Refractory sphenoid wing osteomyelitis as a complication of orbital decompression.

Osteomyelitis of the sphenoid wing is a rare clinical entity that can result in significant morbidity due to cranio-orbital infection. This entity has never previously been described as a complication of orbital decompression. An elderly patient developed relapsing orbital cellulitis and cranio-orbital abscesses following orbital decompression. Multiple attempts at incision and drainage with extended antibiotic therapy failed to eliminate the infection. The patient's clinical course was indicative of sphenoid osteomyelitis at the prior decompression site. A combined craniotomy-orbitotomy with debridement of the involved portion of the sphenoid resulted in resolution of the patient's clinical symptoms. Surgeons should be aware of the possibility of this rare infection following any surgery in which bone is structurally modified or removed, including orbital decompression.

Outcomes following surgical intervention for acute hemorrhage in severe traumatic brain injury: a review of the National Trauma Data Bank.

OBJECTIVE: Severe traumatic brain injury (TBI) is a public health issue posing significant morbidity and mortality to afflicted patients. While the effect of time to surgery as the primary factor for survival has been extensively studied, long-term dispositional outcomes following intracranial hemorrhage evacuation have not been well described in the literature. Therefore, the aim of this study was to elicit potential prognostic factors in patients presenting with severe TBI that may have a significant impact on discharge disposition. METHODS: The authors searched the National Trauma Data Bank (NTDB) for patients included between 2010 and 2019, solely focusing on those with a Glasgow Coma Scale score ≤ 8, signifying severe TBI, and with associated intracranial hemorrhage treated via surgical intervention. Numerous characteristics were analyzed, including demographics (age, sex, race, ethnicity, payment status), discharge disposition, time to surgery, pupillary response, midline shift (> 5 mm), and postoperative inpatient complications and comorbidities. Disposition included routine discharge to home, discharge to home with home health services (HHSs), discharge to acute inpatient rehabilitation (AIR), discharge to a skilled nursing facility (SNF)/long-term acute care hospital (LTACH), and death. RESULTS: The authors analyzed data on 7308 patients, 69.6% of whom were White and 11.2% of whom were Black. More young Black and Hispanic patients had severe TBI events than their matched elders, whereas more elderly White patients had severe TBI events than their matched younger counterparts. The most common disposition across all ages was SNF/LTACH. Septuagenarians and octogenarians were 12.1 and 21 times more likely, respectively, to die following a severe TBI than their younger counterparts (p < 0.001). Patients aged 18-29 were 1.7 times more likely to be discharged with HHSs (p < 0.001). Minority race/ethnicity groups were less likely to be discharged to AIR. As age increased, a patient's intensive care unit stay increased by 15 days (p < 0.001) and total hospital length of stay increased by 25 days (p < 0.001). CONCLUSIONS: Neurosurgical evacuation of intracranial hemorrhage in severe TBI has variable long-term morbidity. Utilizing the largest collection of trauma data within the United States, the authors present quantitative evidence on discharge disposition. Understanding these tangible points can help neurosurgeons present potential outcomes to patients, promote preventative care, and generate tangible conversations with patients and their family members.

Nontraumatic Subarachnoid Hemorrhage and Ruptured Intracranial Aneurysm: Recognition and Evaluation.

Subarachnoid hemorrhage caused by a ruptured intracranial aneurysm is a neurosurgical emergency with a mortality rate of approximately 50%. Prompt identification and treatment of aneurysmal subarachnoid hemorrhage are paramount to reduce mortality, long-term morbidity, and health care burden for survivors. The prevalence of intracranial aneurysms is 2% to 6% of the global population, many of which are found incidentally during workup for an unrelated condition. Screening is not recommended for the general population and should be reserved for patients who have at least one family member with a history of intracranial aneurysm or subarachnoid hemorrhage or when there is a high index of suspicion for those with certain medical conditions associated with an increased incidence of intracranial aneurysms. Physicians who treat patients with headache should be aware of the spectrum of clinical presentation of aneurysmal subarachnoid hemorrhage because not all patients present with the classic thunderclap headache. The Ottawa Subarachnoid Hemorrhage Rule is a validated clinical decision tool to help determine which patients with a sudden, acute headache require imaging with noncontrast computed tomography. Based on the results of initial computed tomography and duration of symptoms, the patient may require a lumbar puncture or additional imaging to confirm the diagnosis. Prompt diagnosis of an aneurysmal subarachnoid hemorrhage is essential to patients receiving definitive treatment.

