Presentation is loading. Please wait.

Presentation is loading. Please wait.

1QQ#11 for 10:30 1.Retrograde axonal transport limits the rate of axonal regeneration to 1-2 mm/day. 2.The cell body of an afferent neuron is located in.

Published byLucas Davidson Modified over 9 years ago

Similar presentations

Presentation on theme: "1QQ#11 for 10:30 1.Retrograde axonal transport limits the rate of axonal regeneration to 1-2 mm/day. 2.The cell body of an afferent neuron is located in."— Presentation transcript:

1 1QQ#11 for 10:30 1.Retrograde axonal transport limits the rate of axonal regeneration to 1-2 mm/day. 2.The cell body of an afferent neuron is located in the ventral root. 3.Microglia are a component of the blood-brain barrier. 4.The neural crest consists of cells, some of which will become somatic motoneurons. Revise two of the following misleading statements. Your revision cannot consist of a “not” statement.

2 1QQ#11 for 11:30 1.Anterograde axonal transport limits the rate of axonal regeneration to 200 mm/day. 2.The cell body of an interneuron is located in the dorsal root ganglion. 3.Microglia adjust the concentration of ions and neurotransmitters in the interstitial fluid surrounding neurons of the CNS. 4.The neural crest consists of cells, some of which will become interneurons. Revise two of the following misleading statements. Your revision cannot consist of a “not” statement.

3 Topics covered with board drawings Axonal regeneration Peripheral vs central Role of growth cones Timecourse of recovery Wallerian degeneration Schwann cells and Schwann tubes CNS and spreading necrosis

4 Cortical vesicle exocytosis during fertilization leads to envelope elevationA, prior to fertilization (left), the proteinaceous vitelline coat of the sea urchin egg of Lytechinus pictus is not visible in this differential interference contrast image. Zimmerberg J et al. J Physiol 1999;520:15-21 ©1999 by The Physiological Society

5 Virtues of Squid Giant Axon Big questions: 1)How do cells generate a resting membrane potential? 2)What causes changes in the membrane potential? 3)How do cells use these potentials? i.e. What is their purpose?

6 Fig. 06.09

7 Fig. 06.10a There is a concentration gradient favoring the diffusion of Na+ and K+ through the selectively permeable membrane which has ion channels only for potassium. At the start, is there an electrical driving force?

8 Fig. 06.10b With K+ channels open, K+ diffuses down its concentraiton gradient, leaving behind CL- ions which are not permeable through the membrane. As more and more K+ move to the left, the compartment they leave becomes more and more negatively charged. Is there an electrical driving force?

9 Fig. 06.10c

10 Fig. 06.10d Soon, the accumulation of negative charges seriously impeded the diffusion of K+ as the electrostatic force builds up in opposition to the concentration driving force.

11 Fig. 06.10e Equilibrium potential = Nernst potential = diffusion potential Eventually, the electrostatic force that impedes diffusion of K+ is exactly equal to the driving force favoring diffusion based on a concentration gradient. When these two driving forces are equal and opposite, the membrane potential reaches an equilibrium at which the voltage is called So which compartment corresponds to intracellular fluid? E ion+ = 61/Z log ([conc outside]/ [conc inside]) E K+ = 61/1 log (5/150) E K+ = -90 mV

12 The Nernst Equation If the membrane is permeable to ONLY ONE ion species and you know the concentrations on both sides of the membrane, use the Nernst Equation to calculate the membrane potential. Nernst potential for X = 61/Z log [Outside ] / [Inside] S 2

13 Fig. 06.10e Equilibrium potential = Nernst potential = diffusion potential E ion+ = 61/Z log ([conc outside]/ [conc inside]) E K+ = 61/1 log (5/150) E K+ = -90 mV 150 mM5 mM K+ 50 mM Predict the change in membrane potential if K+ were added to the extracellular fluid. S 1 What hormone regulates the levels of Na+ and K+ in extracellular fluid?

