17572969
Frage 1
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The lipid bilayer is a [blank_start]hydrophobic[blank_end] environment. This means that it is [blank_start]impermeable[blank_end] to most molecules including [blank_start]ions[blank_end] (they are usually [blank_start]hydrophilic[blank_end]). This means that intracellular and extracellular compartments are established with very different [blank_start]ionic[blank_end] compositions. Ion [blank_start]pumps[blank_end] are used to [blank_start]maintain[blank_end] the gradient.
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hydrophobic
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impermeable
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hydrophilic
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ions
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pumps
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maintain
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ionic
Frage 2
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The inside of a cell contains a slight excess of [blank_start]anions[blank_end] which sets up a [blank_start]negative[blank_end] voltage inside the cell. This voltage is known as the [blank_start]membrane potential[blank_end] (Em). In neurons this is usually about [blank_start]-65[blank_end]mV. Em is determined by the [blank_start]balance[blank_end] of charges.
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anions
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negative
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membrane potential
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-65
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balance
Frage 3
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Ion movement across the membrane is [blank_start]passive[blank_end]. Ion channels are therefore required. There are a few [blank_start]permeant[blank_end] ions (ions that can pass through the channels): Na+, K+, [blank_start]Ca2+[blank_end], Cl-. There are three different types of ion channels that are available:
Non-gated ([blank_start]leak[blank_end]): these set the [blank_start]Em[blank_end] of the resting membrane
[blank_start]Voltage[blank_end]: generate the action potential
[blank_start]Ligand[blank_end] (chemical): generate the Em changes at the [blank_start]synapse[blank_end]
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passive
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permeant
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Ca2+
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leak
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Em
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Voltage
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Ligand
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synapse
Frage 4
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The [blank_start]resting membrane potential[blank_end] of the cell is about -65mV. There are several factors that cause this:
1) the [blank_start]chemical[blank_end] gradient - this is set up due to the [blank_start]potassium[blank_end] [blank_start]efflux[blank_end].
2) the electrical force - the [blank_start]potassium[blank_end] [blank_start]efflux[blank_end] results in the inside being more [blank_start]negative[blank_end] than the outside. This causes [blank_start]potassium[blank_end] influx. At [blank_start]resting membrane potential[blank_end] there is no net movement of [blank_start]potassium[blank_end].
3) the [blank_start]permeability[blank_end] of the membrane to each ion - how easy it is for ions to move across the membrane through ion [blank_start]channels[blank_end].
The following assumptions are made:
- the membrane is only permeable to [blank_start]potassium[blank_end]
- the Em is initially [blank_start]0[blank_end]
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resting membrane potential
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chemical
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potassium
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efflux
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potassium
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efflux
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negative
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potassium
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resting membrane potential
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potassium
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permeability
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channels
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potassium
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0
Frage 5
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Which of the following is true about the Nernst and Goldman equation?
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The Nernst equation defines the value at which the potassium ions are just in excess of the sodium ions.
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For potassium ions, the E(K) value is about -80mV
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For sodium ions, the E(Na) value is about -62mV
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If E(m) doesn't equal the E(ion) value, it is due to an imbalance in electrical and chemical effects. This is called to potential driving force.
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The value of the resting membrane potential is closer to the E(K) value because here the membrane is more permeable to potassium.
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The Goldman equation is used to calculate the E(m) and where it lies between E(Na) and E(K).
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