Neuroanatomy made ridiculously simple

Video Statistics and Information

Video

Captions Word Cloud

Reddit Comments

Captions

well I really I really appreciate the opportunity to be here I apologize that I'm in scrubs but Christy put me to work by booking two cases for me today - as well as a lecture so and then she gave me the task of making neuroanatomy ridiculously simple so what I did is I found a video that's always the easy way to make things simple I'm not the pots of the day before by yes neocortex frontal lobe it goes pretty fast to get right all down hippocampus neural node right hemisphere pons and cortex visual Sylvian fissure pineal left hemisphere cerebellum left cerebellum right synapse hypothalamus striatum dead life Safari stripe axon fibers mattered ray central tegmental pathway temporal lobe white poor matter for brains go central fissure courts final riot oh alright we'll stop is too much okay Sonoran anomie is a is fun it's not that much fun but so what I'd like to do and it obviously it's very difficult to put together a you know a big course in two 45-minute talk so I apologize for not being very in-depth but I want to just quickly run over the basic 'nor anatomy that I think all of us need to be familiar with I'm just going to function on brain I'm just going to focus using a brain anatomy and so just as a reminder the the brain obviously is a very complex organ and it develops from what is a rather simple tube into this very complicated structure with many gyri and sulci and a very complex folding pattern that results in the anatomy that we look at and so when we look at the brain as a final product we can generally divide it into regions and we'll try to do that today and talk about what happens in the cerebral hemisphere which is the cortex of the brain which is the area that we we often think of when we talk about the brain but there clearly are some very important deep structures the diencephalon which is a thalamus and hypothalamus play very critical roles as obviously the brainstem is pinky the brain emphasized there and then we'll talk a little bit about the cerebellum as well so starting with a cerebral hemisphere this really is the the largest portion of the brain it's about 83 percent of the total brain mass it covers the diencephalon it covers the midbrain it sits above the cerebellum and it does have what at first glance looks like a random pattern of gyri and sulci but as we know there is a very unique characteristic pattern here that does allow us to identify different regions of the brain and different functional areas in the first level of dividing the brain into regions is dividing it into lobes so as I'm sure we all remember from school the frontal lobe and the parietal lobe are separated by the central sulcus and that's the main sulcus it separates these two regions of the brain there's a lateral or Sylvian fissure that separates the frontal lobe from the temporal lobe there's an occipital lobe is divined by the pre occipital knotch and then there is the transverse fissure which will divide the super ten toriel space from the infra ten torial space so this is a lateral view of the brain if we look at the brain from above we can identify again a frontal parietal and occipital lobe and a central sulcus here that's dividing the frontal from the parietal so this gives us a real general kind of zipcode segmentation of the brain it's important to keep in mind that the brain is not just that lateral surface that we look at there's a medial surface so again we can identify a frontal and parietal lobe separated by a pair of central lobule which is where the central sulcus dives in functionally that's a leg area we'll talk a little bit about that and then we can identify an occipital lobe separate from the parietal lobe to find again by the pre occipital knotch laterally and then the parietal occipital sulcus here we know this is where vision is for example so these discs anagen general subdividing of the brain has some functional significance and then if you look at the brain front below there's a ventral surface as well so again a very characteristic pattern of temporal lobe gyri and sulci and interhemispheric fissure and then now the cranial nerves and the brainstem itself and the cerebellum are more evident so a lot of complicated anatomy and there's a long history of trying to understand the anatomy of the brain and and one of the earliest important steps and trying to understand the cortex since it did seem like a very random structure was some of the work that Broadman did so Broadman was a German neurologist not a neurosurgeon unfortunately but still very very smart and he was one of the first to really look at these sub regions and he looked at them histologically he looked at the cell types in those areas and began to divide the brain into regions and so this is a colorized version of the original diagram that Broadman pub it was done in black and white dividing the brain into 52 cortical areas and this has been refined quite a bit over time and there obviously we have a better understanding than then Broadman had but this was a really important first step forward in understanding that the brain is not just a random gyrated structure but but there is some function here so here's all the 52 areas we won't go over all of them but this will be on the exam so it's a very important way I think the the more useful way to look at brain anatomy and what we try to you know teach our trainees here is to really look at the anatomy functionally rather than structurally so I think it's very useful to to look at the frontal lobe of the brain and to think about an area that is prefrontal which is a pink area here and we can talk about the prefrontal cortex and what happens there we can talk about the motor region of the frontal lobe so we can divide this frontal lobe into two regions we can talk about a sensory area which is the blue and we have a primary sensory area here we also have another primary sensory area in the back of the brain and then a lot of the light blue or these association areas and association areas are very interesting because a lot of higher-order functioning happens in these association areas bless you and the prefrontal cortex too is technically an association area so these are parts that are taking multiple inputs associating them with one another to comprehend our world so what I'd like to do is walk through these so we'll start with the prefrontal cortex this is the part of the brain