Thoracoscopic Spinal Surgery Research Articles

Video-assisted thoracoscopic image-guided spine surgery: evolution of 19 years of experience, from endoscopy to fully integrated 3D navigation.

The purpose of this study was to describe the evolution of thoracoscopic spine surgery from basic endoscopic procedures using fluoroscopy and anatomical localization through developmental iterations to the current technology use in which endoscopy and image-guided surgery are merged with intraoperative CT scanning. The authors provided detailed explanations of their thoracoscopic spine surgery techniques, beginning with their early-generation endoscopy with fluoroscopic localization, which was followed with point surface matching techniques and early image guidance. The authors supplanted this with the modern era of image guidance, thoracoscopic spine surgery, and seamless integration that has reached its current level of refinement. A retrospective review of single-institution thoracoscopic procedures performed by the senior author over the course of 19 years yielded a total of 160 patients, including 73 women and 87 men. The mean patient age was 55 years, and the range included patients 16-94 years of age. There were no patients with worsened neurological function. One hundred sixteen patients underwent surgery for thoracic disc herniation, 18 for underlying neoplasms with spinal cord compression, 14 for osteomyelitis and discitis, 12 for thoracic deformity with neurological changes, and 8 for traumatic etiologies. More than 19 years of experience has revealed the benefits of integrating thoracoscopic spine surgery with intraoperative CT scanning and image-guided surgery, including direct decompression without manipulation of neural elements, superior 3D spatial orientation, and localization of complex spinal anatomy. With the exponential growth of machine learning, robotics, artificial intelligence, and advances in imaging techniques and endoscopic imaging, there may be further refinements of this technique on the horizon.

Introduction: the rise of the robots in spinal surgery.

In his 1920 science fiction play R.U.R., Czech writer Karel Capek introduced the word "robot" to the English language. The play tells the story of a factory that produces roboti, which are living creatures that resemble humans and have the capacity for individual thought. While at first the roboti seem content to work for their human masters, they later rebel, ultimately leading to the extinction of the human race. 1 This play and similar depictions of robots in literature and film are probably responsible for the slightly negative reputation of robots in general. Only recently has this perception changed, thanks to the advent of robots that can vacuum our houses and perform other mundane chores. Raymond Goertz, while working for the US Atomic Energy Commission, is credited with the development of the first robotic arm in 1951. 2 It was designed to handle hazardous radioactive material. Unimation Inc. developed the first industrial robot in 1961; that robot handled molten die-castings and removed the human element from these labor-intensive, often dangerous tasks. With the development of the Programmable Universal Manipulation Arm (PUMA) in 1978, the robot was sophisticated enough to be introduced to medicine. The first working definition of the word "robot" was published, fittingly, by the Robotics Institute of America in 1980: ". . . a reprogrammable, multifunctional manipulator designed to move materials, parts, tools, or specialized devices through various programmed motions for the performance of a variety of tasks." 6 In 1988, the six-degrees-of-freedom flexible arm PUMA 560 was used to guide a needle under CT guidance into the brain. 4 With the introduction of robotic arms came the ability to use them as surgical assistants. In 1998, Okada et al. described a voice-controlled robot used to hold a thoracoscope. 5 This type of robot was also used in thoracoscopic spinal surgery. The military, having a vested interest in telepresence surgery, helped fund the development of the da Vinci Surgical System that was approved for use by the FDA in 2000 and designed to facilitate complex, minimally invasive intracavitary surgeries. 7 In 2004, the FDA cleared the first commercially available positioning device for the placement of spinal instrumentation. At present, several systems are commercially available that utilize robotics for spinal operations. In a recent review, Joseph et al. evaluated the current landscape regarding safety, accuracy, and radiation exposure with the use of these technologies. These authors concluded that "… the placement of pedicle screws with robotics appears to be safe, and accuracy appears to be superior to freehand placement, although the data are not conclusive." 3 There seems to be a significant level of interest in this technology; however, only time will tell if it will become commonplace in our field. In this issue of Neurosurgical Focus, we visually explore the expanding role of robotics and image guidance in spinal surgery. New robots used for the first time and existing robots used for novel applications graphically demonstrate how our field is evolving. The days of fearing robots are behind us as members of our specialty begin to embrace the concept of automation. Thankfully, unlike Capek's rogue roboti, surgical robots rising up against us and causing world destruction is unlikely!

