chapter 3: biological bases of behavior

... + charged Na and K ions and neg. charged chloride ions flow across membrane Higher concentration of neg ions inside cell; creates voltage Resting potential: a neuron’s stable, negative charge when the cell is inactive (c. -70 millivolts) ...

Action Potentials & Nerve Conduction

... •A graded potential depolarization is called excitatory postsynaptic potential (EPSP). A graded potential hyperpolarization is called an inhibitory postsynaptic potentials (IPSP). •They occur in the cell body and dendrites of the neuron. •The wave of depolarization or hyperpolarization which moves ...

How Neurons and Synapses Work

... local potential aka graded potential  If its big enough it causes action potential ...

File

... 1. How is it possible for charged ions to move from neuron to neuron if the plasma membrane is impermeable to charged ions? 2. Describe the forces that act upon the potassium ions in and out of the plasma membrane. 3. What is the resting membrane potential charge? 4. At rest, why is the neuron negat ...

Neural Phys

... neurons due to presence of only ligand-gated channels  AP begins at axon hillock due to presence of voltagegated channels ...

The Importance of the Nervous System

... • intensity of stimulus is indicated by the frequency of action potentials, not the size • 10-100 action potentials per second • rate of conduction increases with diameter of nerve (up to 25 m/s) ...

How Do Muscles Work?

... the neuronal membrane and dump their contents into the synaptic cleft. ...

Nerves Powerpoint

... • Neurons have three general structures: – Soma (cell body) – Axon (signal transmission) – Dendrite (signal reception) ...

Describe how action potentials are generated

... Essay Question for exam 3 Describe how action potentials are generated and propagated along neurons. Include in your description how intracellular voltage changes during the action potential by labeling the action potential tracing (shown below) and describing what is occurring at that particular ti ...

Describe how action potentials are generated and

... Essay Question for exam 3 Describe how action potentials are generated and propagated along neurons. Include in your description how intracellular voltage changes during the action potential by labeling the action potential tracing (shown below) and describing what is occurring at that particular ti ...

Message Transmission

... Resting potential • This is a nerve cell that is ready to work. • The cell membrane is more permeable to K+ than to Na+, so more positives are leaving than entering. Add the Na+ K+ pump ( a mechanism in the cell membrane that shunts the Na+ back out) and the inside is decidedly negative and the out ...

Neuro Physiology 1

... Action potentials. All animal cells have a resting potential, ion pumps and a membrane which can act to conduct an electrical signal. What distinguishes neruons (and to a less extent muscles and endocrine cells) is their excitability. Excitability is the ability of a cell to generate and propagate a ...

Slide ()

... Kandel ER, Schwartz JH, Jessell TM, Siegelbaum SA, Hudspeth AJ, Mack S. Principles of Neural Science, Fifth Editon; 2012 Available C. The resting potential settles at a new level, where the influx Na+ is balanced by the efflux of K+. In this example the aggregate conductance of the K+ at: http://mhm ...

OCR Document - MrsGorukhomework

... though the channels. And there is the sodium-potassium pump, which actively transports ions using ATP. Three Na+ are moved out for every two K+ moved in. Ion channels for -ve ions are closed. Most -ve ions are large and can't get out. So, Na+ are actively pumped out and not allowed back in. K+ are p ...

PD233-Lecture6

... Potential difference leads to flow of current flow when two points with different electric potential are connected with conducting media. ...

05 CMNB Block 3 Session 4

... time, dV/dt, is infinite. From the equation Icap = C *dV/dt, Icap is then infinite. Of course this is impossible but clearly Icap is extremely large and charges the membrane within a very small time (nannoseconds?). At 1ms, dV/dt = 0. The voltage is not changing with time during the step. Thus, from ...

File

... • Stimulus causes Na+ channels to open in cell membrane • Na+ ions enter the sell • This causes depolarization • Receptor/generator potential is created (local circuit) • If receptor potential (local circuit) is greater than the threshold (-60mv to -50mV), then the action potential is generated • Th ...

PSYCH 2230

... 1. The Na+/K+ pump establishes a “concentration gradient” and a “charge gradient” a. Particles tend to diffuse down a concentration gradient. b. In the charge gradient opposite charges attract and like charges repel c. Once the Na+ is out, it can’t come back in. d. Once the K+ is in, it CAN flow bac ...

