Slide 1

... 1. Neurons are electrically active; They have a resting voltage, and can undergo electrical changes ...

Anatomy and Physiology 121: The Nervous System General

... Synaptic Transmission ...

Nervous Systems

... interneurons and stimulate muscle or glands ...

power point for chap 11

... dissipated due to the leaky plasma membrane • Can only travel over short distances ...

The Nervous System (ppt).

... body Communicates by electrical impulses that cause rapid and specific responses ...

1 - LWW.com

... segment of the sutured MCN was harvested from the transgenetic GFP-fluorescent rats, and prepared as previously ...

nervous system

... intentional introduction of live, disinfected maggots or fly larvae into non-healing skin or soft tissue wounds of a human or other animal. This practice was widely used before the discovery of antibiotics, as it serves to clean the dead tissue within a wound in order to promote healing. ...

Nerve tissue

... postsynaptic region, promoting a transient electrical activity (depolarization) at the postsynaptic membrane. These synapses are called excitatory, because their activity promotes impulses in the postsynaptic cells membrane. ...

Nervous System

... synapse & binds to receptor protein on postsynaptic cell 4. Postsynaptic cell is excited or inhibited 5. Neurotransmitter in synapse is deactivated ...

“Put that in the Form of a Question, Please!”

... on outside). When in action potential, polarity switches and cell becomes more positive on inside as ion channels open up and Na+ ions flood in? ...

ssep anatomy handout

... Active Transport Pump (ATP) (also known as sodium pump and Na+/K+ pump) – forces ions in and out of cell to make cell go from action back to resting. ATP (adenosine triphosphate) is the neurotransmitter substance that energizes the pump. Anions- negatively charged ions (ions that have gained an elec ...

Neural Integration - Oakton Community College

... Rapid, automatic responses to stimuli Components of reflex arc: Stimulus Receptor--translates stimulus into A.P. Sensory neuron--carries A.P. to CNS Integration center--CNS Motor neuron--carries A.P. to effector (muscle) Effector--executes appropriate response ...

Nervous System

... Myelin—whitish, fatty material that protects and insulates nerve fibers. Myelin increases transmission rates. Impulse speed ~400ft/sec! Synapse—tiny gap separating each axon from the next neuron. Nodes of Ranvier—indentations between each myelinated section of axon ...

Printable version

... 1. the difference in two voltages is called the potential 2. in the body, electrical charges are provided by ions B. resting membrane potential 1. a resting neuron has an internal potential of about -70mV 2. the potential is due to the difference in the sodium and potassium ion concentrations inside ...

Nervous Tissues

... central spherical nucleus with one or more nucleoli. Cytoplasm contains: Golgi apparatus, mitochondria, lysosomes as well as other common cytoplasmic organelles and inclusions No centriole. ...

The Nervous System - School District of New Berlin

... – Satellite cells- surround and control the ...

Peripheral NS: Sensory processing & receptors

... Physical region over which each receptor can detect stimuli ...

Action potential

... The voltage clamp uses a negative feedback mechanism. The membrane potential amplifier measures membrane voltage and sends output to the feedback amplifier. The feedback amplifier subtracts the membrane voltage from the command voltage, which it receives from the signal generator. This signal is am ...

Mader/Biology, 11/e – Chapter Outline

... 4) The sodium-potassium pump maintains this unequal distribution of Na + and K+ ions. d. The sodium-potassium (Na+-K+) pump is an active transport system that moves Na+ ions out and K+ ions into the axon. e. The pump is always working because the membrane is permeable to these ions and they tend to ...

Chapter 17:

... axon, with each portion of the axon undergoing depolarization then repolarization. A refractory period ensures that the action potential will not move backwards. In myelinated fibers, the action potential only occurs at the nodes of Ranvier. This “jumping” from node-to-node is called saltatory condu ...

The Nervous System WS-11A Review Quest

... 2. What are the two primary cells of the nervous system, and what do they do? The two primary cells of the nervous system are neurons, that actually carry and store information, and glial cells that support the neurons. 3. What protects the brain? The brain is protected by the bones of the skull and ...

Chapter 9

... A particular neuron of a pool may receive excitatory or inhibitory stimulation; if the net effect is excitatory but ______________the neuron becomes more excitable to ...

Nervous Tissue [PPT]

... Synapses can form between many different parts of neurons and between a neuron and a non-neuronal cell, e.g., a muscle or a secretory cell. ...

Unit Outline_Ch17 - Westgate Mennonite Collegiate

... cord, and the peripheral nervous system, consisting of nerves that carry messages to and from the central nervous system. The nervous system contains two types of cells: neurons and neuroglia. Types of Neurons and Neuron Structure There are three classes of neurons: sensory neurons, interneurons, an ...

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Rheobase

Rheobase is a measure of membrane excitability. In neuroscience, rheobase is the minimal current amplitude of infinite duration (in a practical sense, about 300 milliseconds) that results in the depolarization threshold of the cell membranes being reached, such as an action potential or the contraction of a muscle. In Greek, the root ""rhe"" translates to current or flow, and ""basi"" means bottom or foundation: thus the rheobase is the minimum current that will produce an action potential or muscle contraction.Rheobase can be best understood in the context of the strength-duration relationship (Fig. 1). The ease with which a membrane can be stimulated depends on two variables: the strength of the stimulus, and the duration for which the stimulus is applied. These variables are inversely related: as the strength of the applied current increases, the time required to stimulate the membrane decreases (and vice versa) to maintain a constant effect. Mathematically, rheobase is equivalent to half the current that needs to be applied for the duration of chronaxie, which is a strength-duration time constant that corresponds to the duration of time that elicits a response when the nerve is stimulated at twice rheobasic strength.The strength-duration curve was first discovered by G. Weiss in 1901, but it was not until 1909 that Louis Lapicque coined the term ""rheobase"". Many studies are being conducted in relation to rheobase values and the dynamic changes throughout maturation and between different nerve fibers. In the past strength-duration curves and rheobase determinations were used to assess nerve injury; today, they play a role in clinical identification of many neurological pathologies, including as Diabetic neuropathy, CIDP, Machado-Joseph Disease, and ALS.

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Rheobase