[Paraplegia caused by vertebral compression fractures in senile osteoporosis]

Double-level posterior spinal shortening for paralytic osteoporotic vertebral collapse of two vertebral bodies with a normal vertebra in between: a case report

INTRODUCTION

Spinal shortening is indicated for osteoporotic vertebral collapse. However, this surgical procedure has not been indicated for more than two vertebral levels that are not adjacent. We experienced a rare case of paraparesis due to osteoporotic vertebral collapse of two vertebral bodies with a normal vertebra in between and treated successfully by the double-level posterior shortening procedure.

MATERIALS AND METHODS

A 79-year-old woman suffered from delayed paraparesis 2 years after L1 and Th11 vertebral body compression fracture. Plain X-ray photographs showed Th11 and L1 vertebral body collapse, Th7 compression fracture and a kyphosis angle of 30 degrees from Th10 to L2. Plain magnetic resonance imaging showed spinal canal stenosis at Th11 and L1 vertebral body levels. She was treated by double-level posterior spinal shortening using pedicle screw and hook systems.

RESULTS

After the procedure, the patient's kyphosis angle decreased to 10 degrees and her back pain, leg pain, and sensory deficits improved. She was able to walk by herself. Although new vertebral compression fractures occurred at L4 and L5 in the follow-up period, there has been no deterioration of the neurological symptoms 5 years after the operation.

CONCLUSION

Delayed paraparesis after double-level thoracolumbar vertebral collapse due to osteoporosis was treated successfully by double-level posterior spinal shortening using a pedicle screw and hook system.

Osteoporotic vertebral compression fracture causing neurologic deficit

Osteoporotic vertebral fractures rarely cause neurologic deficits. We discuss a 69-year-old man who presented with the signs of impaired function of the left L5 nerve root. Imaging revealed a fracture of the posterior upper edge of the fifth lumbar vertebra with a bony fragment protruding into the spinal canal. The fracture was attributed to sneezing and coughing in this man with osteoporosis secondary to hypogonadism. Literature search revealed 64 cases of neurologic deficit associated with osteoporotic vertebral fracture. Most osteoporotic fractures with neurologic deficit (72%) occur at the thoracolumbar junction. The symptomatology of girdle-like pain and hypesthesia is not specific and may be misinterpreted as an abdominal problem or renal pain. A typical sign is the slowly progressive neurologic deficit, occurring spontaneously or after minor trauma such as a fall on the buttocks. Surgical treatment confirms the diagnosis and usually leads to remission of the neurologic signs. With increasing frequency of osteoporotic fractures in the developed world because of the expanding elderly population, cases with neurologic problems become more important.

Posterior spinal shortening for paraparesis following vertebral collapse due to osteoporosis

STUDY DESIGN

Retrospective case series.

OBJECTIVES

To assess the efficacy of posterior spinal shortening for paraparetic patients following vertebral collapse owing to osteoporosis, especially on instrumentation loosening.

SETTING

Department of orthopaedic surgery, Jichi Medical University Hospital and Omiya Medical Center in Japan.

METHODS

The clinical records and radiographs of 13 patients with paraparesis following vertebral collapse owing to osteoporosis treated with posterior spinal shortening were retrospectively reviewed to evaluate the usefulness of this method. Assessment of the clinical course was done by direct examination in all cases. Ambulatory ability was divided into four categories.

RESULTS

Upon final observation, nine cases were able to walk with a cane or crutch, one case remained in gait training, two cases remained unable to stand and one case with urinary incontinence improved in urinary function. In one case, paralysis deteriorated. Vertebral compression fracture of the end vertebrae that were fixed occurred in three cases complicated with rheumatoid arthritis.

CONCLUSION

The posterior spinal shortening can be a choice for treating delayed paraparesis following vertebral collapse owing to osteoporosis.