Image-guided navigation and video-assisted thoracoscopic spine surgery: the second generation

Video-assisted thoracoscopic surgery (VATS) has evolved for treatment of a variety of spinal disorders. Early incorporation with image-guided surgery (IGS) was challenged due to reproducibility and adaptability, limiting the procedure's acceptance. In the present study, the authors report their experience with second-generation IGS and VATS technologies for anterior thoracic minimally invasive spinal (MIS) procedures. The surgical procedure is described in detail including operating room set-up, patient positioning (a lateral decubitus position), placement of the spinal reference frame and portal, radiographic localization, registration, surgical instruments, and the image-guided thoracoscopic discectomy. Combined IGS and VATS procedures were successfully performed and assisted in anatomical localization in 14 patients. The mean patient age was 59 years (range 32-73 years). Disc herniation pathology represented the most common indication for surgery (n = 8 patients); intrathoracic spinal tumors were present in 4 patients and the remaining patients had infection and ossification of the posterior longitudinal ligament. All patients required chest tube drainage postoperatively, and all but 1 patient had drainage discontinued the following day. The only complication was a seroma that was presumed to be due to steroid therapy for postoperative weakness. At the final follow-up, 11 of the patients were improved neurologically, 2 patients had baseline neurological status, and the 1 patient with postoperative weakness was able to ambulate, albeit with an assistive device. The evolution of thoracoscopic surgical procedures occurring over 20 years is presented, including their limitations. The combination of VATS and IGS technologies is discussed including their safety and the importance of 3D imaging. In cases of large open thoracotomy procedures, surgeries require difficult, extensive, and invasive access through the chest cavity; using a MIS procedure can potentially eliminate many of the complications and morbidities associated with large open procedures. The authors report their experience with thoracic spinal surgeries that involved MIS procedures and the new technologies. The most significant advance in IGS procedures has resulted from intraoperative CT scanning and automatic registration with the IGS workstation. Image guidance can be used in conjunction with VATS techniques for thoracic discectomy, spinal tumors, infection, and ossification of the posterior longitudinal ligament. The authors' initial experience has revealed this technique to be useful and potentially applicable to other MIS procedures.

Outcome after thoracoscopic ventral stabilisation of thoracic and lumbar spine fractures

Background and PurposeThoracoscopic-assisted ventral stabilisation for thoracolumbar fractures has been shown to be associated with decreased recovery time and less morbidity when compared with open procedures. However, there are a limited number of studies evaluating late clinical and radiological results after thoracoscopic spinal surgery.MethodsWe performed an analysis of the late outcomes of thoracolumbar fractures after minimally invasive thoracoscopic ventral instrumentation. Between August 2003 and December 2008, 70 patients with thoracolumbar fractures (T5-L2) underwent ventral thoracoscopic stabilisation. Tricortical bone grafts, anterior plating systems (MACS-System), and cage implants were used for stabilisation. Outcomes measured include radiologic images (superior inferior endplate angle), Visual Analogue Scale (VAS), VAS Spine Score, quality of life scores SF-36 and Oswestry Disability Index (ODI).ResultsForty seven patients (67%, 47 out of 70) were recruited for the follow up evaluation (2.2 ± 1.5 years). Lower VAS Spine scores were calculated in patients with intra- or postoperative complications (44.7 (± 16.7) vs. 65.8 (± 24.5), p=0.0447). There was no difference in outcome between patients treated with bone graft vs. cage implants. Loss of correction was observed in both bone graft and titanium cage groups.InterpretationThe present study demonstrates diminished long-term quality of life in patients treated with thoracoscopic ventral spine when compared with the outcome of german reference population. In contrast to the other patients, those patients without intra-operative or post-operative complications were associated with improved outcome. The stabilisation method (bone graft versus spinal cage) did not affect the long-term clinical or radiographic results in this series.