that is the most complex and most developed in humans and so this really is is really the closest thing to where our mind sits if you will a lot of complex behavior cognitive behavior social behavior personality expression those of you that have taken care of patients with pre frontal lobe injuries know that that people change when this part of the brain is not working well so a lot of executive functions is well lying here so a lot of our higher cognitive processing trying to follow rules perform multiple tasks at a time control impulses and again a lot of personality lies in the prefrontal cortex and a lot of working memory is here too so for those of us that are patients that have a hard time with working memory hanging on to a rule hanging on to short-term memory and being able to retrieve it while doing a task it's very difficult when you have a front prefrontal cortex injury when patients have a head injury for example which is one of the most common causes for brain injury this dis prefrontal cortex especially the frontal lobe and orbital frontal surface are very prone to moving within the cranial vault and getting damaged so that's why we we see quite a bit of that so that's a brief brief kind of idea of what happens in the prefrontal area if we move back to this darker right area this is the the more posterior portion of the frontal lobe and this is the motor area and so the motor area has multiple regions there's a primary motor cortex which is Broadman area for and in there premotor areas there's an eye field in a language field here so the primary motor cortex is the one we all learned back in school this is the precentral gyrus so it's right in front of that central gyrus so it's right at the very back of the frontal lobe very large pyramidal cells here which is why Broadman identified this as region 4 it's a very distinct anatomic region and it does have a somatic topic organization so a lot of us remember the homunculus this idea of a little map of the body within the frontal lobe so the more lateral parts of this are areas that are controlling movement of hand and face and mouth the more medial and super areas are where the leg area is located and this becomes important in patients that have a stroke or a tumor we're out here you're going to expect more facial droop and weakness an AC a stroke for example which would affect more the pair of central lobule may result in just leg weakness but the arm and hand and face may be ok so this this organization is very important functionally and the motor cortex is is a very simple and starting basic starting point for for motor movement but there's a lot of motor planning that's involved and that's where the pre motor area comes into play so as you get closer to that prefrontal area where you're more cognitively engaged that's also where you become where you're focusing your planning and your access to motor plan and selecting different motor plans and inhibiting competing plans so a lot of that happens here in this premotor cortex area which is a very important area in is as you know if you've had a patient that's at a premotor cortex injury a lot of times they may even look like someone that has a complete motor paralysis because they just have a very hard time with initiating and having that drive to move moving the eyes is a very complex motor function so that occurs in the in the frontal eye field which is located right here and then Broca's area which is this area here is a speech area and it's a pretty large area because speech production can happen with your mouth it can also happen with your hand you can sign speech you can write and you can speak and so Broca's area is a very complex area it's not a coincidence that it's located right next to the part of the monkey that's where your mouth and hand is right so it makes sense that an area that's going to initiate that type of motor plan is going to be right next to that part of the monkey list so then if we move back behind the central sulcus we get into the sensory areas and a lot of the brain is dedicated to sensory processing to understanding the world around us and understanding stimuli as they come in and a lot of it happens in this primary sensory cortex or this post central gyrus HR is right behind the central sulcus and a primary somatosensory cortex is very similar to the motor cortex in that it also has a somatic topic organization so there is a similar organization where the medial portion is the leg the more lateral portion is the hand and face and again the distribution here is is biased towards areas like the fingers the hand to face the mouth or your sensory discrimination is very high areas like your back your sensory discrimination is much lower and so most of us in school did the kind of sensory discrimination tests where you take two little paper clips and you see how far apart you got to get them before they feel like two pokes versus one and if you do that in your fingertips you're really really good at that on your back it's very hard to get a really separate amount because as the plots are much bigger it's just not not a high-resolution area so this is a primary somatosensory cortex but then this large light blue area are these other sensory areas these Association areas and there's a lot going on in here there are areas that are associating input from the hands perhaps from the eyes as well or from the ears as well where the primary auditory region is there are areas that are going to get input from vision as well so areas that lie within here are going to access input from the primary somatosensory primary auditory primary visual so again it makes sense functionally why you would put these sensory Association areas here and so we can plot out primary Association areas for every sensation we have so there's going to be an olfactory cortex or smell vestibular cortex or balance of gustatory cortex for taste and so on and these are going to land in these dark blue areas and then they're going to come into this sort of parietal temporal Association area where it's going to be processed and comprehended now vision is an interesting one because it lies on that medial surface of the brain so if you look at the lateral surface it's as tip all the way back here at the occipital pole but if you look at the medial surface of the brain you can see that actually the sensory cortex has a very interesting orientation it lies right along this calcarine sulcus which is a nice dominant sulcus right in the middle the medial