14 Fig. 06.11a S 3 Now consider a situation in which only Na+ is permeable.

15 Fig. 06.11b S 4

16 Fig. 06.11c S 5

17 Fig. 06.11d S 6

18 Fig. 06.11e Equilibrium potential for Na+ E Na+ = 61/1 log (145/15) E Na + = +60 mV 145 mM 15 mM Extracellular Intracellular So, given these concentrations of Na+ and a membrane permeable only to Na+, use Nernst equation to calculate what the membrane potential would be. At the equilibrium potential, no net movement of Na+ because driving forces (concentration and electrical) are exactly equal and opposite. S 7

19 1QQ#12 for 10:30 1.Ligand-gated ion channels are found exclusively in the axonal membrane. 2.Leak channels are found only at the distal tips of sensory neurons. 3.Trigger zones and axons hillocks are the sites which convert action potentials to graded potentials. 4.Graded potentials are conducted non- decrementally and are well suited for long- distance signalling. Revise two of the following misleading statements. Your revision cannot consist of a “not” statement.

20 1QQ#12 for 11:30 1.Ligand-gated ion channels are found exclusively in the membrane of dendrites. 2.Leak channels are found only at the distal tips of efferent neurons. 3.Trigger zones and axons hillocks are the sites where action potentials are converted to graded potentials. 4.Action potentials are conducted non- decrementally and are well suited for long- distance signaling. Revise two of the following misleading statements. Your revision cannot consist of a “not” statement.

21 Test 1 Monday Thermoregulation Glucose homeostasis Negative feedback, positive feedback, feedforward Endocrine System and endocrine disorders Reflexes. Neurons and glial cells Equilibrium potentials and Resting Membrane potential. Comprehensive list of topics at http://webs.wofford.davisgr/bio342/test1study2012.htm

22 Electrical and concentration gradient driving forces for Sodium and Potassium How does the membrane potential change if 1) permeability to sodium increases 2) Permeability to potassium increases Why is resting membrane potential closer to E K than E Na ? What would happen to membrane potential if suddenly P Na became very great? Size and Direction of Arrows show driving forces! The G-H-K Equation! S 8 How can the membrane become suddenly more permeable to Na+?

23 The Goldman Hodgkin Katz Equation If you know the concentrations of ALL permeable ions and their relative permeabilities, you can calculate the membrane potential using the GHK Equation. S 9

24 At RMP, some Na+ leaks in, some K+ leaks out. S 10

25 Na+ K+ ATPase maintains the concentration gradients across cell membranes Animation of the Pump What would happen to membane potentials and concentrations of Na+ and K+ if cells didn’t have this pump? S 11

26 Animations of the Origin of Resting Membrane Potential Animation of Resting Membrane Potential (single ion) YouTube animation of Na-K-ATPase, Sodium Co-transporter, and K Leak channels Origin of Resting Membrane Potential and intracellular recording S 12

27 S 13

28 Which ion moving in which direction (into or out of cell) is responsible for depolarization and overshoot? Which ion moving in which direction (into or out of cell) is responsible for repolarization and hyperpolarization? Can the membrane potential go more negative than -90 mV? Increase PK+ Increase PNa+ S 14 Increase PK+ How do ions get across the membrane? Ion channels!

Download ppt "1QQ#11 for 10:30 1.Retrograde axonal transport limits the rate of axonal regeneration to 1-2 mm/day. 2.The cell body of an afferent neuron is located in."

Similar presentations

Outline Neuronal excitability Nature of neuronal electrical signals Convey information over distances Convey information to other cells via synapses Signals.

Outline Neuronal excitability Nature of neuronal electrical signals Convey information over distances Convey information to other cells via synapses Signals.
Topic 6.5 - Nerves.

Topic Nerves.
Functional Organization of Nervous Tissue $100 $200 $300 $400 $500 $100$100$100 $200 $300 $400 $500 Introduction FINAL ROUND Cells Membrane Potential Action.