Answering Our Nation's Call: A Solution for Military Neurosurgery Wartime Readiness Through Civilian Collaboration.

Military-civilian partnerships have built the foundation for US neurosurgery as we see it today. Each conflict throughout history has led to expansion within the field of neurosurgery, benefiting civilian patients and those in uniform. Despite the field's growth during wartime, military neurosurgical case volume declines during peacetime, and as a result, important knowledge gained is at risk of being lost. The current landscape of military neurosurgery reflects the relative peacetime for the US-World relationship. Because of this peacetime, the surgical case volume and experience of the military neurosurgeon are declining rapidly. In addition to providing a history of military-civilian partnerships in neurosurgery, we have analyzed the declining case volume trends at a single military treatment facility with neurosurgical capabilities. We compared the case volume of a military neurosurgeon at a civilian partnered location with their previous volume at a military treatment facility and analyzed current trends in wartime readiness by Neurosurgery Knowledge, Skills and Abilities metrics. We believe that military civilian partnerships hold the key to scaffolding the experience to maintain the wartime readiness in the military neurosurgical community.

Evolution of spinal cord injury treatment in military neurosurgery.

During the mid-1900s, military medicine made historical advancements in the diagnosis, stabilization, and treatment of spinal cord injuries (SCIs). In particular, World War II was an inflection point for clinical practice related to SCIs because of the vast number of devastating injuries to soldiers seen during World War I (WWI). The unprecedented rate of SCI along with growth in the field served as a catalyst for surgical and interdisciplinary advancements through the increased exposure to this challenging pathology. Initially, a tragic fate was assumed for soldiers with SCIs in WWI resulting in a very conservative approach strategy given a multitude of factors. However, soldiers with similar injuries 20 years later saw improved outcomes with more aggressive management interventions by specialists in spine trauma, who applied measures such as spinal traction, arthrodesis, and internal fixation, and with the significant developments in the complex rehabilitation of these patients. This article describes the historical shift in the management of SCIs through the two world wars. These historical lessons of SCI and the fundamental advances in their neurosurgical intervention have molded not only military but also modern civilian treatment of SCI.

Diffusion Tensor Imaging Detects Acute and Subacute Changes in Corpus Callosum in Blast-Induced Traumatic Brain Injury.

There is a critical need for understanding the progression of neuropathology in blast-induced traumatic brain injury using valid animal models to develop diagnostic approaches. In the present study, we used diffusion imaging and magnetic resonance (MR) morphometry to characterize axonal injury in white matter structures of the rat brain following a blast applied via blast tube to one side of the brain. Diffusion tensor imaging was performed on acute and subacute phases of pathology from which fractional anisotropy, mean diffusivity, axial diffusivity, and radial diffusivity were calculated for corpus callosum (CC), cingulum bundle, and fimbria. Ventricular volume and CC thickness were measured. Blast-injured rats showed temporally varying bilateral changes in diffusion metrics indicating persistent axonal pathology. Diffusion changes in the CC suggested vasogenic edema secondary to axonal injury in the acute phase. Axonal pathology persisted in the subacute phase marked by cytotoxic edema and demyelination which was confirmed by ultrastructural analysis. The evolution of pathology followed a different pattern in the cingulum bundle: axonal injury and demyelination in the acute phase followed by cytotoxic edema in the subacute phase. Spatially, structures close to midline were most affected. Changes in the genu were greater than in the body and splenium; the caudal cingulum bundle was more affected than the rostral cingulum. Thinning of CC and ventriculomegaly were greater only in the acute phase. Our results reveal the persistent nature of blast-induced axonal pathology and suggest that diffusion imaging may have potential for detecting the temporal evolution of blast injury.

