Correlation of Electrodiagnostic Findings in C8 Radiculopathies With Radiographic Data: A Retrospective Chart Review.

ABSTRACT: Signs and symptoms of a C8 radiculopathy could mimic common comorbidities such as entrapment and peripheral neuropathies. These conditions and a C8 radiculopathy both can result in abnormal findings on needle examination of intrinsic hand muscles. It was hypothesized that needle examination of C8-innervated muscles in the forearm might improve concordance with magnetic resonance imaging (MRI) in the presence of underlying comorbidities. A retrospective analysis of electromyogram and C-spine MRI data in 80 patients with negative MRI of C-spine for C8-T1 neuroforaminal stenosis was performed. The percentage of false-positive results in the MRI-negative group undergoing electromyogram testing for hand and forearm muscles (MRI-NH + F) was 3% compared with 18% (P = 0.06) in the group with electromyogram of the hand intrinsic muscles only (MRI-NH). The false-positive result tends to be lower in the MRI-NH + F group in comparison with the MRI-NH group especially in the presence of underlying peripheral and entrapment neuropathies.

Identifying biopsychosocial factors that impact decompressive laminectomy outcomes in veterans with lumbar spinal stenosis: a prospective cohort study.

ABSTRACT: One in 3 patients with lumbar spinal stenosis undergoing decompressive laminectomy (DL) to alleviate neurogenic claudication do not experience substantial improvement. This prospective cohort study conducted in 193 Veterans aimed to identify key spinal and extraspinal factors that may contribute to a favorable DL outcome. Biopsychosocial factors evaluated pre-DL and 1 year post-DL were hip osteoarthritis, imaging-rated severity of spinal stenosis, scoliosis/kyphosis, leg length discrepancy, comorbidity, fibromyalgia, depression, anxiety, pain coping, social support, pain self-efficacy, sleep, opioid and nonopioid pain medications, smoking, and other substance use. The Brigham Spinal Stenosis (BSS) questionnaire was the main outcome. Brigham Spinal Stenosis scales (symptom severity, physical function [PF], and satisfaction [SAT]) were dichotomized as SAT < 2.42, symptom severity improvement ≥ 0.46, and PF improvement ≥ 0.42, and analyzed using logistic regression. Sixty-two percent improved in 2 of 3 BSS scales (ie, success). Baseline characteristics associated with an increased odds of success were-worse BSS PF (odds ratio [OR] 1.24 [1.08-1.42]), greater self-efficacy for PF (OR 1.30 [1.08-1.58]), lower self-efficacy for pain management (OR 0.80 [0.68-0.94]), less apparent leg length discrepancy (OR 0.71 [0.56-0.91]), greater self-reported alcohol problems (OR 1.53 [1.07-2.18]), greater treatment credibility (OR 1.31 [1.07-1.59]), and moderate or severe magnetic resonance imaging-identified central canal stenosis (OR 3.52 [1.06-11.6]) moderate, OR 5.76 [1.83-18.1] severe). Using opioids was associated with lower odds of significant functional improvement (OR 0.46 [0.23-0.93]). All P < 0.05. Key modifiable factors associated with DL success-self-efficacy, apparent leg length inequality, and opioids-require further investigation and evaluation of the impact of their treatment on DL outcomes.

Recognizing false ischemic penumbras in CT brain perfusion studies.

Computed tomography (CT) plays a pivotal role in the diagnosis of acute stroke and in treatment decision making. CT perfusion imaging performed with intravenous iodinated contrast material allows calculation of the time to peak enhancement, mean transit time, and cerebral blood volume, important parameters for differentiating between an ischemic penumbra, which might benefit from intravascular therapy with thrombolytic agents, and infarcted tissue, which would not benefit from such therapy. Differentiation between the two entities is important because thrombolytic therapy is associated with an increased risk for intracranial hemorrhage. A finding of delay in peak enhancement or increased mean transit time in a region with normal or only slightly abnormal cerebral blood volume is suggestive of an ischemic penumbra; however, accurate interpretation of the CT perfusion parameters may be difficult in the presence of a cerebrovascular anatomic variant or physiologic condition that produces benign oligemia leading to a false appearance of penumbra. For this reason, CT perfusion parameters must be correlated with the clinical history and findings at unenhanced head CT, angiography or CT angiography, and diffusion-weighted magnetic resonance imaging. The authors identify five possible causes of false penumbras, each of which produces a different pattern at imaging: upstream flow restriction, evolution of ischemic change, vascular dysregulation, positioning of the patient's head at an angle during image acquisition, and variant anatomy in the circle of Willis. Familiarity with the imaging patterns and causes of false penumbras may increase the radiologist's confidence in diagnosis and help avoid costly errors in treatment.