Another option to treat Kümmell's disease with cord compression

The efficiency of short-segment fixation with transpedicle body augmenter (a titanium spacer with bone-ingrowth porous surface, TpBA) to treat Kümmell's disease with cord compression (stage III) was retrospectively evaluated. No laminectomy or instrumentation reduction was done. Inclusion criteria included Frankel CDE, single-level within T10-L2. FU rate was 88%, i.e. 21 cases were included. Frankel function classification was 6E9D6C. Mean age was 72+/-8 years. F:M was 16:5. FU period was 48 M (range, 30-76 M). The hospitalization was 4.5+/-2.2 days; operation time, 70.4+/-17.2 min; blood loss, 150+/-72 cc. Final Frankel class was 20E1D. Complications included two superficial infection and one pneumonia. Body height and kyphosis were all corrected significantly and well preserved at the final visit. No TpBA dislodgement or implant failure was noted; however, three cases developed new compression fractures. The clinical outcome showed 81% with P1 or P2 by Denis pain scale. This method can decompress spinal canal, maintain kyphosis correction and vertebral restoration, prevent implant failure, and attain good clinical results.

[Compound osteosynthesis as treatment for an osteoporotic LWK-1 burst fracture in a 76 year old female patient]

The surgical treatment of osteoporotic vertebral compression fractures is rarely necessary and is mostly done in fractures with neurological deficit. We present a case of compound osteosynthesis in an osteoporotic fracture of the first lumbar vertebra as a "salvage procedure" after a dislocation of a dorsal internal fixator in a 76 year old female sustaining incomplete paraplegia. In this case, an additional ventral stabilization using a vertebral body replacement was not practicable because of old age and previous pneumonia. We performed an additional compound osteosynthesis using bone cement because of insufficient stability when only using cement for augmentation of the pedicle screws.

Intravertebral vacuum phenomenon in osteoporotic compression fracture: report of 67 cases with quantitative evaluation of intravertebral instability

OBJECT

The objectives of this study were to: 1) describe the incidence and clinical features of intravertebral vacuum phenomenon (IVVP) in a relatively large number of cases; 2) quantitatively evaluate intravertebral instability and determine the factors affecting instability; and 3) evaluate the efficacy of percutaneous vertebroplasty in the treatment of this phenomenon.

METHODS

A retrospective review was conducted of the records of 67 patients with IVVP among 652 consecutive cases of osteoporotic compression fracture. Comparisons between the IVVP group and a control group, a stable group, and an unstable group were conducted. Percutaneous vertebroplasty was performed in all patients. There were 67 patients (10.3%) in whom there were 70 vacuum phenomena of the intravertebral space. Intravertebral vacuum phenomena occurred predominantly in the thoracolumbar junction (81%) and in patients with a longer duration of symptoms (10.6 +/- 9.8 months) compared with the control group. Of 59 vertebrae for which flexion-extension radiographs were available, 26 vertebrae were categorized as stable and 33 as unstable. Twenty-one vertebrae (64%) had undergone compression fracture in the unstable group compared with nine (35%) compression fractures in the stable group. There were 28 (85%) fractures of the wedged vertebrae in the unstable group compared with 16 (61%) fractures in wedged vertebrae in the stable group. Percutaneous vertebroplasty was performed with successful clinical outcome.

CONCLUSIONS

Intravertebral vacuum phenomenon is more common than has been previously appreciated. The results of this study indicate that biomechanics, not ischemic or avascular theory, may play an important role in pathogenesis of this phenomenon. Percutaneous vertebroplasty was found to be a minimally invasive and effective procedure for the treatment of IVVP.

