head syndrome

A case of cervical traumatic paraplegia is described in which there was no evidence of damage to vertebrae, discs or ligaments. Experimental evidence suggests that such injuries may be caused by inward bulging of the ligamentum flavum during hyperextension. The reasons why this inward bulging may occur, despite the elasticity of the ligamentum flavum, are discussed. Treatment of such cases is considered and the importance of avoiding extension emphasised.

Initial treatment of traumatic spinal cord injury remains as controversial in 2023 as it was in the early 19th century, when Sir Astley Cooper and Sir Charles Bell debated the merits or otherwise of surgery to relieve cord compression. There has been a lack of high-class evidence for early surgery, despite which expeditious intervention has become the surgical norm. This evidence deficit has been progressively addressed in the last decade and more modern statistical methods have been used to clarify some of the issues, which is demonstrated by the results of the SCI-POEM trial. However, there has never been a properly conducted trial of surgery versus active conservative care. As a result, it is still not known whether early surgery or active physiological management of the unstable injured spinal cord offers the better chance for recovery. Surgeons who care for patients with traumatic spinal cord injuries in the acute setting should be aware of the arguments on all sides of the debate, a summary of which this annotation presents. Cite this article: Bone Joint J 2023;105-B(4):347–355

High-pressure injection injuries occur infrequently but are usually work-related and involve the non-dominant hand. The neck is a very rare site for such an injury. We describe the management of a 36-year-old man with a high-pressure grease-gun injection injury to his neck causing a cervical spinal cord injury. He developed severe motor and sensory changes which were relieved by surgical removal of the grease through anterior and posterior approaches

This review provides a concise outline of the advances made in the care of patients and to the quality of life after a traumatic spinal cord injury (SCI) over the last century. Despite these improvements reversal of the neurological injury is not yet possible. Instead, current treatment is limited to providing symptomatic relief, avoiding secondary insults and preventing additional sequelae. However, with an ever-advancing technology and deeper understanding of the damaged spinal cord, this appears increasingly conceivable. A brief synopsis of the most prominent challenges facing both clinicians and research scientists in developing functional treatments for a progressively complex injury are presented. Moreover, the multiple mechanisms by which damage propagates many months after the original injury requires a multifaceted approach to ameliorate the human spinal cord. We discuss potential methods to protect the spinal cord from damage, and to manipulate the inherent inhibition of the spinal cord to regeneration and repair. Although acute and chronic SCI share common final pathways resulting in cell death and neurological deficits, the underlying putative mechanisms of chronic SCI and the treatments are not covered in this review

The June 2013 Spine Roundup. 360 . looks at: the benefit of MRI in the follow-up of lumbar disc prolapse; gunshot injury to the spinal cord; the link between depression and back pain; floating dural sack sign; short segment fixation at ten years; whether early return to play is safer than previously thought; infection in diabetic spinal patients; and dynesis