Direct enhancement of readiness for wartime critical specialties by civilian-military partnerships for neurosurgical care: residency training and beyond.

Military neurosurgery has played an integral role in the development and innovation of neurosurgery and neurocritical care in treating battlefield injuries. It is of paramount importance to continue to train and prepare the next generation of military neurosurgeons. For the Army, this is currently primarily achieved through the military neurosurgery residency at the National Capital Consortium and through full-time out-service positions at the Veterans Affairs-Department of Defense partnerships with the University of Florida, the University of Texas-San Antonio, and Baylor University. The authors describe the application process for military neurosurgery residency and highlight the training imparted to residents in a busy academic and level I trauma center at the University of Florida, with a focus on how case variety and volume at this particular civilian-partnered institution produces neurosurgeons who are prepared for the complexities of the battlefield. Further emphasis is also placed on collaboration for research as well as continuing education to maintain the skills of nondeployed neurosurgeons. With ongoing uncertainty regarding future conflict, it is critical to preserve and expand these civilian-military partnerships to maintain a standard level of readiness in order to face the unknown with the confidence befitting a military neurosurgeon.

Neurosurgical Emergencies in Sport.

Sports related severe brain and spinal cord injuries are medical and potentially surgical emergencies that require timely intervention in order to reduce worsening secondary injury. For this reason, it is important for all medical professionals managing athletic injuries to be knowledgeable in the clinical approach to this type of acute event. This article reviews the initial evaluation of the athlete that occurs on the field and also within the emergency department with a focus on presenting clinical signs of a neurosurgical emergency. We present a basic overview of the types of intracranial injuries requiring emergent neurosurgical intervention.

Reduction in Temporary and Permanent Audiological Injury Through Internal Jugular Vein Compression in a Rodent Blast Injury Model.

HYPOTHESIS: Internal jugular vein (IJV) compression influences not only intracranial but also intracochlear physiology and has demonstrated preclinical effectiveness in reducing acute audiological injury in a rodent blast model. However, the long-term effects in this model are unknown. BACKGROUND: Blast wave-induced audiological injury from an improvised explosive device is a leading cause of morbidity among service members in theater but there are limitations to the current protective measures. METHODS: For this study, we exposed 20 Sprague Dawley rats to a 16.8 ±â€Š0.3 PSI (195.3 dB SPL) right-sided shock wave in which 10 had application of a custom IJV compression collar in place at the time of injury. RESULTS: IJV compression at the time of injury was shown acutely to significantly reduce the incidence of tympanic membrane rupture and the initial temporary threshold shift on otoacoustic emissions in both the right and left ears of animals who had collar application immediately after and 7 days post injury. At 28 days from injury, collared animals demonstrated a return to baseline of otoacoustic emission values while the noncollared animals had persistent threshold shifts, signifying the presence of a permanent threshold shift only in those animals without collar application. IJV compression was also found to significantly reduce hair cell loss at the base of the cochlea secondary to mechanical trauma from the blast wind. CONCLUSION: Previously observed acute protective effects of IJV compression are sustained at chronic time points. IJV compression can potentially be used to reduce long-term permanent morbidity from blast-induced audiological trauma.

Internal Jugular Vein Compression: A Novel Approach to Mitigate Blast Induced Hearing Injury.

