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An important challenge for neural prosthetics research is to record from populations of neurons over long periods of time, ideally for the lifetime of the patient. Two new advances toward this goal are described, the use of local field potentials (LFPs) and autonomously positioned recording electrodes. LFPs are the composite extracellular potential field from several hundreds of neurons around the electrode tip. LFP recordings can be maintained for longer periods of time than single cell recordings. We find that similar information can be decoded from LFP and spike recordings, with better performance for state decodes with LFPs and, depending on the area, equivalent or slightly less than equivalent performance for signaling the direction of planned movements. Movable electrodes in microdrives can be adjusted in the tissue to optimize recordings, but their movements must be automated to be a practical benefit to patients. We have developed automation algorithms and a meso-scale autonomous electrode testbed, and demonstrated that this system can autonomously isolate and maintain the recorded signal quality of single cells in the cortex of awake, behaving monkeys. These two advances show promise for developing very long term recording for neural prosthetic applications.

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The implantation of chronic recording electrodes in the brain has been shown to be a valuable method for simultaneously recording from many neurons. However, precise placement of these electrodes, crucial for successful recording, is challenging if the target area is not on the brain surface. Here we present a stereotaxic implantation procedure to chronically implant bundles of recording electrodes into macaque cortical sulci, employing magnetic resonance (MR) imaging to determine stereotaxic coordinates of target location and sulcus orientation. Using this method in four animals, we recorded simultaneously the spiking activity and the local field potential from the parietal reach region (PRR), located in the medial bank of the intraparietal sulcus (IPS), while the animal performed a reach movement task. Fifty percent of all electrodes recorded spiking activity during the first 2 post-operative months, indicating their placement within cortical gray matter. Chronic neural activity was similar to standard single electrode recordings in PRR, as reported previously. These results indicate that this MR image-guided implantation technique can provide sufficient placement accuracy in cortical sulci and subcortical structures. Moreover, this technique may be useful for future cortical prosthesis applications in humans that require implants within sulci.

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OBJECTIVE: Repair of a cerebrospinal fluid (CSF) leak created at the time of transsphenoidal surgery typically involves placement of a fat, fascial, or muscle graft and sellar floor reconstruction. In this report, a simplified repair for small, "weeping" CSF leaks using collagen sponge is described. METHODS: All patients underwent an endonasal transsphenoidal procedure using the operating microscope. At the completion of tumor removal, if a small CSF leak was noted but no obvious large arachnoidal defect was present, a piece of collagen sponge was fashioned to cover the exposed diaphragma sellae. Titanium mesh was then wedged into the intrasellar, extradural space and a larger piece of collagen was placed over the reconstructed sellar floor. Nasal packing was removed within 24 hours. RESULTS: During an 18-month period, 62 consecutive transsphenoidal procedures were performed for tumor removal. Of 20 patients with a small CSF leak (18 pituitary adenomas, 1 Rathke's cleft cyst, and 1 chordoma), all had successful repair with collagen sponge. At follow-up examinations at 1 to 18 months, no patient had required a lumbar drain or had developed meningitis. One other patient had a large intraoperative arachnoidal defect that was unsuccessfully repaired with the collagen sponge technique; in this patient, a second operation was required with a fat graft, sellar floor reconstruction, and lumbar drainage. CONCLUSION: A simplified repair of small CSF leaks after transsphenoidal surgery using a two-layered collagen sponge technique with sellar floor reinforcement is thought to be safe and effective and obviates the need for tissue grafts, fibrin glue, or lumbar drain placement.

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To determine if a moderate traumatic brain injury (TBI) sustained early in life alters the capacity for developmental plasticity, 17-20-day-old rat pups received a lateral fluid percussion and then reared in an enriched environment for 17 days. Compared to sham-injured controls, this moderate TBI prevented the increase in cortical thickness (1.48 vs. 1.68 mm, p < 0.01) as well as the corresponding enhancement in cognitive performance in the Morris Water Maze (39 vs. 25 trials to criterion, p < 0.05). These injured animals exhibited no significant neuronal degeneration and no evidence of neurologic or motor deficits. These findings strongly support the conclusion that a diffuse brain injury is capable of inhibiting both anatomical and cognitive manifestations of experience-dependent developmental plasticity.

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Brown tumors (osteoclastomas) are histologically benign lesions that are caused by primary or secondary hyperparathyroidism. Secondary hyperparathyroidism is a frequent complication of chronic renal failure. Skeletal brown tumors are relatively uncommon, and brown tumors that involve the spine are considered very rare. The authors present the case of a 37-year-old woman with systemic lupus erythematosus and hemodialysis-dependent anuric renal failure, in whom spinal cord compression developed due to a brown tumor and pathological fracture at T-9. The patient underwent transthoracic decompressive surgery and spinal reconstruction in which cadaveric femoral allograft and instrumentation were used. Brown tumors of the vertebral column require surgical treatment if medical therapy and parathyroidectomy fail to halt their progression or if acute neurological deterioration occurs. In patients with renal failure bone healing is delayed and there is an increased risk that healing will fail because the metabolic derangements can result in severe osteoporosis. Surgical reconstruction of the spine may require the use of augmentation with instrumentation and aggressive treatment of hyperparathyroidism to achieve successful outcomes.

