Experimental neurology
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Experimental neurology · Feb 2006
Comparative StudyAdministration of the immunophilin ligand FK506 differentially attenuates neurofilament compaction and impaired axonal transport in injured axons following diffuse traumatic brain injury.
Traumatic axonal injury (TAI) following traumatic brain injury (TBI) remains a clinical problem for which no effective treatment exists. TAI was thought to involve intraaxonal changes that universally led to impaired axonal transport (IAT), disconnection and axonal bulb formation. However, recent, immunocytochemical studies employing antibodies to amyloid precursor protein (APP), a marker of IAT and antibodies to neurofilament compaction (NFC), RM014, demonstrated that NFC typically occurs independent of IAT, indicating the existence of different populations of damaged axons. ⋯ FK506 treatment failed to reduce the number of axons demonstrating NFC in either the CSpT or ML. FK506's failure to attenuate NFC suggests that additional therapeutic agents may be necessary to blunt the full burden of TAI. Because FK506 targets IAT, calcineurin appears to be a major target for neuroprotection in damaged axons demonstrating IAT.
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Experimental neurology · Jan 2006
Intra-operative STN DBS attenuates the prominent beta rhythm in the STN in Parkinson's disease.
Power spectra from local field potentials (LFPs) recorded post-operatively from the deep brain stimulation (DBS) macroelectrode show prominence of the beta rhythm (11-30 Hz) in untreated Parkinson's disease (PD). Dopaminergic medication and movement attenuate this beta band in PD. In this pilot study of six sides in four patients, we recorded LFPs from the DBS electrode in untreated PD patients in the operating room. ⋯ From one case, our data suggest that the beta rhythm attenuation was most prominent within the STN itself. This study shows for the first time that STN DBS attenuates the power in the prominent beta band recorded in the STN of patients with PD. These pilot findings raise the interesting possibility of using this biomarker for closed loop DBS or neuromodulation.
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Experimental neurology · Jan 2006
Physiologic progesterone reduces mitochondrial dysfunction and hippocampal cell loss after traumatic brain injury in female rats.
Growing literature suggests important sex-based differences in outcome following traumatic brain injury (TBI) in animals and humans. Progesterone has emerged as a key hormone involved in many potential neuroprotective pathways after acute brain injury and may be responsible for some of these differences. Many studies have utilized supraphysiologic levels of post-traumatic progesterone to reverse pathologic processes after TBI, but few studies have focused on the role of endogenous physiologic levels of progesterone in neuroprotection. ⋯ Progesterone in the high physiologic range had a more limited pattern of hippocampal neuronal preservation in the CA3 region only. Neither progesterone dose significantly reduced cortical tissue loss. These findings have implications in understanding the sex-based differences in outcome following acute brain injury.
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Experimental neurology · Jan 2006
Selective regulation of pain affect following activation of the opioid anterior cingulate cortex system.
Morphine and surgical cingulotomy, or transection of the anterior cingulate cortex (ACC), provides relief of chronic pain by selectively decreasing the affective dimension of the condition without altering sensory processing. Clinical reports suggest that morphine might be acting at the level of the ACC to alter the complex experience of pain. ⋯ Supraspinally, microinjection of morphine into the ACC produced a selective naloxone reversible reduction in pain affect, as indicated by a decrease in the aversiveness of noxious cutaneous stimulation in nerve-damaged animals, with no alteration of response to mechanical stimulation. These data demonstrate the central role of the ACC opioid system in selectively processing the aversive quality of noxious mechanical stimulation in animals with a persistent pain condition.
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Experimental neurology · Jan 2006
Transient attenuation of neuropathic manifestations in rats following lesion or reversible block of the lateral thalamic somatosensory nuclei.
Nociceptive behavior in animal models for mononeuropathy has been shown to be altered by spinal tract lesions which suggest a possible supraspinal modulation. The thalamus constitutes a chief center for the processing of nociception. We have, therefore, investigated the effects of transient or permanent blocks of the lateral somatosensory thalamic nuclei (the ventrobasal complex) on the neuropathic manifestations in rats. ⋯ We conclude that the lateral somatosensory thalamic complex is involved in the processing of neuropathic manifestations but cannot be considered as an obligatory or exclusive relay center for the neuropathic syndromes.