Summary Statement. In this study, we observed that MR16-1, an interleukin-6 inhibitor, recovered phosphatidylcholine containing docosahexaenoic acid at the injury site after spinal cord injury in mice model by using imaging mass spectrometry. Introduction. The current drugs for improving motor function of the limbs lost due to spinal cord injury (SCI) are ineffective. Development of new drugs for spinal cord injury is desired. MR16-1, an interleukin-6 inhibitor, is found to be effective in improving motor function after spinal cord injury in mice model. Thus, we examined the molecular mechanism in more detail. Therefore, the purpose of this study was to analyze the molecular changes in the spinal cord of the SCI mice treated with MR16-1 using imaging mass spectrometry. Methods. All experiments were performed according to the guidelines for animal experimentation and care and use of laboratory animals established by Hamamatsu University School of Medicine (Shizuoka, Japan). We used 36 adult female C57BL/6J mice for laminectomy and contusion injury of the spinal cord that were performed at the T10 level using the Infinite Horizon Impactor (IH Impactor, 60 kdyn; Muromachi, Tokyo, Japan). Immediately after SCI, mice were intraperitoneally injected with a single dose of MR16-1 (Chugai, Tokyo Japan) (100 µg/g body weight, MR16-1 group) or a single dose of phosphate-buffered saline (PBS) of the same volume (control group). Motor function of the hind limbs was evaluated using the Basso Mouse Scale (BMS), an open-field locomotor test in which the scores range from 0 points (scored for no ankle movement) to 9 points (scored for complete functional recovery). BMS scores were recorded at 1, 7, 14, 21, 28, 35, and 42 days after SCI. The spinal cord tissues were flash frozen and were sliced to a thickness of 8 µm using a cryostat (CM1950; Leica, Wetzler, Germany). Imaging mass spectrometry was used to visualise 12 molecular species of phosphatidylcholine (PC) from thin slices of the spinal cords obtained at 7 days post-SCI. Results. The contusive SCI immediately resulted in complete paralysis. The MR16-1–treated group showed a significant improvement in the BMS locomotor score compared with the control group at both 7 days and 42 days after SCI (1.4 vs 0.2 points and 4.0 vs 1.4 points, respectively). Phospholipids at 7 days after SCI showed unique distribution patterns. In particular, PCs containing docosahexaenoic acid (DHA) localised in the gray matter region was significantly higher in the MR16-1–treated group than in the control group, at 7 days post-SCI. Discussion. MR16-1 treatment showed to improve locomotor BMS score after 7 days of SCI compared with that observed in the control group. Spinal cord injury had induced inflammation; injury sites showed changes in the lipid content. We had previously reported that PC containing DHA mostly expressed in neuron cells decrease on injury sites. In this study, we observed that MR16-1 recovered PC containing DHA at the injury site. This may be associated with the recovery of motor function

Injury to the spinal cord and kyphosis are the two most feared complications of tuberculosis of the spine. Since tuberculosis affects principally the vertebral bodies, anterior decompression is usually recommended. Concomitant posterior instrumentation is indicated to neutralise gross instability from panvertebral disease, to protect the anterior bone graft, to prevent graft-related complications after anterior decompression in long-segment disease and to correct a kyphosis. Two-stage surgery is usually performed in these cases. We present 38 consecutive patients with tuberculosis of the spine for whom anterior decompression, posterior instrumentation, with or without correction of the kyphus, and anterior and posterior fusion was performed in a single stage through an anterolateral extrapleural approach. Their mean age was 20.4 years (2.0 to 57.0). The indications for surgery were panvertebral disease, neurological deficit and severe kyphosis. The patients were operated on in the left lateral position using a ‘T’-shaped incision sited at the apex of kyphosis or lesion. Three ribs were removed in 34 patients and two in four and anterior decompression of the spinal cord was carried out. The posterior vertebral column was shortened to correct the kyphus, if necessary, and was stabilised by a Hartshill rectangle and sublaminar wires. Anterior and posterior bone grafting was performed. The mean number of vertebral bodies affected was 3.24 (2.0 to 9.0). The mean pre-operative kyphosis in patients operated on for correction of the kyphus was 49.08° (30° to 72°) and there was a mean correction of 25° (6° to 42°). All except one patient with a neural deficit recovered complete motor and sensory function. The mean intra-operative blood loss was 1175 ml (800 to 2600), and the mean duration of surgery 3.5 hours (2.7 to 5.0). Wound healing was uneventful in 33 of 38 patients. The mean follow-up was 33 months (11 to 74). None of the patients required intensive care. The extrapleural anterolateral approach provides simultaneous exposure of the anterior and posterior aspects of the spine, thereby allowing decompression of the spinal cord, posterior stabilisation and anterior and posterior bone grafting. This approach has much less morbidity than the two-stage approaches which have been previously described

This study assessed the frequency of acute injury to the spinal cord in Irish Rugby over a period of ten years, between 1995 and 2004. There were 12 such injuries; 11 were cervical and one was thoracic. Ten occurred in adults and two in schoolboys. All were males playing Rugby Union and the mean age at injury was 21.6 years (16 to 36). The most common mechanism of injury was hyperflexion of the cervical spine and the players injured most frequently were playing at full back, hooker or on the wing. Most injuries were sustained during the tackle phase of play. Six players felt their injury was preventable. Eight are permanently disabled as a result of their injury