Splenic Rupture Related to Thoracoscopic Spine Surgery

Case report and review of the literature. We report a case of splenic rupture in association with thoracoscopic spine surgery. Complications of thoracoscopic spine surgery have been reported in the literature, including pleural effusion, pneumothorax, chyle thorax, intercostal neuralgia, cerebrospinal fluid fistula, lung injury, and great vessel injury. Although it has been reported to have occurred with other endoscopic procedures, splenic rupture has not been reported in association with thoracoscopic spine surgery. A 60-year-old man with a T12 spine lesion underwent T12 corpectomy and fusion using a thoracoscopic approach. Intraoperatively, he became hemodynamically unstable, and postoperative abdominal computed tomography was consistent with splenic rupture. He underwent emergent splenectomy and has made a good recovery. This case describes how retraction on the diaphragm during thoracoscopic spine surgery can lead to splenic injury. A high index of suspicion should be maintained in cases in which hemodynamic instability is identified despite a clean surgical field.

Thoracoscopic approaches for treating various spinal diseases

Minimally invasive surgery is currently a goal for surgical intervention in the spine. The effectiveness of endoscopic thoracic spine surgery and technological improvements are two factors that are always under consideration in the practice of spinal surgery. We present twenty-five patients whose thoracoscopic spinal surgeries were performed between 2002 and 2008 for the treatment of various spinal diseases. Eleven patients with thoracic disc herniation, five patients with traumatic thoracic spinal compressive fracture, six patients with metastatic thoracic spinal tumors and three patients with tubercular spondylitis underwent thoracoscopic spine surgery. Clinical evaluations were performed at 3, 6,12 and 24 months post-surgery. The Oswestry disability questionnaire and linear visual analog scale (VAS) were used for the evaluation of pain. Postoperatively, two patients had lung contusions, one patient had pneumonia and one patient had instability. There were significant initial improvements in both the Oswestry score and the VAS pain score up to 6 months (p<0.05). The average relative difference in pain scores in all groups was not significant at 12 and 24 months (p>0.05). The favorable results of thoracoscopic spinal surgery encourage its application to situations in which a conventional thoracic approach is indicated. Thoracoscopic spine surgery is applicable to all patients with various spinal diseases.

内視鏡手術の現況 脊椎内視鏡下手術

The Japan Orthopedic Association has led the way with endoscopic surgery for the spine and has developed its own training course and technical authorization system. Endoscopic surgery can be classified roughly as an anterior procedure from the pleural or peritoneal cavity or as a posterior procedure from the posterior interlaminar space in spine endoscopic surgeries. A representative technique of the endoscopic posterior spine surgery, which uses the posterior method, is microendoscopic discectomy (MED). While MED was initially utilized for lumbar herniotomy, it has recently been used for lumbar spinal canal stenosis and cervical spine disease. Therefore, all the posterior operative procedures are generally used with an MED system and they are referred to as MED. Thus, MED accounts for 98.7% of spine endoscopic operations performed in Japan (2006). There is little soft tissue damage with this approach and the lamina can be reached between the muscles for lumbar disc herniation. In the MED, radiographic control is indispensable for localization of the tube retractor, and it is necessary to resect the yellow ligament little by little to divide the superficial layer and the deep layer. MED is superior in visual safety for retraction of the nerve root to herniotomy. As for issues with MED, there is a substantial learning curve, the operation requires a long time, expensive instrumentation, there is the lack of haploscopic vision, the visual field to operate is limited, there is a tendency to become disoriented, and the lack of sensation of palpating an organ. Additional approaches include video-assisted thoracoscopic spine surgery (VATS) and endoscopic anterior lumbar spine surgery via the peritoneal or retroperitoneal cavity, but they do not lead to global operations.

Thoracoscopic Debridement and Stabilization of Pyogenic Vertebral Osteomyelitis

The role of surgical debridement and internal fixation in treatment of vertebral osteomyelitis has been evolving. The standard surgical approach to thoracolumbar vertebral osteomyelitis requiring extensive thoracotomy or retroperitoneal exposure carries significant associated morbidity and postoperative pain. Minimally invasive thoracoscopic spine surgery is designed to improve postoperative morbidity associated with the traditional open surgery. We report a case of a 70-year-old man who developed T11-T12 pyogenic vertebral osteomyelitis 3 months after undergoing posterior laminectomy and microsurgical excision of a herniated thoracic disc. The patient underwent minimally invasive thoracoscopic radical debridement and anterior spinal reconstruction and fusion. Patients with vertebral osteomyelitis may benefit from the decreased postoperative morbidity that is associated with minimally invasive thoracoscopic spinal surgery.

