Robert E. Hampson scite author profile

A primary objective in developing a neural prosthesis is to replace neural circuitry in the brain that no longer functions appropriately. Such a goal requires artificial reconstruction of neuron-to-neuron connections in a way that can be recognized by the remaining normal circuitry, and that promotes appropriate interaction. In this study, the application of a specially designed neural prosthesis using a multi-input/multi-output (MIMO) nonlinear model is demonstrated by using trains of electrical stimulation pulses to substitute for MIMO model derived ensemble firing patterns. Ensembles of CA3 and CA1 hippocampal neurons, recorded from rats performing a delayed-nonmatch-to-sample (DNMS) memory task, exhibited successful encoding of trial-specific sample lever information in the form of different spatiotemporal firing patterns. MIMO patterns, identified online and in real-time, were employed within a closed-loop behavioral paradigm. Results showed that the model was able to predict successful performance on the same trial. Also, MIMO model-derived patterns, delivered as electrical stimulation to the same electrodes, improved performance under normal testing conditions and, more importantly, were capable of recovering performance when delivered to animals with ensemble hippocampal activity compromised by pharmacologic blockade of synaptic transmission. These integrated experimental-modeling studies show for the first time that, with sufficient information about the neural coding of memories, a neural prosthesis capable of real-time diagnosis and manipulation of the encoding process can restore and even enhance cognitive, mnemonic processes.

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Distribution of spatial and nonspatial information in dorsal hippocampus

Hampson

Simeral

Deadwyler

1999

Nature

273

212

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The hippocampus in the mammalian brain is required for the encoding of current and the retention of past experience. Previous studies have shown that the hippocampus contains neurons that encode information required to perform spatial and nonspatial short-term memory tasks. A more detailed understanding of the functional anatomy of the hippocampus would provide important insight into how such encoding occurs. Here we show that hippocampal neurons in the rat are distributed anatomically in distinct segments along the length of the hippocampus. Each longitudinal segment contains clusters of neurons that become active when the animal performs a task with spatial attributes. Within these same segments are ordered arrangements of neurons that encode the nonspatial aspects of the task appropriate to those spatial features. Thus, anatomical segregation of spatial information, together with the interleaved representation of nonspatial information, represents a structural framework that may help to resolve conflicting views of hippocampal function.

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Chronic ▵⁹‐Tetrahydrocannabinol Treatment Produces a Time‐Dependent Loss of Cannabinoid Receptors and Cannabinoid Receptor‐Activated G Proteins in Rat Brain

Breivogel¹,

Childers²,

Deadwyler³

et al. 1999

Journal of Neurochemistry

251

174

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Systemic and Nasal Delivery of Orexin-A (Hypocretin-1) Reduces the Effects of Sleep Deprivation on Cognitive Performance in Nonhuman Primates

Deadwyler¹,

Porrino²,

Siegel³

et al. 2007

J. Neurosci.

242

192

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Hypocretin-1 (orexin-A) was administered to sleep-deprived (30 -36 h) rhesus monkeys immediately preceding testing on a multi-image delayed match-to-sample (DMS) short-term memory task. The DMS task used multiple delays and stimulus images and effectively measures cognitive defects produced by sleep deprivation (Porrino et al., 2005). Two methods of administration of orexin-A were tested, intravenous injections (2.5-10.0 g/kg, i.v.) and a novel method developed for nasal delivery via an atomizer spray mist to the nostrils (dose estimated 1.0 g/kg). Results showed that orexin-A delivered via the intravenous and nasal routes significantly improved performance in sleep-deprived monkeys; however, the nasal delivery method was significantly more effective than the highest dose (10 g/kg) of intravenous orexin-A tested. The improvement in performance by orexin-A was specific to trials classified as high versus low cognitive load as determined by performance difficulty under normal testing conditions. Except for the maximum intravenous dose (10 g/kg), neither delivery method affected task performance in alert non-sleep-deprived animals. The improved performance in sleep-deprived animals was accompanied by orexin-A related alterations in local cerebral glucose metabolism (CMRglc) in specific brain regions shown previously to be engaged by the task and impaired by sleep deprivation (Porrino et al., 2005). Consistent with the differential effects on performance, nasal delivered orexin-A produced a more pronounced reversal of sleep deprivation induced changes in brain metabolic activity (CMRglc) than intravenous orexin-A. These findings provide strong evidence for the effectiveness of intranasal orexin-A in alleviating cognitive deficits produced by loss of sleep.

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Robert E. Hampson

Cannabinoid physiology and pharmacology: 30 years of progress

A cortical neural prosthesis for restoring and enhancing memory

Distribution of spatial and nonspatial information in dorsal hippocampus

Chronic ▵⁹‐Tetrahydrocannabinol Treatment Produces a Time‐Dependent Loss of Cannabinoid Receptors and Cannabinoid Receptor‐Activated G Proteins in Rat Brain

Systemic and Nasal Delivery of Orexin-A (Hypocretin-1) Reduces the Effects of Sleep Deprivation on Cognitive Performance in Nonhuman Primates

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Robert E. Hampson

Cannabinoid physiology and pharmacology: 30 years of progress

A cortical neural prosthesis for restoring and enhancing memory

Distribution of spatial and nonspatial information in dorsal hippocampus

Chronic ▵9‐Tetrahydrocannabinol Treatment Produces a Time‐Dependent Loss of Cannabinoid Receptors and Cannabinoid Receptor‐Activated G Proteins in Rat Brain

Systemic and Nasal Delivery of Orexin-A (Hypocretin-1) Reduces the Effects of Sleep Deprivation on Cognitive Performance in Nonhuman Primates

Contact Info

Product

Resources

About

Chronic ▵⁹‐Tetrahydrocannabinol Treatment Produces a Time‐Dependent Loss of Cannabinoid Receptors and Cannabinoid Receptor‐Activated G Proteins in Rat Brain