Retina and Vision COPY Flashcards
4 factors that are necessary for an object to be seen?
- Pattern of the object must fall on the vision receptors (rods and cones in the retina) - allows accommodation
- Amount of light entering the eye must be regulated (too much light will “bleach out” the signals)
- Energy from the waves of photons must be transduced into electrical signals
- Brain must receive and interpret the signals
Structure of the retina?
Inside-out laminar structure
Direct (vertical) pathway for signal transmission via the retina?
Photoreceptors to bipolar cells to ganglion cells
IMAGE
Importance of the lateral connection to the direct pathway?
Horizontal cells - receive input from photoreceptors and project to other photoreceptors and bipolar cells
Amacrine cells - receive input from bipolar cells and project to ganglion cells, bipolar cells and other amacrine cells
Function of the photoreceptors?
Converts electromagnetic radiation to neural signals (transduction)
4 main regions of the photoreceptors?
- Outer segment
- Inner segment
- Cell body
- Synaptic terminal
2 types of photoreceptors?
Rods
Cones
Resting membrane potential of a photoreceptor?
Have a DEPOLARISED rmp of -20 mV; compared to other neurons, the resting Vm is more positive
What happens to the membrane potential when there is light exposure?
Vm hyperpolarises
Why is the Vm +ve in a photoreceptor?
Due to the ‘dark current’ - a cGMP gated Na+ channel that is:
• OPEN in the DARK
• CLOSED in the LIGHT
Why is the ‘dark current’ important for vision?
Change in Na+ with light is the signal that enables the brain to perceive objects in the visual field
Action of the dark current in the dark?
Permeability of Na+ and K+ are equal and thus the Vm is between ENa and EK
Action of the dark current in response to light?
Na+ channels close so permeability decreases to below that of K+
Thus, hyperpolarisation occurs (driving the Vm towards the equlibrium potential of K+); this is local and graded (the more light there is, the more hyperpolarisation occurs?)
What are the visual pigment molecules?
Rhodopsin (for rods):
• 11-cis-Retinal (vitamin A derivate) + Opsin (GPCR)
These are present in the membrane folds
Action of light on rhodopsin?
Converts 11-cis-retinal to all-trans-retinal (activated form)
Mechanism of action of all-trans-retinal?
Activates transducin, causing a molecular cascade
cGMP decreases leading to closure of cGMP-gated Na+ channels
Lowered Na+ entry causes hyperpolarisation