bio approach: neural networks

Question 1

definition of neuroplasticity

Answer 1

neuroplasticity is the ability of the brain to change throughout the course of life.

Question 2

changes developed are due to?

Answer 2

the creation of new synaptic connections between neurons and the breakdown of ones no longer in use; in response to biological maturation, genetics, environmental stimulus, learning or brain injury.

Question 3

brief into neural networks

Answer 3

the pathways otherwise known as neural networks consist of nerve cells, neurons and these cells pass electrical impulses from one another and are responsible for transmitting signals and information from our senses.

Question 4

how neural networks are formed

Answer 4

this repeated firing of the neurons, called long-term potentiation, results in gene expression which causes the neurons to sprout new dendrites – known as dendritic branching. dendritic branches increase the number of synapses available for a behavior thus forming the neural network.

Question 5

the study used to explain it?

Answer 5

study conducted Draganski et. al. (2004) demonstrates how repeated action can lead to the growth of neural networks.

Question 6

draganski et al. (2004) aim -

Answer 6

to see whether learning a new skill - in this case, juggling - would affect the brains of participants.

Question 7

draganski et al. (2004) sample -

Answer 7

24 volunteers (21 females and 3 males) who were between the ages of 20 and 24.

Question 8

draganski et al. (2004) procedure -

Answer 8

each P had an MRI scan at the start of the study to serve as a base rate for grey matter and brain structure.

juggling condition - taught a three-ball cascade juggling routine. they were asked to practice this routine and to notify the researchers when they had mastered it. at that point, the jugglers had a second MRI scan. after the second scan, they were told not to juggle anymore. then a third and final scan was carried out three months later.

non- jugglers -> control group.

MRI scans: identify the part of the brain involved in the formation of visual memory. to analyze the MRI scans, the researchers used voxel-based morphometry [VBM] to determine if there were significant differences in neural density (grey matter) in the brains of jugglers vs. non-jugglers.

Question 9

draganski et al. (2004) results -

Answer 9

first, MRI scans of both groups showed no significant regional differences in the grey matter between the two conditions.

However, at the end of the first part of the study (after mastery), the researchers observed a significant bilateral expansion in grey matter in the mid-temporal area (hMT/V5) and the left posterior intraparietal sulcus for the juggler group.

3 months after the participants stopped juggling - when many were no longer able to carry out the routine - the amount of grey matter in these parts of the brain had decreased.

however, the jugglers still had more grey matter in these areas than at the first brain scan (before they started juggling).

no change throughout the study in the non-juggling sample.

Question 10

conclusion -

Answer 10

grey matter grows in the brain in response to environmental demands (learning) and shrinks in the absence of stimulation (lack of practice), and this shows a causality relationship b/w learning and brain structure.

provides strong evidence for neuroplasticity, the brain’s ability to adapt and change structure in response to new experiences.

P who learned to juggle showed increased grey matter in the mid-temporal area, a region associated with visual memory, compared to the non-juggling control group.

increased grey matter density suggests a potential increase in the number of synapses, leading to formation of new neural connections. explaining the improved visual memory performance observed in the jugglers.

these findings suggest that even complex skills like juggling can induce brain plasticity in young adults, challenging the previously held belief that such changes were limited to early development.