Clinical Analysis of Video-assisted Thoracoscopic Spinal Surgery in the Thoracic or Thoracolumbar Spinal Pathologies

Thoracoscopic spinal surgery provides minimally invasive approaches for effective vertebral decompression and reconstruction of the thoracic and thoracolumbar spine, while surgery related morbidity can be significantly lowered. This study analyzes clinical results of thoracoscopic spinal surgery performed at our institute. Twenty consecutive patients underwent video-assisted thoracosopic surgery (VATS) to treat various thoracic and thoracolumbar pathologies from April 2000 to July 2006. The lesions consisted of spinal trauma (13 cases), thoracic disc herniation (4 cases), tuberculous spondylitis (1 case), post-operative thoracolumbar kyphosis (1 case) and thoracic tumor (1 case). The level of operation included upper thoracic lesions (3 cases), midthoracic lesions (6 cases) and thoracolumbar lesions (11 cases). We classified the procedure into three groups: stand-alone thoracoscopic discectomy (3 cases), thoracoscopic fusion (11 cases) and video assisted mini-thoracotomy (6 cases). Analysis on the Frankel performance scale in spinal trauma patients (13 cases), showed a total of 7 patients who had neurological impairment preoperatively : Grade D (2 cases), Grade C (2 cases), Grade B (1 case), and Grade A (2 cases). Four patients were neurologically improved postoperatively, two patients were improved from C to E, one improved from grade D to E and one improved from grade B to grade D. The preoperative Cobb's and kyphotic angle were measured in spinal trauma patients and were 18.9+/-4.4 degrees and 18.8+/-4.6 degrees , respectively. Postoperatively, the angles showed statistically significant improvement, 15.1+/-3.7 degrees and 11.3+/-2.4 degrees , respectively (P<0.001). Although VATS requires a steep learning curve, it is an effective and minimally invasive procedure which provides biomechanical stability in terms of anterior column decompression and reconstruction for anterior load bearing, and preservation of intercostal muscles and diaphragm.

Research on complications of thoracoscopic assisted thoracic spine surgery

To analyze occurrence, prevention and treatment of the complications of thoracoscopic assisted spine surgery. Retrospective review of 182 patients who underwent standard thoracoscopic technique or video-assisted thoracic surgical procedure from October 1998 to August 2004. The treatment of thoracic diseases included debridement, decompression with (or) reconstruction. The total number of complications were recorded, and its mechanism, prevention and treatment were analyzed. Complications occurred in 16 patients, 12 cases of perioperative complications included 3 patients suffered from pneumonia, 3 pulmonary atelectasis, 2 patients' lung injured by trocar, 1 patient obtained transient monoplegia, 2 suffered from transient intercostal nerve pain and 1 had superficial incision infection. Long-term complications occurred in 4 cases: spinal tuberculosis relapsed 2 cases (one who had diabetes obtained relapse in 8 months of post-operation and another relapsed with complex spinal tuberculosis in 4 weeks postoperation), 2 patients suffered from kyphosis deformity and pain. The type and incidence of complications with thoracoscopic spine surgery mainly depend on indication, operation procedures and anesthesia, only by limit surgical indication, ameliorate technique, obey surgical principle and consummate perioperative treatment can we obtain mini-invasive effect by thoracoscopic assisted spine surgery.

Thoracoscopic spine surgery for decompression and stabilization of the anterolateral thoracolumbar spine

The anterior thoracolumbar spine can be exposed via a variety of approaches. Historically, open anterolateral or posterolateral approaches have been used to gain access to the anterior thoracolumbar spinal column. Although the exposure is excellent, open approaches are associated with significant pain and respiratory problems, substantial blood loss, poor cosmesis, and prolonged hospitalization. With the increasing use of the endoscope in surgical procedures and recent advances in video-assisted thoracoscopic surgery, minimally invasive thoracoscopic spine surgery has been developed to decrease the morbidity associated with open thoracotomy. The purpose of this article is to illustrate the surgical technique of a minimally invasive thoracoscopic approach to the anterolateral thoracolumbar spine and to discuss its potential indications and contraindications in patients with diseases involving the anterior thoracic and lumbar regions.