Principles of management of osteometabolic disorders affecting the aging spine

Osteoporosis is the most common contributing factor of spinal fractures, which characteristically are not generally known to produce spinal cord compression symptoms. Recently, an increasing number of medical reports have implicated osteoporotic fractures as a cause of serious neurological deficit and painful disabling spinal deformities. This has been corroborated by the present authors as well. These complications are only amenable to surgical management, requiring instrumentation. Instrumenting an osteoporotic spine, although a challenging task, can be accomplished if certain guidelines for surgical techniques are respected. Neurological deficits respond equally well to an anterior or posterior decompression, provided this is coupled with multisegmental fixation of the construct. With the steady increase in the elderly population, it is anticipated that the spine surgeon will face serious complications of osteoporotic spines more frequently. With regard to surgery, however, excellent correction of deformities can be achieved, by combining anterior and posterior approaches. Paget's disease of bone (PD) is a non-hormonal osteometabolic disorder and the spine is the second most commonly affected site. About one-third of patients with spinal involvement exhibit symptoms of clinical stenosis. In only 12-24% of patients with PD of the spine is back pain attributed solely to PD, while in the majority of patients, back pain is either arthritic in nature or a combination of a pagetic process and coexisting arthritis. In this context, one must be certain before attributing low back pain to PD exclusively, and antipagetic medical treatment alone may be ineffective. Neural element dysfunction may be attributed to compressive myelopathy by pagetic bone overgrowth, pagetic intraspinal soft tissue overgrowth, ossification of epidural fat, platybasia, spontaneous bleeding, sarcomatous degeneration and vertebral fracture or subluxation. Neural dysfunction can also result from spinal ischemia when blood is diverted by the so-called "arterial steal syndrome". Because the effectiveness of pharmacologic treatment for pagetic spinal stenosis has been clearly demonstrated, surgical decompression should only be instituted after failure of antipagetic medical treatment. Surgery is indicated as a primary treatment when neural compression is secondary to pathologic fractures, dislocations, spontaneous epidural hematoma, syringomyelia, platybasia, or sarcomatous transformation. Five classes of drugs are available for the treatment of PD. Bisphosphonates are the most popular antipagetic drug and several forms have been investigated.

Osteoporotic vertebral burst fractures with neurologic compromise

A retrospective study was performed on the operative results following osteoporotic burst fractures with neurologic compromise. We sought to investigate the results of operative decompression and stabilization in patients with neurologic deficit as a result of an osteoporotic burst fractures. We examined the postoperative radiographic outcomes, level of disability, functional outcomes, and complications. Compression fractures of the anterior vertebral column secondary to osteoporosis and minimal trauma are a common clinical entity. These fractures are often effectively treated by nonoperative means. However, compressive failure of the middle vertebral column can lead to retropulsion of vertebral body fragments with significant canal compromise and neurologic injury. Treatment of these more severe injuries becomes more difficult and is less well established. Functional outcomes and disability from pain have not been examined. Previous reports on this subject have documented generally good results but have given few specific data regarding outcomes. We retrospectively report on a series of 10 patients, from 1995 to 1998, with osteoporotic burst fractures, which led to varying degrees of neurologic compromise. There were nine female and one male patient with a mean age of 76 years. Nine of the 10 patients presented more than 1 month following the onset of neurologic symptoms; 70% of the fractures occurred at the thoracolumbar junction (T11-L2). Mean loss of anterior column height was 59%, with significant kyphosis (mean 28 degrees) in nine of the 10 fractures. Mean canal compromise was 41%. At presentation, seven patients were Frankel grade D and three were Frankel grade C. All patients were treated operatively with decompression and arthrodesis. Mean time to follow-up was 16 months. Six of the 10 patients had improvement of their Frankel grade postoperatively and one deteriorated neurologically. Seven of the eight surviving patients completed the Oswestry questionnaire with a mean score of 44%, representing severe disability secondary to low back pain. The Physical Component score of the SF-36 was at or below the national mean for each patient. Complications were present in six of the eight surviving patients. Osteoporotic fractures are not benign. Careful evaluation for neurologic deterioration is warranted. Neurologic recovery occurred in six of the 10 patients; however, significant disability secondary to pain was common.

Posterior spinal shortening for paraplegia after vertebral collapse caused by osteoporosis

STUDY DESIGN

Case report of a patient who underwent a new surgical procedure for paraplegia after vertebral collapse due to osteoporosis.

OBJECTIVES

To propose a new approach to posterior spinal fusion surgery for osteoporotic patients.

