Laminectomy with Rib Shears: A Technical Note.

Introduction: Laminectomy/laminoplasty either free or vascularized pedicle flap is currently performed with a variety of expensive instruments. Use of Tudor Edwards rib shears to perform above procedure is described. Materials and Methods: Tudor Edwards rib shear was used to cut lamina in 18 cases for a variety of spinal lesions. Depending upon the size of lesion, laminectomy/laminoplasty was required for 2 to 8 levels. Vascularized pedicle laminoplasty or free flap laminoplasty was done with Tudor Edwards rib shears. Ligamentum flavum and interspinous and supraspinous ligaments were preserved in cases of vascularized pedicled laminoplasty, which was carried out in 12 cases. Free flap laminoplasty was carried out in 6 cases. Results: In all our cases, laminectomy was successfully achieved with rib shears without any injury to the dura or its underlying structures. It was possible to perform vascularized pedicle laminoplasty or free flap laminoplasty in all cases. Laminectomy was easier to perform in the cervical region and dorsal region, while it was difficult in the lumbar region due to the wider, thick lamina and its angulation, especially in adults. Conclusion: Laminectomy/laminoplasty with Tudor Edwards rib shears is quick, safe, and easy. Beveled cut edges with minimal bony loss prevents sinking of laminoplasty, thereby facilitates lamina fixation. This is an alternative method of performing laminectomy/laminoplasty, especially for those not having accessibility to expensive equipment.

Antegrade Subperiosteal Temporalis Muscle Elevation and Posterior Retraction Technique Avoiding Muscle Incision for Pterional Craniotomy: A Technical Note.

Background: The current technique of pterional craniotomy involves temporalis muscle incision followed by retrograde elevation. Feasibility of antegrade temporalis muscle elevation without any direct incision over its bulk is evaluated. Objective: Incisionless "antegrade, subgaleal, subfascial, and subperiosteal elevation" of temporalis muscle preserves vascularity and muscle bulk. Posterior maneuvering of "bare" temporalis muscle bulk either above (out rolling) or under (in rolling) the scalp for pterional craniotomy is discussed. Material and Methods: Technique of antegrade, subfascial, subperiosteal elevation, and posterior rotation of temporalis muscle without incising in its bulk by "out rolling" or "in rolling" along the posterior aspect of the scalp incision was carried out in 15 cadavers and later in 50 surgical cases undergoing pterional craniotomy. Postoperatively, patients were evaluated for subgaleal collection and periorbital edema. Operated side cosmesis and temporalis muscle bulk was compared with nonoperated temporalis muscle at 6 months interval. Results: Antegrade subperiosteal dissection of temporalis muscle was possible in all cases. "In-rolling" or "out rolling" technique provided adequate surgical exposure during pterional craniotomy. Postoperative subgaleal collection and periorbital edema was prevented. Facial nerve paresis or temporalis muscle-related complications were avoided. Conclusion: Antegrade, subgaleal, subfascial, and subperiosteal dissection techniques of temporalis muscle elevation without any direct incision in its bulk enables neurovascular and muscle volume preservation. Posterior maneuvering of elevated temporalis muscle with "out rolling" or "in-rolling" technique is easy, quick, and provides adequate exposure during pterional craniotomy. Opening and closing of scalp layers without violating subgaleal space prevent postoperative subgaleal hematoma and periorbital edema.

Anchoring the Temporalis Muscle with an Intact Fascial Layer Along the Superior Temporal Line in Pterional Craniotomy: A Technical Note.

BACKGROUND: Manipulation of the temporalis muscle during pterional and frontotemporal approaches poses major cosmetic and functional issues postoperatively. The temporalis muscle has usually been secured in its normal position using implants or by leaving a thin rim of muscle and fascia attached along the superior temporal line. In the present report, we have described a pure tissue-based method of anchoring the intact temporalis muscle precisely along the superior temporal line. METHODS: A total of 30 consecutive cases of pterional or frontotemporal craniotomy were performed by single surgeon (SKR). A subfascial dissection technique was used to expose the transition zone of the frontal pericranium with the temporalis fascia. These were then separated by sharp dissection along the superior temporal line at which the muscle is attached. The temporalis muscle and fascia were repositioned during closure, precisely at their original anatomical location by passing multiple anchoring sutures along the free edge of the muscle and fascia lying along the superior temporal line. RESULTS: Temporalis muscle reattachment was achieved in all 30 cases with good cosmesis and functional outcome without temporalis muscle-related complications at 6 months of follow-up. CONCLUSIONS: The approximation of sutures running through the free edge of the temporalis muscle with intact fascia along the superior temporal line from anteriorly to posteriorly restored the muscle and fascial layer to its original position. Avoidance of the formation of any potential dead space during surgical exposure will prevent periorbital edema and/or subgaleal collection postoperatively. The described inexpensive technique avoids implant-related complications, with good functional and aesthetic outcomes. A comparative study is needed to establish the superiority of this procedure over other techniques.