HYPOTHESIS: Internal jugular vein (IJV) compression before blast injury will lead to reduced risk of traumatic hearing injury following exposure to a blast injury. BACKGROUND: IJV compression and its effects on not only intracranial, but also intracochlear pressure may potentiate blast induced hearing injury, therefore, precluding its use as a prophylactic therapy for blast induced traumatic brain injury. METHODS: Twenty Sprague Dawley rats were exposed to a 17.9 ±â€Š0.4 PSI (195.8 dB SPL) right sided shock wave in which 10 had application of a custom IJV compression collar before injury. All rodents received baseline and post blast injury otoacoustic emission (OAE) and auditory brainstem response (ABR) testing followed by cochlear histology. RESULTS: IJV compression was shown to significantly reduce ABR and OAE threshold shifts in comparison to the non-intervention group by: 14.9 ±â€Š4.8 dB (right ear ABR 0.5 kHz Day 1 post blast, p = 0.01), 13.1 ±â€Š4.9 dB (right ear ABR 4 kHz Day 1 post blast, p = 0.04), 16.5 ±â€Š4.5 dB (right ear ABR click Day 1 post blast, p = 0.003), 12.1 ±â€Š4.6 dB (right ear ABR click Day 6 post blast, p = 0.04), and 14.0 ±â€Š3.2 dB (both ears OAE 3.2-10 kHz, p < 0.0001). Also, those animals with collar application had a greater number of total hair cells per mm from 70 to 100% distance from the cochlear apex following blast injury in comparison to those without intervention (blast: 211.8 ±â€Š27.5 versus blast+collar: 355.5 ±â€Š39.5 [p = 0.0002]). CONCLUSION: This study supports the use of IJV compression in a pre-clinical model as a new prophylactic mechanism to combat blast induced hearing injury.

Effect of Internal Jugular Vein Compression on Intracranial Hemorrhage in a Porcine Controlled Cortical Impact Model.

Internal jugular vein (IJV) compression has been shown to reduce axonal injury in pre-clinical traumatic brain injury (TBI) models and clinical concussion studies. However, this novel approach to prophylactically mitigating TBI through venous congestion raises concerns of increasing the propensity for hemorrhage and hemorrhagic propagation. This study aims to test the safety of IJV compression in a large animal controlled cortical impact (CCI) injury model and the resultant effects on hemorrhage. Twelve swine were randomized to placement of a bilateral IJV compression collar (CCI+collar) or control/no collar (CCI) prior to CCI injury. A histological grading of the extent of hemorrhage, both subarachnoid (SAH) and intraparenchymal (IPH), was conducted in a blinded manner by two neuropathologists. Other various measures of TBI histology were also analyzed including: ß-amyloid precursor protein (ß-APP) expression, presence of degenerating neurons, extent of cerebral edema, and inflammatory infiltrates. Euthanized 5 h after injury, the CCI+collar animals exhibited a significant reduction in total SAH (p = 0.024-0.026) and IPH scores (p = 0.03-0.05) compared with the CCI animals. There was no statistically significant difference in scoring for the other markers of TBI (ß-APP, neuronal degeneration, cerebral edema, or inflammatory infiltration). In conclusion, IJV compression was shown to reduce hemorrhage (SAH and IPH) in the porcine CCI model when applied prior to injury. These results suggest the role of IJV compression for mitigation of not only axonal, but also hemorrhagic injury following TBI.

Brainstem Monitoring in the Neurocritical Care Unit: A Rationale for Real-Time, Automated Neurophysiological Monitoring.

Patients with severe traumatic brain injury or large intracranial space-occupying lesions (spontaneous cerebral hemorrhage, infarction, or tumor) commonly present to the neurocritical care unit with an altered mental status. Many experience progressive stupor and coma from mass effects and transtentorial brain herniation compromising the ascending arousal (reticular activating) system. Yet, little progress has been made in the practicality of bedside, noninvasive, real-time, automated, neurophysiological brainstem, or cerebral hemispheric monitoring. In this critical review, we discuss the ascending arousal system, brain herniation, and shortcomings of our current management including the neurological exam, intracranial pressure monitoring, and neuroimaging. We present a rationale for the development of nurse-friendly-continuous, automated, and alarmed-evoked potential monitoring, based upon the clinical and experimental literature, advances in the prognostication of cerebral anoxia, and intraoperative neurophysiological monitoring.