Image-Guided Thoracoscopic Spinal Surgery: A Merging of 2 Technologies

Retrospective clinical and intraoperative navigational data review. To evaluate quantitatively the application of frameless stereotactic image guidance in thoracoscopic discectomy procedures. Thoracoscopic spinal surgery has technical and anatomic challenges that result in difficult orientation with a 2-dimensional imaging procedure in a complex 3-dimensional structure. There were 16 patients who underwent image-guided thoracoscopic discectomy procedures that combine these 2 technologies. Accuracy was determined by the registration (calculated) error and actual navigation (intraoperative) error. The clinical outcomes and complications were reviewed. Accuracy determined by registration (calculated) and navigation (intraoperative) was 1.7 and 1.2 mm, respectively. The additional time required for the image guidance portion of the procedure was countered by the efficiency of the remaining procedure. Clinical outcomes and complication were comparable with previous experience. Image-guided thoracoscopic spinal surgery can provide 3-dimensional orientation to a 2-dimensional imaging procedure that ultimately improves accuracy, efficiency, and safety. Future developments in combining guidance technology with standard surgical procedures will likely continue.

Spinal cord feeding arteries at MR angiography for thoracoscopic spinal surgery: feasibility study and implications for surgical approach.

To prospectively investigate the feasibility of contrast material-enhanced magnetic resonance (MR) angiography for visualization of the spinal vasculature in patients referred for video-assisted thoracoscopic surgical treatment of a thoracic herniated disk and to prospectively assess the influence of preoperative imaging of the spinal vasculature on the choice of surgical approach. Eight patients (three men and five women; mean age, 58 years; range, 42-83 years) with a thoracic herniated disk underwent contrast-enhanced MR angiography of the thoracoabdominal aorta and posterior branches. Imaging was performed with three-dimensional first-pass contrast-enhanced MR angiographic technique and a triple dose of gadolinium-based contrast agent. Images were analyzed by two observers in consensus to localize the Adamkiewicz artery (AKA) and its connections to the aorta and the anterior spinal artery (ASA). This information was used to determine any change in surgical approach. In all eight patients, the AKA, the ASA, and the connections with the aorta were identified. The AKA originated between T9 and L2 in all patients and derived from the left side of the aorta in 75% (six of eight) of the patients. In three patients in whom the AKA was observed on the left side, the surgical approach was changed to the right side to preserve spinal cord integrity. Preoperative imaging of the AKA is feasible with contrast-enhanced MR angiography. Contrast-enhanced MR angiography can be used to image the main feeding arteries of the spinal cord in patients undergoing thoracoscopic spinal surgery, and results can be used to change the side of surgical approach.

Operative technique of thoracoscopic spine surgery

Thoracoscopic approaches to the spine decrease associated morbidity compared with open approaches. This article reviews techniques applied to manage common thoracoscopically treated pathologies.

Thoracoscopic Multilevel Anterior Instrumented Fusion in a Goat Model

A survival study in a caprine model for evaluation of a thoracoscopic anterior scoliosis instrumentation construct for fusion. To compare the efficacy of performing multilevel anterior thoracoscopic "scoliosis" fusion with both allograft and autograft bone. The use of minimally invasive thoracoscopic spinal surgery has been increasing. Until recently, instrumentation methods for correcting scoliosis entirely with a minimally invasive approach have not been available. Although multilevel thoracoscopic instrumentation and fusion now is in use clinically at some centers, reports of its effectiveness in an animal model are limited. A thoracoscopically implanted multilevel screw-rod instrumentation construct was used in a goat survival model, with fusion quality evaluated 16 weeks after surgery. Autogenous iliac crest bone graft was compared with an allogenic bone graft substitute. The quality of fusion was evaluated both radiographically and biomechanically. Thoracoscopic insertion of a multilevel screw-rod construct was demonstrated to be technically feasible. However, with regard to the quality of fusion, only 47% of the disc space "fusion ratings" with the use of autogenous iliac crest graft were considered fully fused by computed tomography scan evaluation. This compares with no ratings of full fusion in the allograft demineralized bone group and only a single rating of full disc space fusion in the control group, which received no bone graft. Torsional range of motion was the smallest in the group receiving iliac crest bone graft and the greatest in the control animals that did not undergo bone grafting. The lack of complete fusion at 4 months in the autogenous iliac crest group emphasizes the importance of the discectomy and bone grafting technique. The use of demineralized bone allograft as a sole source of interbody fusion is not supported.

