References: Hair growth and hair loss
Audiol Neurootol. 2002 May-Jun;7(3):161-4.
From gene identification to gene therapy.
Kanzaki S, Kawamoto K, Oh SH, Stover T, Suzuki M, Ishimoto S, Yagi M, Miller JM, Lomax MI, Raphael Y.
Kresge Hearing Research Institute, Ann Arbor, Mich., USA.
Inner ear disease due to hair cell loss is common, and no restorative treatments for the balance and hearing impairment are currently available. To develop clinical means for enhancing protection and regeneration in the inner ear, it is necessary to understand the molecular basis for hereditary and acquired deafness and vestibular disorders. One approach is to identify and characterize genes that regulate protection or repair in other systems. For that purpose, we have used the differential display assay and compared gene expression between normal and acoustically traumatized inner ears of chicks. Several chick cDNAs that were identified are considered as candidates for roles in the reparative process that follows trauma in the basilar papilla. The mammalian vestibular epithelium has a limited regenerative capability. To identify genes that may participate in the regenerative response, we have used gene arrays profiling, comparing normal to drug-traumatized vestibular epithelia. We identified several genes that are differentially expressed in traumatized vestibular epithelium, including several insulin-like growth factor-I binding proteins. To use this molecular knowledge for enhancing protection and repair in the organ of Corti, it is necessary to overexpress the genes of choice in the inner ear. Using viral-mediated gene transfer, we overexpressed transgenic glial cell line-derived neurotrophic factor and demonstrated a robust protective effect against acoustic and ototoxic inner ear trauma. Future identification of the genes that are important for protection and regeneration, along with improved gene transfer technology, will allow the use of gene therapy for treating hereditary and environmental inner ear disease. Copyright 2002 S. Karger AG, Basel
online pharmacy ref. source: www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=PubMed&list_uids=12053138&dopt=Abstract
Audiol Neurootol. 2002 May-Jun;7(3):165-70.
Mechanisms of cell death in the injured auditory system: otoprotective strategies.
Lefebvre PP, Malgrange B, Lallemend F, Staecker H, Moonen G, Van De Water TR.
Department of Otolaryngology, University of Liege, Belgium.
Oxidative stress insults such as neurotrophin withdrawal, sound trauma, hypoxia/ischemia, ototoxic antibiotics, and chemotherapeutic agents have been shown to induce apoptosis of both auditory hair cells and neurons. In this paper, we review some components of the apoptotic pathways leading to the death of hair cells and auditory induced by growth factor withdrawal or cisplatin intoxication: (1) reactive oxygen species and free radicals are formed as by-products of several metabolic pathways and these molecules can themselves cause cell damage by reacting with cellular proteins; (2) activation of caspases, and (3) activation of calpain. These mechanisms have several different points at which inhibitors could be targeted to protect cells from programmed cell death, including the prevention of oxidative stress-induced apoptosis and the activation of caspases and calpains. Copyright 2002 S. Karger AG, Basel
online pharmacy ref. source: www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=PubMed&list_uids=12053139&dopt=Abstract
umich.edu
Deafness, with loss of sensory (hair) cells, results in progressive pathophysiological changes ending in the degeneration of most auditory nerve neurons. It is now possible to consider these events in the broader context of anti-apoptotic survival factors in the peripheral and central nervous system. One consequence of deafferentation of a neuron is the loss of neurotrophins that can lead to a change in oxidative state (formation of free radicals), changes in intracellular Ca(2+), and an up-regulation of apoptotic genes. Interventions that can modify availability of neurotrophins, [Ca(2+)](I), and/or free radical formation or their destructive effects, may preserve the auditory nerve. Some interventions (neurotrophins) may also lead to a regrowth of neurites. Studies in this area are of basic value and also of immediate clinical interest for the application of the cochlear prosthesis to the severe and profoundly deaf, since the benefits of this prosthesis are directly dependent on auditory nerve survival and the proximity of stimulating electrode to neuron. We, and others, have found that auditory nerve degeneration can be prevented by chronic electrical stimulation. We have demonstrated in vivo that this effect can be blocked by tetrodotoxin, thus indicating that propagated action potentials are a necessary condition, and by verapamil (Ca(2+) channel blocker), supporting in vitro studies by others, indicating that L-type Ca(2+) channels are necessary for stimulation-induced rescue of the deafferented auditory nerve. The intensities of electrical stimulation required for rescue are at levels sufficient to express the intermediate-early gene c-fos which can initiate transcription of anti-apoptotic genes and pathways, and up-regulate expression of neurotrophins that may act in an autocrine manner to protect the nerve from death. We, and others, have found that chronic local delivery (osmotic pump and microcannulation of the inner ear fluid spaces) of individual neurotrophins and cocktails of factors can also enhance survival of the deafferented nerve, and some can also initiate a regrowth of degenerated peripheral processes of the nerve into the region of the destroyed sensory epitheliae. Recently, we have shown that this rescue can occur with delayed intervention, after degeneration of some neurons has begun, more closely mimicking the human clinical situation. Finally, we have shown that interventions with antioxidants may also be effective in preventing pathophysiological changes of the auditory nerve following deafness. These studies in the auditory periphery support the 'neurotrophic factor hypothesis' as proposed as a general mechanism underlying neurodegenerative and age-related pathology of the central nervous system. Additional animal studies can yield a rational scientific basis to justify human trials, with a goal to maintain auditory cell survival and initiate and direct fiber growth to the next generation of prosthesis. Intimate contact between electrode and a dense population of auditory neurons should greatly enhance the benefits of these devices for the profoundly deaf. Copyright 2002 S. Karger AG, Basel
online pharmacy ref. source: www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=PubMed&list_uids=12053141&dopt=Abstract
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