Nerve Dendrite

NMR. On the other hand what do you think of the Pilla currents, i.e. the electromagnetic induced currents pulsed by Helmholtz coils, which can also stimulate nerve dendrite growth In the future they might be in competition with your methods. 

Tree like networks of nerve fiber called dendrites protrude outward from the neuron s cell body, or soma. Extending outward from the soma is also a long fiber called the axon that itself eventually branches out into a set of strands and sub strands. At the ends of these strands are the transmitting ends of communication junctions between nerve fibers called synapses. The receiving ends of these junctions exist both on dendrites and on the somas themselves. Each neuron is typically connected to several thousand other neurons. 

Neurodegeneration. Figure 3 Illustration of synaptic (neuritic) apoptosis. A pyramidal neuron is depicted with cortical afferents synapsing on its dendrites. Localized apoptotic mechanisms lead to the release of cytochrome c from the mitochondria and an increase in the concentration of activated caspase-3 in a presynaptic terminal that is synapsing on a dendritic spine. Increased caspase-3 activity results in a localized breakdown of this nerve terminal and its synapse. Subsequently, the postsynaptic dendritic spine retracts and disappears (Figure modified from Glantz et al. [5] [3]). 

Figure 33. Proposed interface between an electronic component (video camera) and a nerve (optical nerve) that could transduce electronic signals from the equipment to ionic signals that can be understood by dendrites.

Saez ET, Pehar M, Vargas MR, Barbeito L, Maccioni RB (2006) Production of nerve growth factor by beta-amyloid-stimulated astrocytes induces p75NTR-dependent tau hyperphosphorylation in cultured hippocampal neurons. J Neurosci Res 84 1098-1106 Sala C, Roussignol G, Meldolesi J, Fagni L (2005) Key role of the postsynaptic density scaffold proteins Shank and Homer in the functional architecture of Ca homeostasis at dendritic spines in hippocampal neurons. J Neurosci 25 4587 592 Santello M, Volterra A (2008) Synaptic modulation by astrocytes via Ca(2-l-)-dependent glutamate release. Neuroscience 158 253-9... 

Figure 17.4 The effect of neuroleptics on the activity of DA neurons. Although neuroleptics (DA antagonists) are used primarily to inhibit the postsynaptic effects of released DA they also increase the activity of the DA neuron itself since they (1) inhibit the effect of synaptic DA on nerve terminal autoreceptors and so increase DA release (2) block inhibitory DA autoreceptors on the soma of the DA neuron so that they cannot be stimulated by endogenous DA, possibly released from the neuron s own dendrites and (3) facilitate feedback excitation to the DA neuron from those neurons normally inhibited by distally released DA. All the DA receptors involved are D2 (or possibly D3). — Blocked by D2 antagonists (neuroleptics)...

Lamina IV is composed of heterogeneous sized cells and is less densely packed than lamina III due to the number of nerve axons passing in this layer. At least three types of neurons have been identified in lamina IV, based on different dendritic projection patterns and these include SCT and PSDC cells. Another cell type has been described which has a dendritic pattern similar to SCT and PSDC, but with local axon terminations. Somas of STT cells are also found in lamina IV. 

The structural design of nerve cells is a striking example of dendritic architecture, which acts as a signal transduction system. Neurons are known to send out a series of long specialized processes that will either receive electrical signals (dendrites) or transmit these electrical signals (axons) to their target cells (Fig. 5.40). 

Raff It also seems to be true in nerve cells, in the formation of dendrites and axons. This seems to be a stochastic process. 

Action potential, or nerve impulse The wave of electrical activity that passes from the dendrites of the neuronal cell body, down the axon to the synaptic bouton. 

The postsynaptic receptors on any given neuron receive information from transmitters released from another neuron. Typically, postsynaptic receptors are located on dendrites or cell bodies of neurons, but may also occur on axons or nerve terminals in the latter case, an axoaxonic synaptic relationship may cause increases or decreases in transmitter release. In contrast, autoreceptors are found on certain neurons and respond to transmitter molecules released from the same neuron. Autoreceptors may be widely distributed on the surface of the neuron. At the nerve terminal, they respond to transmitter molecules released into the synaptic cleft on the cell body, they may respond to transmitter molecules released by dendrites. Functionally, most autoreceptors appear to decrease further transmitter release in a kind of negative feedback loop. Autoreceptors have been identified for all the catecholamines, as well as for several other neurotransmitters. a2-adrenergic receptors are often found on noradrenergic nerve terminals of postganglionic sympathetic nerves, as well as on noradrenergic neurons in the CNS [36], and activation of these receptors decreases further norepinephrine release. Dopamine autoreceptors,... 

By immunohistochemistry, a- and p-synucleins are concentrated in nerve terminals, with little staining of somata and dendrites. Ultrastructurally, they are found in close proximity to synaptic vesicles. In contrast,y-synuclein is present throughout nerve cells in many brain regions. In rat, a-synuclein is most abundant throughout telencephalon and diencephalon, with lower levels in more caudal regions. P-Synuclein is distributed fairly evenly throughout the central nervous system, whereas y-synuclein is most abundant in midbrain, pons and spinal cord, with much lower levels in forebrain areas. 

Figure 1.1 Neurons (nerve cells) transmit information throughout the brain and the body. A typical neuron is shown here. Electrical impulses are received by the dendrites and transmitted to the next neuron via the axon. The myelin sheath insulates the axon and increases the speed at which electrical impulses can travel.

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