Posterior cervical wiring is commonly performed for patients with spinal instability, but has inherent risks. We report eight patients who had neurological deterioration after sublaminar or spinous process wiring of the cervical spine; four had complete injuries of the spinal cord, one had residual leg spasticity and three recovered after transient injuries. We found no relation between the degree of spinal canal encroachment and the severity of the spinal-cord injury, but in all cases neurological worsening appeared to have been caused by either sublaminar wiring or spinous process wiring which had been placed too far anteriorly. Sublaminar wiring has substantial risks and should be used only at atlantoaxial level, and then only after adequate reduction. Fluoroscopic guidance should be used when placing spinous process wires especially when the posterior spinal anatomy is abnormal

We studied a consecutive series of 58 patients with penetrating missile injuries of the brachial plexus to establish the indications for exploration and review the results of operation. At a mean of 17 weeks after the initial injury, 51 patients were operated on for known or suspected vascular injury (16), severe persistent pain (35) or complete loss of function in the distribution of one or more elements of the brachial plexus (51). Repair of the nerve and vascular lesions abolished, or significantly relieved, severe pain in 33 patients (94%). Of the 36 patients who underwent nerve graft of one or more elements of the plexus, good or useful results were obtained in 26 (72%). Poor results were observed after repairs of the medial cord and ulnar nerve, and in patients with associated injury of the spinal cord. Neurolysis of lesions in continuity produced good or useful results in 21 of 23 patients (91%). We consider that a vigorous approach is justified in the treatment of penetrating missile injury of the brachial plexus. Primary intervention is mandatory when there is evidence of a vascular lesion. Worthwhile results can be achieved with early secondary intervention in patients with debilitating pain, failure to progress and progression of the lesion while under observation. There is cause for optimism in nerve repair, particularly of the roots C5, C6 and C7 and of the lateral and posterior cords, but the prognosis for complete lesions of the plexus associated with damage to the cervical spinal cord is particularly poor

Aims: To identify the incidence of neurological deþcit and functional outcome following displaced acetabular fractures. Methods: We carried out a prospective study of 136 patients who underwent skeletal stabilization of displaced acetabular fractures. Patients with sciatic nerve injuries were identiþed, assessed and followed up clinically. Routine EMG and nerve conduction studies were performed post-operatively on all cases with clinical proven neurological lesions to correlate the level, severity of the lesion and monitor progress of recovery. Results: 27 patients (19.8%) have neurological deþcit identiþed preoperatively. In 12 patients where the femoral heads were dislocated posteriorly. 20 were male and 7 were female. The mean age was 33.8 years (range 16–66). 15 patients had associated injuries but none of the patients had injury to the spinal cord. The mean ISS was 12.6 (range 9–34). The mean follow up was 3.4 years (range 1.5–6 years). 13 patients with complete drop foot at presentation. 9 patients had EMG proven double crush lesion. 3 patients had ipsilateral knee injury. 2 patients had intraopearative iatrogenic injury. All 9 patients with double crush syndrome have no improvement in function. Conclusions: Acetabular fractures associated with sciatic nerve injuries are devastating injuries with signiþcant long term morbidity. 50% patients showed improvement with time. Identiþcation of double crush lesion is vital as it is associated with poorer functional recovery as compared to single lesion