Lumbar canal stenosis in "young" - How does it differ from that in "old" - An analysis of 116 surgically treated cases.

OBJECTIVE: Patients treated for lumbar canal stenosis (LCS) were retrospectively analyzed to evaluate the differences in clinical management in those below (Group A) and those above (Group B) the age of 50 years. All patients were treated with the premise that instability is the nodal point of the pathogenesis of LCS and "only-stabilization" is the surgical treatment. MATERIALS AND METHODS: During the period June 2014 to June 2020, 116 cases were diagnosed to have LCS and surgically treated by the Goel modification of Camille's transarticular screw fixation technique. RESULTS: Twenty-four patients in Group A and six patients in Group B had a history of "significant" injury to the back at the onset of clinical symptoms. The indices suggested that the intensity of symptoms was relatively more severe in Group A than in Group B. Unilateral leg symptoms were more common in Group A (68%) than in Group B (31.8%). Neurological motor deficits were more common in Group A (28%) than in Group B (12%) patients. Spinal segments surgically treated in Group A ranged from 1 to 4 (average 2 levels) and in Group B it ranged from 2 to 5 (average 3 levels). During the follow-up period that ranged from 6 to 72 months (average 37 months), 100% of patients had varying degrees of relief from symptoms. CONCLUSIONS: LCS is confined to a lesser number of spinal segments in the Group A patients. The symptoms were radicular in nature and relatively severe in Group A than in Group B patients.

Rotatory atlantoaxial dislocation presenting as spinal kyphoscoliosis.

A 16-year-old male presented with primary complaint of worsening dorsal spinal kyphoscoliosis (SKS) for 3 years. More recently, he developed spasticity in legs, breathlessness on mild exertion, and sleep apneas. Apart from SKS, investigations revealed rotatory atlantoaxial dislocation. Atlantoaxial fixation resulted in rapid recovery from all symptoms including from spinal deformity. Observations in this patient suggest that rotatory dislocation can be a cause of spinal deformity.

Silent stellate ganglion paraganglioma masquerading as schwannoma: A surgical nightmare.

A 28-year-old normotensive female presented with Horner's syndrome and paresthesia over the left side of the chest. Imaging study showed a large heterogeneous enhancing lesion in short-T1 inversion recovery sequence with flow voids in T2W sequence of magnetic resonance imaging. The lesion was located in the left-sided D1 and D2 regions extending into the neural foramina and apical part of the lung. During surgery, even minimal dissection of the tumor resulted in marked fluctuation in hemodynamic parameters, requiring temporary suspension of the surgery multiple times until hemodynamic parameters were brought under control by the anesthesiologist with drugs. The massive fluctuation in hemodynamic parameters in an unprepared and unanticipated scenario was a challenge for the anesthetist and surgeon. The tumor was radically excised with improvement of paresthesia in the immediate postoperative period, but Horner's syndrome persisted. After 18-months of follow-up, she was relieved of all symptoms including Horner's syndrome. Histopathological examination confirmed our suspicion as paraganglioma.

Modified Ipsilateral Endonasal Endoscopic Trans-Sphenoidal Approach to Sphenoid Sinus Lateral Recess Cerebrospinal Fluid Leak Management in Two Cases: A Technical Note.

Background Cerebrospinal fluid (CSF) leak from the sphenoid sinus lateral recess (SSLR) is very rare. Majority prefer transpterygoid approach which is extensive and time consuming. Two such cases were managed with least possible dissection/destruction of paranasal sinus. Methods Two cases of SSLR were accessed through the ipsilateral nostril from the side of CSF leak. Wide ipsilateral anterior sphenoidotomy was done preserving intersinus septum of sphenoid sinus. Middle turbinate was lateralized and remaining paranasal structures were preserved. Two handed single nostril approach was done in both the cases by 45- and 70-degree endoscope along with angled instruments. SSLR defects were visualized and packed with autologous fat graft and glue. Results SSLR defects could be visualized and packed with fat graft in both the cases from ipsilateral side. Both cases had uneventful outcome with no leak with mean -follow-up of 11.5 months. Conclusion Modified ipsilateral endonasal endoscopy trans-sphenoidal approach is least invasive technique for SSLR leak. Use of angled scope and instruments help in defect visualization, avoiding extensive paranasal sinus dissection and bony removal. Tedious time-consuming reconstructive procedures can be avoided with simple fat graft with good outcome.

Optimizing Burr Hole Placement for Craniotomy: A Technical Note.

