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OBJECTIVE@#To investigate whether 3D-printed artificial vertebral body can reduce prosthesis subsidence rate for patients with cervical chordomas, through comparing the rates of prosthesis subsidence between 3D printing artificial vertebral body and titanium mesh for anterior spinal reconstruction after total spondylectomy.@*METHODS@#This was a retrospective analysis of patients who underwent surgical treatment for cervical chordoma at our hospital from March 2005 to September 2019. There were nine patients in the group of 3D artificial vertebral body (3D group), and 15 patients in the group of titanium mesh cage (Mesh group). The patients' characteristics and treatment data were extracted from the medical records, including age, gender, CT hounsfield unit of cervical vertebra and surgical information, such as the surgical segments, time and blood loss of surgery, frequency and degree of prosthesis subsidence after surgery. Radiographic observations of prosthesis subsidence during the follow-up, including X-rays, CT, and magnetic resonance imaging were also collected. SPSS 22.0 was used to analysis the data.@*RESULTS@#There was no significant difference between the two groups in gender, age, CT hounsfield unit, surgical segments, time of surgery, blood loss of posterior surgery and total blood loss. Blood loss of anterior surgery was 700 (300, 825) mL in 3D group and 1 500 (750, 2 800) mL in Mesh group (P < 0.05). The prosthesis subsidence during the follow-up, 3 months after surgery, there was significant difference between the two groups in mild prosthesis subsidence (P < 0.05). The vertebral height of the 3D group decreased less than 1 mm in eight cases (no prosthesis subsidence) and more than 1 mm in one case (mild prosthesis subsidence). The vertebral height of the Mesh group decreased less than 1 mm in five cases (no prosthesis subsidence), and more than 1 mm in eight cases (mild prosthesis subsidence). Two patients did not have X-rays in 3 months after surgery. There was a statistically significant difference between the two groups in the prosthesis subsidence rate at the end of 12 months (P < 0.01). The vertebral height of eight cases in the 3D group decreased less than 1 mm (no prosthesis subsidence) and one case more than 3 mm (severe prosthesis subsidence). Four of the 15 cases in the Mesh group decreased less than 1 mm (no prosthesis subsidence), two cases more than 1 mm (mild prosthesis subsidence), and nine cases more than 3 mm (severe prosthesis subsidence). There was a statistically significant difference between the two groups in the prosthesis subsidence rate at the end of 24 months (P < 0.01). The vertebral height of seven cases in the 3D group decreased less than 1 mm (no prosthesis subsidence), one case more than 3 mm (severe prosthesis subsidence), and one case died with tumor. One case in the Mesh group decreased less than 1 mm (no prosthesis subsidence), one case more than 1 mm (mild prosthesis subsidence), 11 case more than 3 mm (severe prosthesis subsidence), one case died with tumor and one lost the follow-up. Moreover, at the end of 12 months and 24 months, there was significant difference between the two groups in severe prosthesis subsidence rate (P < 0.01).@*CONCLUSION@#3D-printed artificial vertebral body for anterior spinal reconstruction after total spondylectomy for patients with cervical chordoma can provide reliable spinal stability, and reduce the incidence of prosthesis subsidence after 2-year follow-up.
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Humanos , Cordoma/cirurgia , Estudos Retrospectivos , Corpo Vertebral , Titânio , Vértebras Cervicais/cirurgia , Impressão Tridimensional , Fusão Vertebral/métodos , Resultado do TratamentoRESUMO
Objective@#To summarize the perioperative nursing measures and effects of 3D printed artificial cervical vertebrae for lower cervical spine fractures.@*Methods@#Treatment of 15 cases of lower cervical spine fracture with 3D printed artificial cervical vertebrae. Preoperative cervical spine fixation to prevent spinal cord injury, strict observation of clinical symptoms, assist the doctor to perform CT three-dimensional reconstruction of the cervical spine, and calculate the physiological height of the injured vertebrae; maintain the surgical position fixed during surgery, carefully prepare the supporting equipment, familiar with the surgical related steps, accurate delivery of all types of surgical instruments to assist with intraoperative fluoroscopy. Postoperative focus on the neck to see if there is swelling, effectively maintain the airway patency, observe changes in spinal nerve function, develop a personalized functional exercise program to promote rehabilitation, and actively prevent complications.@*Results@#The JOA score increased from (9.23±1.62) points before surgery to (14.09±1.35) points after surgery, and the improvement rate was 62.55%. There were no complications such as difficulty swallowing, hoarseness, and difficulty breathing.@*Conclusions@#Through targeted perioperative care, surgical complications can be reduced and the quality of life of patients improved.
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Objective To summarize the perioperative nursing measures and effects of 3D printed artificial cervical vertebrae for lower cervical spine fractures. Methods Treatment of 15 cases of lower cervical spine fracture with 3D printed artificial cervical vertebrae. Preoperative cervical spine fixation to prevent spinal cord injury, strict observation of clinical symptoms, assist the doctor to perform CT three-dimensional reconstruction of the cervical spine, and calculate the physiological height of the injured vertebrae; maintain the surgical position fixed during surgery, carefully prepare the supporting equipment, familiar with the surgical related steps, accurate delivery of all types of surgical instruments to assist with intraoperative fluoroscopy. Postoperative focus on the neck to see if there is swelling, effectively maintain the airway patency, observe changes in spinal nerve function, develop a personalized functional exercise program to promote rehabilitation, and actively prevent complications. Results The JOA score increased from (9.23 ± 1.62) points before surgery to (14.09 ± 1.35) points after surgery, and the improvement rate was 62.55%. There were no complications such as difficulty swallowing, hoarseness, and difficulty breathing. Conclusions Through targeted perioperative care, surgical complications can be reduced and the quality of life of patients improved.