Improving stroke alert response time: applying quality improvement methodology to the inpatient neurologic emergency.

BACKGROUND: Stroke often leaves its victims with devastating disabilities if not treated promptly. Guidelines recommend that brain imaging be obtained within 25 minutes, yet this benchmark is rarely achieved for the in-hospital stroke. PURPOSE: To reduce time to evaluation for strokes occurring in patients already hospitalized, through systematic analysis of current processes and application of standardized quality improvement methodology. METHODS: Improving the quality of care for in-hospital stroke patients involved 4 key steps: (1) creation of a detailed process map to identify inefficiencies in the current process for identifying and treating hospitalized stroke patients, (2) development of an optimized care pathway, (3) implementation of a checklist of optimal practices for the acute stroke response team and nursing staff, and (4) real-time feedback. Time from stroke alert to initiation of computed tomography (CT) scan was prospectively tracked for the 6-month period prior to intervention. After a 3-month interval for intervention roll-out, the response times for the pre-intervention period were compared to a 6-month post-intervention evaluation period. RESULTS: Pre-intervention median inpatient stroke alert-to-CT time was 69.0 minutes, with 19% meeting the goal of 25 minutes from alert to CT time. Post-intervention median inpatient stroke alert-to-CT time was reduced to 29.5 minutes, with 32% at goal (P < 0.0001). CONCLUSIONS: This inpatient stroke alert quality improvement initiative decreased median inpatient alert-to-CT time by 57%, and demonstrated that speed of in-hospital stroke evaluation can be improved through systematic application of quality improvement principles.

Stroke alert program improves recognition and evaluation time of in-hospital ischemic stroke.

An inpatient stroke alert program is effective in decreasing evaluation time for in-hospital strokes, although response times remain significantly longer than those in the emergency department. It is capable of increasing the percentage of ischemic strokes identified by the hospital's stroke team, at the cost of an increased percentage of false alarms.

Proximal nerve root spinal hemangioblastomas: presentation of three cases, MR appearance, and literature review.

BACKGROUND: Hemangioblastomas (HBLs) are relatively uncommon tumors of uncertain histogenesis usually located in the cerebellum or spinal cord. Much less frequently they are identified in extramedullary locations including the filum terminale, proximal nerve roots, or even distal nerves of the peripheral nervous system (PNS). PNS cases not only present diagnostic challenges but also raise interesting questions regarding the common cell of origin for these CNS and PNS neoplasms. Few studies have detailed the neuroimaging characteristics of the rare extramedullary variants. METHODS: Neuroimaging and intraoperative findings of three recent cases of proximal nerve root HBLs are described. The English language literature on extramedullary HBLs is reviewed and discussed, particularly in regards to magnetic resonance (MR) findings and association with von Hippel-Lindau Syndrome (VHL). RESULTS: All 3 of our cases had prominent vessels present within the subarachnoid space on MR scans and all lesions enhanced. All were of intermediate or mildly decreased signal intensity on the T1-weighted images before contrast and were either iso- or hyperintense to spinal cord on the T2-weighted images. Two had probable cystic areas on MR, and all had cystic areas on histologic evaluation. CONCLUSION: These neuroimaging characteristics can serve to distinguish HBLs from the more common benign nerve sheath tumors with which they are most frequently confused. Less than half of all extramedullary HBLs are diagnosed in patients with known VHL. It is important to consider HBLs in the differential diagnosis, as they are vascular and have the propensity for causing significant blood loss at surgery.