Objective Usually, burr holes are placed along the line of a craniotomy. We describe a novel technique of burr hole placement to obtain smooth and beveled bony margin without any troughs and crests. Dural separation is obtained by minimizing the number of burr holes required. Methods Fifty craniotomies of diameter ranging from 3.5 to 11.5 cm were accomplished by placing burr hole in the center of bone flap rather than along the craniotomy line permitting 360 degrees of dura separation dependent on the length of dura separator. Craniotomy < 9  cm in diameter was performed by placing a single burr hole and a larger size craniotomy was performed with two burr holes. Parasagittal craniotomy was performedby placing burr hole not > 2.5  cm away from expected craniotomy site, namely superior sagittal sinus area enabling separation of adhered dura and venous sinuses. The bone cutter was used in a particular fashion to create smooth margin and beveled edges. Results Craniotomy < 9  cm in diameter was possible with single burr hole in 34 cases. Craniotomy larger than 9  cm in size was performed in 16 cases with double burr hole by strategically placing burr in the center of the desired bone flap. The craniotomy was achieved in all cases without damaging dura and venous structures. Conclusions An optimally placed single burr hole is sufficient for small to moderately large size craniotomy. Larger size craniotomy is possible with minimum numbers of burr holes. This achieves good cosmesis and avoids sinking of the bone flap.

Brain Tumor Interface Dissection Technique with Surgical Blade from Laboratory to Neurosurgical Operating Room.

BACKGROUND: Ideal tumor resection requires brain/spinal cord tumor interface separation in perfect and precise surgical planes within a few micrometers for radical tumor resection and maximum normal tissue preservation. Despite the availability of several dissection techniques, the search for additional alternatives and an ideal technique continues. We evaluated the feasibility and advantages of dissection using a No. 15-blade scalpel in special brain tumor surgery situations. We developed a leaf model wherein its outer layer is progressively dissected from its inner skeleton using a scalpel. An additional model used was a tomato wherein its skin was peeled off its pulp using the same technique. OBJECTIVE: We developed an inexpensive leaf model. A scalpel knife was used in a microneurosurgical setting, and the leaf's outer layer is peeled off. The technique is then used in an operating room setup where surgery on extra-axial tumors like meningiomas and intra-axial brain and spinal cord tumors is done. METHODS: A No. 15 scalpel was used for dissection between the layers of the Peltophorum pterocarpum leaf model. This dissection method was compared with other neurosurgical dissecting tools. RESULTS: We dissected 120-µm thick leaves into 2 layers with removal of an 18- to 55-µm thick layer. Leaving behind a transparent layer was possible using a No. 15 blade scalpel. Similarly, it was possible to preserve a 35- to 40-µm thick arachnoid layer that separated a meningioma from the underlying brain parenchyma. CONCLUSION: A scalpel with a sharp edge could be used to perform precise and fine dissection. The scalpel deserves to occupy a place of pride as a dissecting tool in neurosurgery.

Volume change theory for syringomyelia: A new perspective.

BACKGROUND: The etiopathogenesis of syringomyelia is still an enigma. The authors present a novel theory based on fluid dynamics at the craniovertebral (CV) junction to explain the genesis of syringomyelia (SM). The changes in volume of spinal canal, spinal cord, central canal and spinal subarachnoid space (SSS) in relation to the posterior fossa have been analysed, specifically during postural movements of flexion and extension. The effect of fluctuations in volume of spinal canal and its contents associated with cerebrospinal fluid (CSF) flow dynamics at the CV junction have been postulated to cause the origin and propagation of the syringomyelia. The relevant literature on the subject has been reviewed and the author's theory has been discussed. CONCLUSION: Volume of spinal canal in flexion is always greater than that in extension. Flexion of spine causes narrowing of the ventral subarachnoid space (SAS) and widening of dorsal SAS while extension causes reverse changes leading to fluid movement in dorsal spinal SAS in flexion and ventral spinal SAS in extension. Cervical and lumbar spinal region with maximum bulk hence maximum area and volume undergo maximum deformation during postural changes. SSS CSF is the difference between the volume of spinal canal and spinal cord, varies in flexion and extension which is compensated by changes in posterior fossa (CSF) volume in normal circumstances. Blocked SAS at foramen magnum donot permit spinal SAS CSF exchange which during postural changes is compensated by cavitatory/cystic (syrinx) change at locations in cervical and lumbar spine with propensity for maximum deformation. Augmentation of posterior fossa volume by decompression helps by normalization of this CSF exchange dynamics but immobilizing the spinal movement theoretically will cease any dynamic volume changes thereby minimizing the destructive influence of the fluid exchange on the cord. Thus, this theory strengthens the rational of treating patients by either methodology.