Purpose: Recent studies have examined the systemic inflammation that occurs following spinal cord injury (SCI) (Gris et al. 2008). It is believed that this systemic inflammation plays a role in the respiratory, renal and hepatic morbidity of SCI patients, ultimately contributing to mortality post-injury. Evidence of this inflammatory response has been shown as early as two hours post SCI (Gris et al. 2008) Intravital microscopy is a powerful tool for assessing inflammation acutely and in ‘real-time’ (Brock et al. 1999). This tool would be useful for demonstrating the acuteness of a systemic inflammatory response post-SCI, and for assessing the degree of inflammation to different severities of SCI. The liver has been shown to play a particularly important role in the initiation and progression of the early systemic inflammatory response to spinal cord injury (SCI), therefore the purpose was to evaluate hepatic inflammation immediately after SCI. We hypothesized that SCI would cause immediate leukocyte recruitment and that the magnitude of inflammation would increase with increasing severity of cord injury. Method: Male Wistar rats (200–225g) were randomly assigned to one of the following groups: uninjured, trauma-injured (laminectomy and no cord injury), cord compressed or cord transected. Spinal cord-injured rats were anesthetized by isoflurane, a dorsal laminectomy was performed, and the 4th thoracic spinal segment was injured by a moderately severe clip-compression injury or by a severe complete cord transection injury. Uninjured rats and trauma-injured rats served as controls. At 0.5 and 1.5 h after SCI rats had the left lobe of their livers externalized and visualized using intravital video microscopy. Results: At 0.5 hours the total number of leukocytes per post-sinusoidal venule was significantly increased after cord compression and cord transection compared to that in uninjured and trauma-injured rats (P< 0.05). Of these leukocytes significantly more were either adherent or rolling along venule walls compared to uninjured and trauma-injured rats (P< 0.05). Of the rolling leukocytes 2–fold more were observed after cord transection compared to cord compression. At 1.5 h the total number of leukocytes per post-sinusoidal venule and the number of adherent leukocytes was significantly increased only after cord transection. Conclusion: Injury to the spinal cord but not trauma alone causes immediate leukocyte recruitment to the liver within 0.5 h after injury. Also, leukocyte recruitment increases with increasing severity of injury. This is the first study to use intravital microscopy to visualize systemic inflammation in the liver following SCI

Introduction: This is a report on results from the first three years of the British Spinal Registry. Background: The British Scoliosis Society supported a web based scoliosis registry in 2003. At the Britspine meeting in 2004 all four British spine societies (BSS, BASS, BCSS, SBPR) agreed to expand this to include all spinal surgical procedures in the United Kingdom. An extensive marketing and promotional campaign was targeted at all members of the four societies, and online and telephone support was provided. Aims: To report on the clinical results from the first three years registry activity. Methods: The British Spinal Registry is a web based out-come tool, collecting basic demographic and outcome data on spinal surgical procedures in the UK. Over three years from November 2004, 1410 patient data sets were entered. The activity analysis is party carried out using the online diagnostics that are part of the web based software tool, and partly with downloaded data. Results: 73 surgeons from 55 centres entered patient data on 1410 surgical episodes between November 2004 and December 2007. The number of patients entered per year has declined marginally, with 540 patients in the first year, 454 in the second and 416 in the third. The majority of cases entered have a low back diagnosis (842) of whom 106 were part of a BASS audit on discectomy. Of the low back cases 40% had disc herniation and 7.4% had previous surgery. The complications included dural tear (3.7%), nerve root injury (0.4%) and infection (1.1%). The BASS study showed that 70% of UK surgeons were not using intraoperative radiographic localisation of surgical level. There were 448 deformity cases, and of these 223 were idiopathic scoliosis, 49 neuromuscular and 20 congenital. 57% had posterior surgery, 20% anterior and 23% combined. There were no intraoperative deaths, no complete spinal cord injuries, 4 partial spinal cord injuries (0.9%), 6 deep infections (1.3%) and 14 implant revisions (3.1%). Conclusion: The initial clinical results from the British Spinal Registry support the hypothesis that such registries can produce useful audit data. There is no other record nationally of number and type of procedures in spinal surgery in the UK. The complication rates are similar to those reported elsewhere and provide an opportunity for benchmarking and for comparative personal and centre audit. The uptake and usage rates however are low and would not allow scientifically valid clinical results to be reported

