At rest, the neuron is called polarized Show
The neuron become activated when an incoming impulse opens the ion channels Sodium ion channels open allowing a more positive charge on the inside of the cell membrane, known as depolarization Potassium channels open allowing the positively charged to move out through the semipermeable membrane, returning the neuron to a polarized state The next group of channels flips open briefly and continues the action potential all the way down the axon Recommended textbook solutions
 Myers' Psychology for the AP Course3rd EditionC. Nathan DeWall, David G Myers 955 solutions
Consumer Behavior: Buying, Having, Being13th EditionMichael R Solomon 449 solutions Social Psychology10th EditionElliot Aronson, Robin M. Akert, Samuel R. Sommers, Timothy D. Wilson 525 solutions Myers' Psychology for AP2nd EditionDavid G Myers 900 solutions The brain is difficult to study not only because of its inherent complexity; the billions of neurons, the hundreds or thousands of types of neurons, the trillions of connections. The brain also works at a number of different scales, both in the physical sense and in the time domain. To understand the brain’s electrical activity at these scales, no single technology is enough. As a result, neuroscientists have a suite of tools at their disposal. Some of these, such as fMRI and EEG, can be used in humans because they are non-invasive; they work through by looking into the skull. But these tools suffer from a lack of detail. To get a more microscopic picture of neuron activity, researchers turn to animal models. This allows the behaviour of individual neurons, or small groups of neurons, to be analysed in much greater detail. Functional Magnetic Resonance Imaging (fMRI)Functional magnetic resonance imaging, or fMRI, might be the most widely known technology for recording neural activity, but it doesn’t actually record activity of neurons – instead, the multicolour images you see of particular brain regions being lit up reflect blood flow in the brain. More precisely, the signal you see reflects the relative presence of oxygenated versus deoxygenated blood; active regions require more oxygenated blood, and so despite being indirect, fMRI allows scientists to infer activity patterns of neurons. fMRI has become a staple of modern neuroscience research because it allows brain anatomy (obtained from a structural, rather than functional, MRI scan) and function to be correlated in humans. But it does have limitations. Both the spatial (~1 mm3, relating to location) and temporal (~1–2 sec, relating to time) resolutions are poor compared to what we’d want; a cubic millimetre contains around 60,000 neurons – enough to sustain the entire life of a fruit fly or lobster – and complex perceptual decisions take only hundreds of milliseconds, but fMRI provides no access to this information. Nevertheless, fMRI allows an unrivalled look at where and to what extent different functions may be localised within the human brain, and researchers continue to devise ways to improve its spatial and temporal resolution, for example by making the technique sensitive to neuronal changes rather than changes in blood flow. No current technique matches fMRI for its ability to ‘map’, or determine the likely source of, cognitive function within the human brain. Electroencephalography (EEG)Electroencephalography, or EEG, is probably the second-best known technique for recording neural activity. Whereas fMRI records blood flow, a proxy of neuron activation, EEG directly records the brain’s electrical activity via electrodes placed on the scalp of the subject. However, EEG doesn’t record action potentials, the electrical events that neurons use to communicate with each other. Instead, it surveys the summed activity of hundreds of thousands or millions of neurons in the form of oscillatory activity. In contrast to action potentials, it’s not known what information these oscillations actually carry, but different frequencies of oscillation do correlate with different behavioural states. EEG has a 'temporal resolution' far superior to fMRI (~1 ms vs. 1 sec). Because of this, EEG can be used to more accurately track neural dynamics in awake humans, and is often used to determine the brain’s electrical response to a stimulus or condition. The primary limitation of EEG is its poor spatial resolution, much poorer than for fMRI. Although it’s known that EEG signals only come from the cerebral cortex, it remains extremely difficult to know precisely where in the cortex signals arise. Furthermore, its cortical bias means that we can’t use it to measure what happens in the hippocampus, where many memories are made and stored, or in the substantia nigra or striatum, regions affected by Parkinson’s Disease. So unlike fMRI, mapping of activity is not really possible with EEG. Electrocorticography (ECoG)Electrocorticography is similar to EEG in that it measures the combined activity of millions of neurons, often in the form of oscillatory waves. But there are two major differences. First, ECoG requires insertion of the electrode array under the scalp, and so requires surgery. For this reason, ECoG is only suitable for patients already scheduled for a medical surgery that involves opening of the scalp. Second, ECoG allows significantly improved localisation of the activity source, as well as the recording of higher frequency electrical activity. Both of these characteristics assist during epilepsy surgery, but for pure research purposes, the technique is too invasive to be used in humans who don’t already require brain surgery. SummaryNeuroscientists are justifiably limited in the sort of approaches they can use to study human brain activity. However, so far no technology exists that allows detailed neuron activity to be recorded through the human skull, meaning that the measures we can take give fairly coarse information as to how our brains work. These spatial and temporal resolution limits will undoubtedly be improved in the near future, enabling more precise measurements and greater insights into human brain activity. Furthermore, complementary approaches that allow the temporary disruption of neuronal processing will help us to understand what sorts of regional brain dysfunction might lead to the cognitive deficits associated with mental disorders. QBI Laboratories using fMRI
QBI Laboratories using EEG
What is the unique capacity of change that occurs in your brain?There are two main types of neuroplasticity: Functional plasticity is the brain's ability to move functions from a damaged area of the brain to other undamaged areas. Structural plasticity is the brain's ability to actually change its physical structure as a result of learning.
In which of the following ways does functional magnetic resonance imaging detect?Functional magnetic resonance imaging, or FMRI, works by detecting the changes in blood oxygenation and flow that occur in response to neural activity – when a brain area is more active it consumes more oxygen and to meet this increased demand blood flow increases to the active area.
When neuroscientists use electrodes to measure brain activity what exactly are they measuring?An EEG is a test that detects abnormalities in your brain waves, or in the electrical activity of your brain. During the procedure, electrodes consisting of small metal discs with thin wires are pasted onto your scalp. The electrodes detect tiny electrical charges that result from the activity of your brain cells.
Which of the following are techniques for studying the brain that creates an image of the brain using a magnetic field and radio waves?A technique that produces clearer images of the brain (and other body parts) by using magnetic fields and radio waves is known as MRI- Magnetic Resonance Imaging.
|
The fmri scan monitors changes in ____ that occur in association with brain activity.
Postagens relacionadas
direito autoral © 2024 comojogaruno Inc.