Functional Organization of Nervous Tissue $100 $200 $300 $400 $500 $100$100$100 $200 $300 $400 $500 Introduction FINAL ROUND Cells Membrane Potential Action.
Monday April 9, 2014. Nervous system and biological electricity II 1. Pre-lecture quiz 2. A review of resting potential and Nernst equation 3. Goldman.

Monday April 9, Nervous system and biological electricity II 1. Pre-lecture quiz 2. A review of resting potential and Nernst equation 3. Goldman.
Nerves, hormones and homeostasis

Nerves, hormones and homeostasis
Lecture packet 9 Reading: Chapter 7

Lecture packet 9 Reading: Chapter 7
RESTING MEMBRANE POTENTIAL

RESTING MEMBRANE POTENTIAL
Resting Membrane Potential. Cell Membranes F5-1 Cell membrane distinguishes one cell from the next. Cell membranes do the following: a) Regulates exchange.

Resting Membrane Potential. Cell Membranes F5-1 Cell membrane distinguishes one cell from the next. Cell membranes do the following: a) Regulates exchange.
PHYSIOLOGY 1 Lecture 11 Membrane Potentials. n Objectives: Student should know –1. The basic principals of electricity –2. Membrane channels –3. Electrical-chemical.

PHYSIOLOGY 1 Lecture 11 Membrane Potentials. n Objectives: Student should know –1. The basic principals of electricity –2. Membrane channels –3. Electrical-chemical.
Bioelectricity Provides basis for “irritability” or “excitability Fundamental property of all living cells Related to minute differences in the electrical.

Bioelectricity Provides basis for “irritability” or “excitability Fundamental property of all living cells Related to minute differences in the electrical.
Bioelectromagnetism Exercise #1 – Answers TAMPERE UNIVERSITY OF TECHNOLOGY Institute of Bioelectromagnetism.

Bioelectromagnetism Exercise #1 – Answers TAMPERE UNIVERSITY OF TECHNOLOGY Institute of Bioelectromagnetism.
Neurophysiology Opposite electrical charges attract each other

Neurophysiology Opposite electrical charges attract each other
Resting membrane potential 1 mV= 0.001 V membrane separates intra- and extracellular compartments inside negative (-80 to -60 mV) due to the asymmetrical.

Resting membrane potential 1 mV= V membrane separates intra- and extracellular compartments inside negative (-80 to -60 mV) due to the asymmetrical.
Neurophysiology Opposite electrical charges attract each other In case negative and positive charges are separated from each other, their coming together.

Neurophysiology Opposite electrical charges attract each other In case negative and positive charges are separated from each other, their coming together.
General Organization - CNS and PNS - PNS subgroups The basic units- the cells - Neurons - Glial cells Neurophysiology - Resting, graded and action potentials.

General Organization - CNS and PNS - PNS subgroups The basic units- the cells - Neurons - Glial cells Neurophysiology - Resting, graded and action potentials.
Ion Pumps and Ion Channels CHAPTER 48 SECTION 2. Overview  All cells have membrane potential across their plasma membrane  Membrane potential is the.

Ion Pumps and Ion Channels CHAPTER 48 SECTION 2. Overview  All cells have membrane potential across their plasma membrane  Membrane potential is the.
Nervous systems. Keywords (reading p. 960-976) Nervous system functions Structure of a neuron Sensory, motor, inter- neurons Membrane potential Sodium.

Nervous systems. Keywords (reading p ) Nervous system functions Structure of a neuron Sensory, motor, inter- neurons Membrane potential Sodium.
Neural Signaling: The Membrane Potential Lesson 9.

Neural Signaling: The Membrane Potential Lesson 9.
RESTING MEMBRANE POTENTIAL

RESTING MEMBRANE POTENTIAL
Neurons: Cellular and Network Properties

Neurons: Cellular and Network Properties

Similar presentations

Ads by Google