Thoracoscopic-assisted Treatment of Thoracic and Lumbar Fractures: A Series of 371 Consecutive Cases

Conventional approaches for the treatment of thoracic and thoracolumbar fractures require extensive surgical exposure, often leading to significant postoperative pain and morbidity. Thoracoscopic spinal surgery was performed to reduce the morbidity of these approaches while still achieving the primary goals of spinal decompression, reconstruction, and stabilization. Between May 1996 and May 2001, 371 patients with fractures of the thoracic and thoracolumbar spine (T3-L3) were treated with a thoracoscopically assisted procedure. In the first 197 patients, a conventional open anterior plating system was used. The last 174 patients were treated with the MACS-TL system (Aesculap, Tuttlingen, Germany), which was designed specifically for endoscopic placement, thereby significantly reducing operative times. Seventy-three percent of the fractures were located at the thoracolumbar junction. In 49% of patients, mobilization of the diaphragm was performed to expose the fracture, with later repair. Both x-ray canal compromise and neural deficit were present in 15% of patients. In 35% of patients, a stand-alone anterior thoracoscopic reconstruction was performed. In 65% of patients, a supplemental posterior pedicle-screw construct was also placed either before or after the anterior construct. A steep learning curve was present, with an average operating time of 300 minutes in the first 50% of cases and an average of 180 minutes with the MACS-TL system. The severe complication rate was low (1.3%), with one case each of aortic injury, splenic contusion, neurological deterioration, cerebrospinal fluid leak, and severe wound infection. Compared with a group of 30 patients treated with open thoracotomy, thoracoscopically treated patients required 42% less narcotics for pain treatment after the operation. A complete anterior thoracoscopically assisted reconstruction of thoracic and thoracolumbar fractures can be safely and effectively accomplished, thereby reducing the pain and morbidity associated with conventional thoracotomy and thoracolumbar approaches. Although the learning curve is steep, the functional and cosmetic benefits to the patient warrant the difficult training process.

1:36 Thoracoscopic treatment of 371 thoracic and lumbar fractures

Purpose of study: Conventional approaches for the treatment of thoracic and thoracolumbar fractures require extensive surgical exposure, often leading to significant postoperative pain and morbidity. Thoracoscopic spinal surgery was introduced to reduce the morbidity of these approaches while still achieving the primary goals of spinal decompression, reconstruction and stabilization. The purpose of this study was to summarize our experience with the thoracoscopic treatment of 371 consecutive cases of thoracic and lumbar fractures.Methods used: Between May 1996 and May 2001, 371 patients with fractures of the thoracic and thoracolumbar spine (T3–L3) were treated with a thoracoscopically assisted procedure. Case records and radiographs were reviewed. All phases of the procedure, including discectomy, vertebrectomy, grafting and instrumentation, were accomplished through this minimally invasive technique.of findings: Seventy-three percent of the fractures were located at the thoracolumbar junction. In 49% of cases, mobilization of the diaphragm was performed to expose the fracture with subsequent repair. Both radiographic canal compromise with neural deficit was present in 15% of patients. In 35% of cases, a stand-alone anterior thoracoscopic reconstruction was performed. For cases of greater instability, this was supplemented with a posterior pedicle-screw construct in 65% of patients. A steep learning curve was present with an average operating room time of 300 minutes in the first 50% of cases and a recent average of 180 minutes with use of the MACS-TL system. The severe complication rate was low (1.3%) with one case each of aortic injury, splenic contusion, neurological deterioration, cerebrospinal fluid leak and severe wound infection. Compared with a group of 30 patients treated with open thoracotomy, thoracoscopically treated patients used 42% less narcotics in the postoperative period.Relationship between findings and existing knowledge: Compared with the reported rates of complications and morbidity for open thoracotomy in the literature, our results are on par with, if not lower than, the published data.Overall significance of findings: A complete anterior thoracoscopically assisted reconstruction of thoracic and thoracolumbar fractures can be safely and effectively accomplished, thereby reducing the pain and morbidity associated with conventional thoracotomy and thoracolumbar approaches. Although a steep learning curve is present, the functional and cosmetic benefits to the patient warrant the difficult training process.Disclosures: Device or drug: MACS-TL plating system. Status: approved.Conflict of interest: Larry Khoo, grant research support.