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At present, artificial vertebral implants have proven to be effective in the treatment of spinal tumors, infections, fractures and other diseases. However, the fusion artificial vertebral body can cause adjacent intervertebral joint degeneration and loss of original physiological curvature and activity. The movable artificial vertebral body can, to some extent, restore the normal physiological movement and reduce biomechanical changes of the spine, reducing the occurrence of complication. The design of movable artificial vertebral body is to equip movable device when the basis of reliable stability is obtained. According to its principle it can be divided into ball socket joint or elastic deformation. However the overall design of movable artificial vertebral body needs further improvement. Traditional mechanical processing methods are difficult to process complex prostheses and the agreement rate between traditional produced prostheses and lesions was low. While the emerging 3D printing technology can achieve individualized improvement of prosthesis, its slow rate and high cost need to be improved. The materials of movable artificial vertebral body includes metal, ceramics, biomaterials, high polymer materials and so on. Titanium alloy is the main material in metal materials, which is widely used, but its modulus of elasticity is still far from that of human bone and it lacks ideal bone fusion. Ceramic materials are rich in variety but fragile and poor in wear resistance. Biomaterials include autogenous bone, allogeneic bone, etc., with limited source and complicated operation. There are many kinds of polymer and biodegradable materials which obtain excellent and ideal properties. But their properties and applications need to be further studied. The movable artificial vertebral body still needs to be promoted and developed. The clinical experimental data is still insufficient, and long-term curative effect needs to be further observed and studied. This paper reviews the development, advantages, design, processing and materials of movable artificial vertebral bodies and provides useful reference for optimization design, processing and clinical application of movable artificial vertebral bodies.
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Humanos , Materiais Biocompatíveis , Fenômenos Biomecânicos , Próteses e Implantes , Neoplasias da Coluna Vertebral , Coluna Vertebral , TitânioRESUMO
BACKGROUND:Vertebral metastatic tumor often occurs in the thoracolumbar segment, and it is difficult for internal fixation due to the complex anatomical position. OBJECTIVE:To evaluate the stability of lumbar vertebra in the patients with single thoracolumbar vertebral metastases after treated with artificial vertebral placement and internal fixation. METHODS:Sixteen patients (9 male and 7 female) with single thoracolumbar vertebral metastases treated in the Department of Orthopedics, the Fourth Hospital of Hebei Medical University from January 2006 to January 2009 were selected, and the age ranged 40-74 years, averaged 52 years. Before treatment, al the patients were evaluated according to Frankel classification:A grade in two cases, B grade in three cases, C grade in three cases, D grade in five cases, and E grade in three cases. And the vertebral state of patients was detected with X-ray plain film examination, systemic radionuclide bone scanning, CT and MRI. The T11 vertebral metastases were treated with chest approach artificial vertebral placement and internal fixation, and T12-L2 vertebral metastases were treated with artificial vertebral placement and internal fixation via extrapleural and extraperitoneal space approach. RESULTS AND CONCLUSION:Al the 16 patients were fol owed up for 4-32 months, and the average survival time after treatment was 12 months. After treatment, Frankel classification was C grade in three cases, D grade in five cases and E grade in eight cases. The visual analog scale score was decreased from (6.22±1.31) before treatment to (3.25±0.94) after treatment, and there was significant difference between two groups (P<0.05). The artificial vertebral placement and internal fixation can restore the stability of lumbar vertebra in the patients with spinal metastases, and thus improving the symptoms and quality of life.
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[Objective]To observe the clinical results of adjustable hollow titanium artificial vertebra in the treating of tumor,tuberculosis and severe burst fracture of the thoracic and lumber vertebra.[Method]Totally 169 cases of thoracolumbar fractures were treated,including 64 cases of tumor,66 cases of tuberculosis and 39 cases of severe burst fracture of the thoracic and lumber spine,of which 57 cases with kyphosis of those Cobb's angle was 27.1~65.4 degrees with a mean(38.5?10.7)degrees,were treated by one-stage procedure,including pathologic vertebral resection,anterior interbody reduction and implant adjustable hollow titanium artificial vertebral body,anterior internal fixation or posterior transpedicular fixation,reconstruction of spinal stability.For anterior stabilization,the Centaur plate system,Z-plate and XIAⅡrod-screw spinal system were used.Relief of the pain,the function of spinal cord or nerve,kyphosis collection and spinal stability were monitored.[Result]Postoperatively,the period of follow-up lasted 12 months to 46 months with a mean of 32 months.All these patients had their incision healed by first intention,and no recurrence was noted in those patients of tumor and tuberculosis.All patients experienced significant palliation local pain,and 73 patients showed improved neurological status(at least one grade improvement on Frankel's functional classification).The instrumentation provided immediate stability and protected against development of kyphotic deformity in all patients.Postoperative radiological evaluation revealed that implants were stable,there was no phenomena of prosthesis subsidence,hook dislodgment and failure restoration of spinal segments height.Solid bony fusion was obtained in all patients.The residual kyphotic deformity had been corrected by(31.6?8.3)degrees with a mean(6.2?8.7)degrees after operation.[Conclusion]Pathologic vertebral resection,artificial vertebral body replacement and internal fixation are ideal treatmens in thorough decompression,release of pain,reconstruction of spinal stability and resume of spinal sequence.