SUMMARY OF BACKGROUND DATA

Surgical treatment was performed on a paraplegic patient after vertebral collapse due to osteoporosis. However, the surgery was difficult because implants such as hooks and screws often dislodged during the treatment. The poor holding power of these implants to the osteoporotic spine is a challenging problem in this treatment.

METHODS

When a fractured vertebra is shortened by resecting the posterior part of the spine and the application of a compression force, a short vertebra is produced. As a result, the thoracic kyphosis decreases and the force pushing the upper thoracic spine inferio-ventrally also decreases.

RESULTS

A 74-year-old woman with T12 vertebral collapse was treated with this new method. Lateral Cobb angle (T10-L2) was reduced from 26 to 4 degrees after surgery. The shortened vertebral body united, and after 33 months, the implant had not dislodged and no loss of correction was seen.

CONCLUSION

The posterior spinal shortening can be a choice for treating delayed paraplegia after osteoporotic vertebral fracture.

Vertebral pseudarthrosis in the osteoporotic spine

STUDY DESIGN

Radiologic and operative findings of intravertebral cleft in the osteoporotic spine were investigated and the pathomechanism discussed.

OBJECTIVES

To clarify the pathologic features of the intravertebral cleft.

SUMMARY OF BACKGROUND DATA

Intravertebral "vacuum" cleft is one of the common radiographic findings in the osteoporotic spine. It is thought that the cleft is a rare lesion of an ununited fracture, or pseudarthrosis. Evidential findings of the disease, however, have never been reported.

METHODS

Simple bone grafting was performed in five cases (average age, 76.8 years) of thoracolumbar intravertebral cleft in osteoporotic spine in patients who had been suffering from prolonged pain of the back or leg. Preoperative radiologic evaluation using flexion-extension radiograph and magnetic resonance imaging was performed in all patients. At operation, the cleft and the components of the structure were macroscopically and microscopically observed. The fluid content in the cleft was biochemically analyzed.

RESULTS

In all patients, preoperative flexion-extension radiographs showed intravertebral instability at the location of the clefts that indicated gas density in three cases and water density in two cases. Magnetic resonance imaging showed that, for the most part, the cleft was low intensity on the T1-weighted image and high intensity on the T2-weighted scans, regardless of the radiographic findings. At operation, abnormal movement was observed at the cleft of the affected body, which was covered with hypertrophic membrane. The serous fluid within the cleft was aspirated before the excision of soft tissue. The thick membrane was excised and showed that the cleft was lined by smooth fibrocartilaginous tissue and the great degree of motion between the fracture ends that is consistent with the pathologic appearance of pseudarthrosis.

CONCLUSIONS

The unstable cleft in the affected vertebral body of the osteoporotic spine with magnetic resonance findings of low intensity on the T1-weighted scans and high intensity on the T2-weighted scans suggests that the cleft is a false joint lined by fibrocartilaginous tissue with notable movement consistent with pseudarthrosis.

[Osteoporotic vertebral crush fractures with severe neurologic manifestations. Apropos of 6 cases]

Osteoporotic vertebral crush fractures with neurologic complications are rarely reported in the literature. We report six new cases particularly severe in which death occurred in two cases. The study group included four women and two men with a mean age of 75 years (range: 72-79). Vertebral collapse causing neurological deficit was T5, T9, T11 in two cases, L1 and L3. The mean number of vertebral collapses was three per patient (range: 1-9). Back pain appeared without traumatism 6 weeks before admission (range: 1-24). Neurological complications appeared 2.5 weeks after back pain (range: 1-8). One patient suffered from a paraplegia, three from a paraparesia with bladder dysfunction (n = 1). In one case there was a severe weakness of the levator muscles of the foot and in another a L3 femoral neuralgia with severe bowel and bladder dysfunction. X-rays demonstrated backwards displacement of the posterior cortex in three cases, an intravertebral vacuum phenomenon in two cases and a heterogeneous appearance suggesting a malignancy in two cases. Computed tomography, performed in four patients and tomography in one patient, demonstrated fragmentation of the vertebral body in all the cases and vacuum phenomenon in four cases. Magnetic resonance imaging performed in four cases has confirmed the absence of epiduritis and a compression due to bony structures in two cases. A vertebral biopsy was performed in three cases. Osteoporosis was observed in all the cases and in two cases there was also an osteonecrosis. Surgical treatment was performed in three cases and conservative medical treatment in the other cases. After surgical treatment we have observed an absence of improvement of neurological complications in one case, an improvement in another and finally a full recovery in the last case. After conservative treatment we have noted in two cases an absence of improvement of neurological complications and in one case an improvement of neurological deficit. Two patients died (one after medical treatment and another after surgical treatment).