Thoracoscopic microdiscectomy.

The thorascopic approach for the microsurgical removal of herniated thoracic discs is described, and perioperative management is also discussed. The microsurgical techniques used for decompression of the spinal canal in the thoracic spine are presented in detail. The diagnostic imaging, surgical positioning, approach, port placement, localization of the thoracic level, exposure of the surgical field, excision of the rib head, exposure with removal of the herniated disc, and postoperative management are outlined. Surgical and operative "pearls" in thoracoscopic spinal surgery for removing herniated thoracic discs when possible are described and illustrated.

Thoracoscopic spine surgery: current indications and techniques.

The first report of thoracoscopic surgery was in 1910, after Jacobaeus used thoracoscopy to lyse tuberculous lung adhesions. However, it was not until the end of the century that Lewis (1991) recognized the value of thoracoscopic surgery, and Mack (1993) reported the application of video-assisted thoracic surgery (VATS) for spine surgery. VATS is still in its infancy and the application of this technology for spine surgery continues to rapidly expand. The current indications for thoracoscopic spine surgery include tissue biopsies, thoracic paravertebral abscess drainage and debridement, thoracic disc herniation excisions, anterior spinal release and/or fusion for spinal deformity, stabilization and fusion of thoracic and thoracolumbar fractures, corpectomy for vertebral tumors, and the placement of anterior spinal instrumentation with fusion. This article reviews these current indications for VATS--the technique and subsequent nursing implications.

A new system for the anterior restoration and fixation of thoracic spinal deformities using an endoscopic approach.

A report on the results of animal experiments in which the authors' new system that enables the anterior correction and fixation of thoracic spinal deformity by use of a thoracic endoscope and small incisions was used. The results suggest that the new approach involving thoracoscopic anterior correction and fusion for thoracic spinal deformity could be adapted successfully for the clinic. To develop a new system that enables the anterior correction and fixation of thoracic spinal deformity by use of a thoracic endoscope and small incisions. Anterior correction and fusion through open thoracotomy have been applied mainly for thoracic scoliosis because this approach provides effective correction with short fusion. However, excellent visualization of the spine during thoracic surgical procedures led to the development of thoracoscopic spine surgery. Therefore, the authors postulated that a thoracoscopic approach could allow not only discectomy but also correction and fusion of the deformed thoracic spine in a single surgical event. The vertebral columns and attached thoracic walls were dissected from fresh porcine cadavers and used in the experimental surgery to evaluate the new system. As a next step, thoracoscopic surgery using this new system was performed on four or five vertebrae of five live pigs with an average weight of 50 kg. Initially, the discs and rib heads were removed through the thoracic wall. For each vertebra, a screw connected to a shaft used as a screw holder was inserted through the thoracic wall in a posterior to anterior direction. Each shaft then was linked outside the body to an outrigger. This outrigger was used to both create and restore scoliosis. A rod then was introduced through the thoracic wall and fixed to the screw heads. The animal experiments clearly showed that it was possible to change the Cobb angles of the spine through the use of the outrigger apparatus. In cadaver experiments, it was possible to create scoliosis and re-store it by 25 degrees to 35 degrees. Also, surgery on live pigs resulted in scoliosis of approximately 30 degrees, which means approximately 5 degrees to 10 degrees for each disc space. The procedures used also demonstrated that it was possible to fix a rod, introduced into the pleural cavity through a port, with screw heads. The use of this system successfully changed the Cobb angle of the spine, which suggests that its use should make it possible to correct spinal deformities. This apparatus also succeeded in fixing the rods in the screw heads, which raises the possibility of its use in spinal fixation. The authors believe that this apparatus could be adapted successfully for clinical use. Studies currently are under way in clinics using the new system.