Assignment: Sensing mechanical changes in firing neurons

... membrane is only a few nanometers thick, causing an electrical field strength over the cell membrane in the order of 20∙106 Volts/meter. When an action potential travels down the axon, deviations from this resting potential in the order of 100 milliVolts occur, causing a strong change in electrical ...

Neurons

... Voltage causes electrically charged particles, ions, to move across cell membranes. Major ions in neurons: • Sodium (Na+) • Potassium (K+) • Calcium (Ca2+) • Chloride (Cl–) Membrane potentials are measured with electrodes. • The resting potential of an axon is –60 to –70 millivolts (mV). • The insid ...

here - York University

... When an action potential invades an axonal terminal, voltage-gated calcium channels open causing an increase in calcium in the cytoplasm. Higher concentration of calcium will cause the neurotransmitter filled vesicles to fuse to the membrane, allowing the neurotransmitters to diffuse to the post-syn ...

Nervous System Neurons And Synapses

... more likely to have developed from nerve tissue or from neuroglia? Why? Considering that nerve cells do not usually divide (amitotic), the tumor is most likely a glioma, developing from one of the types of neuroglia. 2. Describe how the following substances exert their effects on the body: botulism; ...

P215 - Basic Human Physiology

... • Action potentials are triggered by membrane depolarization at the axon hillock • Depolarization caused by increased permeability to ions • Permeability typically increased by chemically-or physically-gated ion channels • Can also be affected by membrane perturbations, changes in ion gradients, etc ...

Topic 20: Neurons and Synapses (Ch. 48)

... B. neurons keep a resting membrane potential (polarized membrane) 1. many negative ions (anions) are trapped inside the cell 2. sodium-potassium pumps in the plasma membrane actively pump out 3 Na+ ions and bring in 2 K+ ions – makes inside even more negative 3. active pumping sets up diffusion grad ...

Ch. 48 - 49

... Describe the main parts of a neuron. Describe what happens in a Reflex Arc. How are Nodes of Ranvier and Saltatory conduction related? What occurs at the synapse? ...

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Action potential

In physiology, an action potential is a short-lasting event in which the electrical membrane potential of a cell rapidly rises and falls, following a consistent trajectory. Action potentials occur in several types of animal cells, called excitable cells, which include neurons, muscle cells, and endocrine cells, as well as in some plant cells. In neurons, they play a central role in cell-to-cell communication. In other types of cells, their main function is to activate intracellular processes. In muscle cells, for example, an action potential is the first step in the chain of events leading to contraction. In beta cells of the pancreas, they provoke release of insulin. Action potentials in neurons are also known as ""nerve impulses"" or ""spikes"", and the temporal sequence of action potentials generated by a neuron is called its ""spike train"". A neuron that emits an action potential is often said to ""fire"".Action potentials are generated by special types of voltage-gated ion channels embedded in a cell's plasma membrane. These channels are shut when the membrane potential is near the resting potential of the cell, but they rapidly begin to open if the membrane potential increases to a precisely defined threshold value. When the channels open (in response to depolarization in transmembrane voltage), they allow an inward flow of sodium ions, which changes the electrochemical gradient, which in turn produces a further rise in the membrane potential. This then causes more channels to open, producing a greater electric current across the cell membrane, and so on. The process proceeds explosively until all of the available ion channels are open, resulting in a large upswing in the membrane potential. The rapid influx of sodium ions causes the polarity of the plasma membrane to reverse, and the ion channels then rapidly inactivate. As the sodium channels close, sodium ions can no longer enter the neuron, and then they are actively transported back out of the plasma membrane. Potassium channels are then activated, and there is an outward current of potassium ions, returning the electrochemical gradient to the resting state. After an action potential has occurred, there is a transient negative shift, called the afterhyperpolarization or refractory period, due to additional potassium currents. This mechanism prevents an action potential from traveling back the way it just came.In animal cells, there are two primary types of action potentials. One type is generated by voltage-gated sodium channels, the other by voltage-gated calcium channels. Sodium-based action potentials usually last for under one millisecond, whereas calcium-based action potentials may last for 100 milliseconds or longer. In some types of neurons, slow calcium spikes provide the driving force for a long burst of rapidly emitted sodium spikes. In cardiac muscle cells, on the other hand, an initial fast sodium spike provides a ""primer"" to provoke the rapid onset of a calcium spike, which then produces muscle contraction.

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Action potential