Abstract


Neurosurgical hemostasis can be performed with bipolar coagulation and with the support of several dedicated biomaterials including oxidized regenerated cellulose (ORC; e.g., Surgicel®, Johnson & Johnson, New Brunswick, NJ, USA). Oxidized regenerated cellulose is a sterile absorbable fibrous biomaterial that has become a major local hemostatic agent thanks to its ease of use, favorable biocompatibility and bioabsorption characteristics. However, some postoperative issues associated with its use, such as allergic reaction, seroma, foreign-body reaction with compressive neuropathies and misdiagnosis during follow-up, have been reported. These complications could compromise clinical outcomes with a negative impact on patient quality of life and sometimes require risky major surgical procedures. An understanding of the specific properties of ORC combined with adequate surgical expertise and compliance with some basic rules are needed to optimize clinical outcomes and minimize postoperative issues.

Abstract


Introduction: There is a steep learning curve for a successful posterior endoscopic cervical foraminotomy and discectomy (PECFD), an important surgery for cervical foraminal or lateral disc herniation, and cervical radiculopathy due to a small operation field. PECFD becomes even more challenging in patients who have prominent shoulders and/or short necks with C6–7-disc herniation, because of the difficulty to localize C6–7 vertebral structure under fluoroscopy.
The study objective is to prove that the PECFD can be performed safely and successfully to C6–7-disc herniation on patients with prominent shoulders and/or short necks following our novel surgical techniques under fluoroscopic guidance.
Materials and Methods: PECFD was performed on a patient who had an extruded foraminal disc herniation at C6–7 on the left with left arm pain and weakness. Due to his prominent shoulders and a short neck, the C6–7 anatomic site was not visible under traditional anterior-posterior (AP) and lateral fluoroscopic views. The authors inserted a reference needle to C4–5 facets between C4 and C5 pedicles under AP and lateral fluoroscopic views. Following the reference needle, the C6–7 facets were easily located with an oblique fluoroscopic view. A large endoscopic cannula was used initially for adequate resection of C6–7 facets, followed by a small cannula for nerve root handling with minimal pressure and discectomy.
Results: The novel surgical techniques resulted in a complete resection of the C6–7-disc herniation and resolution of the patient’s radiculopathy with no postoperative complications.
Conclusion: PECFD can be safely and successfully applied for C6–7-disc herniation in patients with prominent shoulders and/or short necks using our novel surgical techniques.

Abstract


Peripheral nerve stimulation (PNS) electrodes are used to treat intractable painful conditions involving peripheral nerves. Methods for performing PNS continue to evolve, from open surgical to minimally invasive placement of electrodes. A PNS system consisting of subcutaneously implanted leads with an integrated anchor and electrodes, and an external pulse generator to produce peripheral neuromodulation, is now available for use in the clinical setting. This novel system allows either surgical or percutaneous lead positioning, and avoids the use of long leads or extensions crossing the joints, which are exposed to mechanical stress and damage. To identify methods for successfully inserting these electrodes, we investigated if a cadaver model could be an effective educational tool for teaching PNS electrode placement using ultrasound guidance. Six cadavers were studied in an attempt to find an ideal approach for ultrasound-guided electrode placement into the upper and lower extremities and cervical spine, and to describe the unique anatomy of the peripheral nerves relative to percutaneous stimulation-electrode placement. The use of cadaveric model simulations offers opportunities to practice percutaneous placement of PNS electrodes under stress-free conditions without patient discomfort, to acquire skill and confidence in performing these surgical approaches. Ultrasound-guided percutaneous placement of PNS electrodes should be learned in a simulation laboratory before such placement is performed in actual patients.