Aims. The aim of this study was to determine whether early surgical treatment results in better neurological recovery 12 months after injury than late surgical treatment in patients with acute traumatic spinal cord injury (tSCI). Methods. Patients with tSCI requiring surgical spinal decompression presenting to 17 centres in Europe were recruited. Depending on the timing of decompression, patients were divided into early (≤ 12 hours after injury) and late (> 12 hours and < 14 days after injury) groups. The American Spinal Injury Association neurological (ASIA) examination was performed at baseline (after injury but before decompression) and at 12 months. The primary endpoint was the change in Lower Extremity Motor Score (LEMS) from baseline to 12 months. Results. The final analyses comprised 159 patients in the early and 135 in the late group. Patients in the early group had significantly more severe neurological impairment before surgical treatment. For unadjusted complete-case analysis, mean change in LEMS was 15.6 (95% confidence interval (CI) 12.1 to 19.0) in the early and 11.3 (95% CI 8.3 to 14.3) in the late group, with a mean between-group difference of 4.3 (95% CI -0.3 to 8.8). Using multiply imputed data adjusting for baseline LEMS, baseline ASIA Impairment Scale (AIS), and propensity score, the mean between-group difference in the change in LEMS decreased to 2.2 (95% CI -1.5 to 5.9). Conclusion. Compared to late surgical decompression, early surgical decompression following acute tSCI did not result in statistically significant or clinically meaningful neurological improvements 12 months after injury. These results, however, do not impact the well-established need for acute, non-surgical tSCI management. This is the first study to highlight that a combination of baseline imbalances, ceiling effects, and loss to follow-up rates may yield an overestimate of the effect of early surgical decompression in unadjusted analyses, which underpins the importance of adjusted statistical analyses in acute tSCI research. Cite this article: Bone Joint J 2023;105-B(4):400–411

Purpose: To document the incidence of neurological lesions and functional outcome following displaced acetabular fractures. Patients and Methods: Prospective review of patients who underwent stabilisation of acetabular fractures in a University Hospital trauma centre. From December 1994 to November 2000 136 patients were identified with acetabular fractures. The open reduction and internal fixation of the acetabular fixation was performed by standard operative techniques. The time from the initial injury to the operation ranged from 24 hours to I4days. Patients with sciatic nerve injuries were prospectively followed up and long-term outcome recorded. Weakness or absence of dorsiflexion or plantar flexion was graded according to the standard Medical Research Council. Abnormalities of sensation, including absent or diminished sensation to light touch and pinprick as well as dysesthesia or hyperesthesia of the dorsal and plantar aspects of the foot were recorded. None of the patients had an injury of the spinal cord. Intra-operative monitoring was performed in most cases, and routine electromyography and nerve -conduction studies were done post-operatively and at least on one more occasion to record the level and severity of the lesion and to monitor progress of recovery. All the patients were followed up clinically in the trauma clinics and functional improvement was routinely assessed. The mean follow up of the patients was 3.4 years (range 1.5–6 years). Results: Out of 136 patients who underwent stabilisation of acetabular fractures there were 27 (19.8 %) cases of neurological lesions. In 12 cases the femoral head was dislocated posteriorly. Twenty were men and eight were woman. The mean age was 33.8 (range 16–66). 15 patients had associated injuries. The mean ISS was 12.6 (range 9–34). At initial presentation there were 13 patients with a complete dropped foot lesion, 10 patients with foot weakness and 4 patients with burning pain and altered sensation over the dorsum of the foot. Intra-operative monitoring was performed in 16 cases. All the patients had EMG studies for neurophysiological assessment of the lesion. EMG studies revealed sciatic nerve lesions in all the cases but in nine patients with a dropped foot there was evidence of a proximal (sciatic) and distal (neck of fibula) lesion, “double crush syndrome”. Only in 3 of these cases there was documentation of an ipsilateral knee injury. In two patients there was deterioration of foot function after surgery due to iatrogenic damage. At final follow-up, clinical examination and associated EMG studies revealed full recovery in 5 cases with initial muscle weakness (mean time 4.2 years (2–5)) and complete resolution of sensory symptoms (burning pain and hyposthesia) in 4 cases (mean time 3 years (2–4)). There was improvement of functional capacity (motor and sensory) in two cases with initially complete drop foot and in 4 cases with muscle foot weakness (mean time 3.6 years (range 2–6). In 11 of the cases with dropped foot (all nine with “double crush”) at presentation, there was no improvement in function, (mean time 3.9 years (range 2–6). Conclusion: Acetabulum fractures associated with sciatic nerve injuries continue to be a significant cause of long-term morbidity in trauma patients. In cases where there is evidence of “double crush lesions” the prospect of functional recovery is low as seen in this group of patients. Single lesions appear to be associated with a more favourable prognosis