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To study the ionic, metabolic, and morphologic derangements that occur following brain injury we utilized a retina in vitro model of hypoxia. Retinas were dissected into oxygenated (95% O2, 5% CO2) Ames medium, a physiologic solution resembling cerebrospinal fluid, and randomly assigned to either experimental hypoxic conditions (95% N2, 5% CO2) or control conditions. All retinas were incubated and maintained at 37 degrees C. Changes in extracellular K+ and lactate concentration, intracellular incorporation of 45Ca and 14C-leucine, uptake of glucose using [14C]-2-deoxy-D-glucose (2DG), and cell size were determined at 10, 20, 30, and 60 minute time intervals. The results show that compared to control retinas hypoxia produced: (1) an early increase in extracellular concentration of K+ and lactate, (2) a delayed increase in the intracellular incorporation of 45Ca, (3) an early onset of cellular swelling, and (4) a decrease in the intracellular incorporation of 14C-leucine, and (5) increased glucose utilization. All of the results were statistically significant (p < 0.05) and exhibited a dose response relationship with the exception of intracellular incorporation of 45Ca which did not become significantly different until 30 minutes post-hypoxia. A 16% increase in cell size was noted after 10 minutes of hypoxia. Increased hypoxic cell size persisted for 30 minutes but after 60 minutes the control retinas appeared enlarged as well. Our results suggest that ionic, metabolic, and morphologic derangements can be demonstrated utilizing an in vitro model of hypoxia which are similar to those seen following in vivo traumatic brain injury. With use of this model the mechanisms behind these ionic-metabolic relationships can be addressed at the molecular level.

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In order to determine the extent and duration of calcium (Ca2+) flux following a lateral fluid percussion brain injury in the rat, 45Ca autoradiography was used to study animals immediately, 6, 24 and 96 h after the insult. In addition, cell suspension studies were conducted to determine the extent of cellular flux of 45Ca. Optical density and/or scintillation counting was utilized to provide a relative measure of 45Ca accumulation within 20 different structures. The results indicated that in animals who exhibited no gross morphological damage, 45Ca accumulation following injury was exhibited primarily within the ipsilateral cerebral cortex, dorsal hippocampus and striatum. This accumulation continued for several days returning to control levels by the 4th day after injury. In animals who sustained morphological damage, the contusion site exhibited a marked accumulation of 45Ca which did not resolve spontaneously over the course of 4 days. We conclude from this work that Ca2+ flux is a major component of this experimental model of traumatic injury. Furthermore, that depending on the extent of cell damage, the accumulation of Ca2+ is regionally different. Finally, that even in an injury which by itself does not produce gross morphological tissue damage, accumulation of Ca2+ can continue for at least 48 h.

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The role of an anion exchange pathway in the regulation of intracellular pH (pHi) under alkaline load and steady-state conditions and the modulation of this transporter by pHi was investigated in confluent monolayers of cloned JTC-12 cells, derived from monkey kidney proximal tubule. Regulation of pHi was fluorometrically monitored using the pH-sensitive probe, 2',7'-bis(2-carboxyethyl)-5(6)-carboxyfluorescein (BCECF). Monolayers in which pHi was rapidly elevated by removal of HCO3(-)-CO2 from the bathing medium demonstrated an absolute requirement for Cl- to recover toward base-line pHi. The recovery process proceeded in the absence of Na+, was inhibited 80% by 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid, and was unaffected by 10(-4) M amiloride. When extracellular pH (pHo) was serially lowered from 7.4 to 6.7, recovery from an alkaline load induced by removal of HCO3(-)-CO2 from the medium occurred only when pHi was elevated above approximately 7.25. Below pHi approximately 7.25 no recovery toward initial pHi was observed. When pHi was elevated above approximately 7.25 with pHo maintained at 6.7, the recovery process ceased at pHi approximately 7.25 despite favorably oriented Cl- and OH- chemical gradients. Consistent with these observations, removal of Cl- from the medium of cells buffered with 25 mM HCO3(-)-5% CO2 at pHo 7.4 (in the absence of Na+) resulted in reversible elevation of pHi, whereas in a solution buffered to pHo 6.7 with 5 mM HCO3(-)-5% CO2, removal of Cl- failed to elevate pHi. Under steady-state conditions in the presence of 25 mM HCO3(-)-5% CO2 at pHo 7.4, pHi was 7.40 +/- 0.02 and reversibly decreased to 7.23 +/- 0.01 on removal of Na+ (in the presence of amiloride) from the bathing medium, indicating that the Cl(-)-base exchanger is operative under basal conditions and functions as a base extruder. In summary the JTC-12 cell possesses a Na(+)-independent Cl(-)-base exchange mechanism that is operative under alkaline load and steady-state conditions. pHi but not pHo modulates the activity of this transport pathway, and below pHi approximately 7.25 the exchanger is quiescent.

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Immediately following a lateral fluid percussion brain injury, the cerebral cortex and hippocampus ipsilateral to the percussion show a marked accumulation of calcium and a pronounced increase in glucose metabolism. To determine if this increase in glucose metabolism was related to the indiscriminate release of the excitatory amino acid (EAA) glutamate, kynurenic acid (an EAA antagonist) was perfused into the cerebral cortex through a microdialysis probe for 30 min prior to injury. The results show that adding kynurenic acid to the extracellular space prior to trauma prevents the injury-induced increase in glucose utilization. These results indicate that calcium contributes to the ionic fluxes that are typically seen following brain injury and supports the concept of an increased energy demand upon cells to drive pumping mechanisms in order to restore membrane ionic balance.

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