Download Recording of Membrane Potential

Survey
yes no Was this document useful for you?
   Thank you for your participation!

* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project

page
1
page
2
page
3
page
4
page
5
page
6
page
7
page
8
page
9
page
10
page
11
page
12
page
13
page
14
page
15
page
16
page
17
page
18
page
19
page
20
page
21
page
22
Document related concepts
no text concepts found
Transcript 
Recording of Membrane Potential
Oscilloscope display
Stimulating
electrode
Recording
oscilloscope
mV
+ 60 -
+ 30 -
Insert
electrode
0- 30 -
Electrotonic potential
- 60 - 90 -
Nerve cell
Resting
potential
Local Electrical Circuit
Stimulation
+
+
+ + + ++ + + + + + + + + + + + + + + + - - - - - - - + + + + + + + + + + + + + + + + + + + +
Membrane capacitance
---------------------------++++++------------------------The resting membrane potential
+ +
Intracellular axial resistance
Membrane Potential in
Response to Current Injection
mV
Outward
-45 -50 -55 -
Membrane
-60 potential
Current 0
-65 -70 -
0.5 nA
Inward
Time
-75 -
Time
Current-Voltage (I-V) Relationship
I (nA)
DV =
+1
Outward
+2
Slope dV/dI = Rin
- 80
- 70
- 50
-1
Inward
Hyperpolarization
-2
Depolarization
- 40
I x Rin
Rin (input resistance)
can be defined by slope
of the I-V curve. The I-V
curve shown here is
linear; Vm changes by
10 mV for every 1 nA
change in current,
yielding a resistance of
10 mV/1nA, or 10 x
106W.
Capacitive property of
neural membrane
Membrane potential
Applied current
Time
Time
Current flow across the neural membrane
ionic and capacitive current
Capacitive
current
Ionic
current
K
Na
K
Na
K
- --
+++
Na
K
Electrical equivalent circuit for examining
the effects of membrane capacitance
Extracellular side
Capacitive
current
Ionic
current
Current
generator
_ _
Rin
Ii
Cm
++
Ic
Im
Cytoplasmic side
Electrical equivalent circuit for examining
the effects of membrane capacitance
Extracellular side
Im
Ic
Current
generator
Rin
Cin
Cytoplasmic side
Ii
RESTING STATE: No current flow through capacitor or resistor.
Electrical equivalent circuit for examining
the effects of membrane capacitance
Extracellular side
Im
Ic
Current
generator
Rin
- + + Cin
Cytoplasmic side
Ii
INITIAL STEP: V = 0 and no current flow through the resistor. Im = Ic
Electrical equivalent circuit for examining
the effects of membrane capacitance
Extracellular side
Im
Ic
Current
generator
Rin
- + + Cin
Cytoplasmic side
Ii
Vm increase and drive the current to flow through the resistor. Im = Ii + Ic
Electrical equivalent circuit for examining
the effects of membrane capacitance
Extracellular side
Im
Ic
Current
generator
Rin
- + + Cin
Cytoplasmic side
Ii
Vm increase and drive the current to flow through the resistor. Im = Ii + Ic
Electrical equivalent circuit for examining
the effects of membrane capacitance
Extracellular side
Im
Ic
Current
generator
Rin
- + + Cin
Cytoplasmic side
Ii
Capacitor is fully charged and no more current flow through capacitor. The
system approach steady state and all current flow through the resistor. Im = Ii
Electrical equivalent circuit for examining
the effects of membrane capacitance
Extracellular side
Im
Ic
Current
generator
Rin
- + + Cin
Cytoplasmic side
Ii
The process is reversed after no current is applied.
Membrane capacitance and time
course of potential change
b
a
Membrane
potential (D Vm)
63%
Time constant (t)
Out
Im
Ii
Membrane
current (Im)
In
0
Ionic current (Ii)
Ic
Capacitive
current (Ic)
Neuronal process as a co-axial fiber
Current Generator
RECF
Rm
Ra
Neuronal process as a co-axial fiber
Inner conductor
(cytoplasm)
Outer conductor
(ECF)
Inner layer insulation
(membrane)
Cytoplasm
Membrane
Outer layer insulation
(ECF)
Neuronal process as a co-axial fiber
Outer resistance (raECF)
Membrane
Tranmembrane
resistance (rm)
Axial resistance (ra)
Extracellular fluid (outer conductor)
rm
cm
Membrane
ra
Cytoplasm (inner conductor)
Neuronal process as a co-axial fiber
Current Generator
Rm
Ra
The Length Constant
100%
100
37%
10
l
0
distance
1
stimulation
0
1
2
3
4
Propagation of action potential
The continuous conduction
+50
Direction of propagation
+50
0
0
- 60
- 60
+++++++++++
___________
1
_____
+++++
2
++++
____
3
+++
___
1
_____
+++++
2
++++++++++++++
______________
3
Effect of myelination
• Increase membrane resistance
• Decrease membrane capacitance
Less charge loss in charging
capacitor and leakage across
membrane, therefore increase the
length constant.
Propagation of action potential
The saltatory conduction
+++
___
____
+++
++++
____
Related documents
Hemodialysis and the Artificial Kidney
Hemodialysis and the Artificial Kidney
Metodi per ottenere informazioni sulla sequenza aminoacidica delle
Metodi per ottenere informazioni sulla sequenza aminoacidica delle
La cellula batterica
La cellula batterica
Chapter 4 2015 - Franklin College
Chapter 4 2015 - Franklin College
Diapositive 1
Diapositive 1
Konsep Pemrograman Internet
Konsep Pemrograman Internet
No Slide Title
No Slide Title
Formula Sheet for LSU Physics 2113, Third Exam, Fall ’14
Formula Sheet for LSU Physics 2113, Third Exam, Fall ’14
Superfluid BEC dynamics in peridioc potentials
Superfluid BEC dynamics in peridioc potentials
08-CEAmplifier[1]
08-CEAmplifier[1]
Linear Equations in Two Variables HCF and LCM of
Linear Equations in Two Variables HCF and LCM of
Chapter S28
Chapter S28
Use of ECMO in Severe Sepsis - Hong Kong Society of Critical Care
Use of ECMO in Severe Sepsis - Hong Kong Society of Critical Care
30 kW John Deere.FH10
30 kW John Deere.FH10
Inductance and Capacitance
Inductance and Capacitance