Osteoporotic vertebral collapse with late neurological complications

This paper describes 27 patients who had a spinal fracture and underwent an anterior or a posterior spinal decompression, with or without spinal instrumentation, for late neurological compromise secondary to post-traumatic vertebral collapse associated with osteoporosis. Five males and 22 females were studied, with an average follow-up of 3.7 years. The patients developed delayed neurological compromise due to osteoporotic vertebral collapse 1 month to 1.5 years following insignificant spinal fractures. Abnormal hypermobility at the collapsed spinal level with gradual retropulsion of fracture fragments into the spinal canal appeared to contribute to late paralysis. This pathology is treated surgically either anteriorly or posteriorly, but we recommend transpedicular posterolateral decompression and stabilization with a screw-rod construct because of technical ease and minimum invasion.

Spontaneous burst fracture of the thoracolumbar spine in osteoporosis associated with neurological impairment: a report of seven cases and review of the literature

This is a report of seven patients suffering from osteoporosis, who sustained unstable burst fractures in the thoracolumbar spine associated with neurological impairment, without trauma. The manner of presentation, the neurological involvement, the radiological findings, as well as the surgical treatment with respect to functional and neurological recovery are discussed.

A comprehensive classification of thoracic and lumbar injuries

In view of the current level of knowledge and the numerous treatment possibilities, none of the existing classification systems of thoracic and lumbar injuries is completely satisfactory. As a result of more than a decade of consideration of the subject matter and a review of 1445 consecutive thoracolumbar injuries, a comprehensive classification of thoracic and lumbar injuries is proposed. The classification is primarily based on pathomorphological criteria. Categories are established according to the main mechanism of injury, pathomorphological uniformity, and in consideration of prognostic aspects regarding healing potential. The classification reflects a progressive scale of morphological damage by which the degree of instability is determined. The severity of the injury in terms of instability is expressed by its ranking within the classification system. A simple grid, the 3-3-3 scheme of the AO fracture classification, was used in grouping the injuries. This grid consists of three types: A, B, and C. Every type has three groups, each of which contains three subgroups with specifications. The types have a fundamental injury pattern which is determined by the three most important mechanisms acting on the spine: compression, distraction, and axial torque. Type A (vertebral body compression) focuses on injury patterns of the vertebral body. Type B injuries (anterior and posterior element injuries with distraction) are characterized by transverse disruption either anteriorly or posteriorly. Type C lesions (anterior and posterior element injuries with rotation) describe injury patterns resulting from axial torque. The latter are most often superimposed on either type A or type B lesions. Morphological criteria are predominantly used for further subdivision of the injuries. Severity progresses from type A through type C as well as within the types, groups, and further subdivisions. The 1445 cases were analyzed with regard to the level of the main injury, the frequency of types and groups, and the incidence of neurological deficit. Most injuries occurred around the thoracolumbar junction. The upper and lower end of the thoracolumbar spine and the T10 level were most infrequently injured. Type A fractures were found in 66.1%, type B in 14.5%, and type C in 19.4% of the cases. Stable type A1 fractures accounted for 34.7% of the total. Some injury patterns are typical for certain sections of the thoracolumbar spine and others for age groups. The neurological deficit, ranging from complete paraplegia to a single root lesion, was evaluated in 1212 cases.(ABSTRACT TRUNCATED AT 400 WORDS)