occipital lobe and this is area 17 and this is primary visual cortex so the visual input that comes from the eyes relays through the thalamus and comes back to the occipital lobe comes here and so it's the same idea where you have a primary area so this is an area that's going to detect the flash of light for example in a certain area but understanding what you're seeing in that area understanding movement and then identifying an object is going to happen in association areas so when we take care of patients it's important to keep in mind that a lesion of a primary area and a lesion of a Association area are going to have different deficits in Association areas where a lot of comprehension is going to occur one example of that is the vision visual input that comes into the primary visual cortex actually goes forward to the Association areas in two different streams there's a dorsal stream which actually goes towards a parietal lobe and that's a part of the brain that that is focused more on on where something is where an object is where you are geographically where structures are within your world and then there's a ventral stream that goes towards a temporal lobe which is an association area that's more of a what area so a lot of our recognition of a face of an object naming things is going to occur here so one example of how input coming to the primary visual cortex might make you blind cortically blind if you weren't able to get that input to begin with but if you get that input you may have a hard time identifying where something is versus what something is depending on whether you have dysfunction in there in your dorsal stream or your ventral stream so these are things that that do come into play again when we're seeing patients with injuries to different brain areas and in these association areas which we've kind of talked about multiple times again they occupy different areas of the brain the prefrontal cortex really is a very large complicated Association area because identifying objects in your world but then formulating a plan initiating a response and trying to do that in the context of the information you just processed is very complex and so we're talking about information coming into sensory and then perhaps going to prefrontal where you may decide how you feel about it how you want to respond to it what your mother or father told you you're supposed to do during a situation like this this is all prefrontal cortex and then you're going to go to premotor to plan a response if it's a motor response and then go to your motor cortex so this really is a very complex Association area these are really complex sensory Association areas where you're trying to interpret that information and identify what it is and in language both the motor language in the sensory language so that's the the Wernicke's area which is our sensory language and then Broca's our motor language these are association areas these are areas which are taking input from multiple primary areas to to either understand what you've seen or formulate a response there is an area called the insula which we're kind of ignoring because it's hidden under the lateral sulcus here but the insula is a very interesting area where there's not a great understanding of what it does really plays a role in language does play a role in some visceral kind of organ sensation some of the autonomic type of responses and the limbic cortex and the way we respond to things now we talked a lot about gray matter here but there's white matter connecting everything and so those of us that have taken care of patients with diffuse axonal injury know that you can have a great cortex but if white matter tracks are damaged then function is compromised so there are a lot of important white matter tracks to keep in mind the ones that cross the brain like the corpus callosum or the smaller anterior and posterior commissure these are called kama sure's these ones that connect the left and right brain together those are very very important for Association and comprehension of complex input their association fibers which run within one hemisphere one like the super longitudinal fasciculus for example and their projection fibers which are actually kind of the input output from the brain and so these white matter tracks are absolutely critical and many of us have seen patients where the cortical process might be fine for example a patient with a conductive aphasia you know Wernicke's file is okay Broca's is okay but that arcuate fasciculus it connects it to is not okay so you can see it a dramatic dysfunction even though the cortical regions are working okay so if the connections are not there you know this complex computer falls apart so it's very important to keep in mind that this Anatomy is there it can be affected by by injury and in surgeons you know we can actually map this we can image this with tractography diffusion tensor imaging we were much more thoughtful now about white matter tracks in the brain to kind of finish off this you know walk through the anatomy of the cortex you know we talked about gray matter areas we talked about white matter it's important to keep in mind that when you when you take a slice through the brain either imaging on an MRI or cat scan or anatomically in the laboratory you see a lot of gray matter that's deep in the brain as well so it's not just gray matter on the surface white matter underneath there are areas of deep gray matter and there are many areas in the brain these are very complex areas some examples are the basal forebrain nuclei which sit in the lower back part of the frontal lobe deep structures these are areas that are very important in acetylcholine mediated transmission we think in Alzheimer's diseases as an area that does not function well and we lose cholinergic transmission the basal ganglia is another great example which is a group of many structures including the caudate the putamen the Globus pallidus a subthalamic nucleus these are areas that are involved in motor processing kind of scaling movement picking different motor plans so patients with Parkinson's disease with Huntington's disease the cortex is fine but movement is still affected because of these basal ganglia these deep structures so having just a normal motor cortex and intact white matter tracts doesn't mean the motor function is going to work well you also have to have this deeper cortical relay working well in these deeper gray matter structures being able to regulate and control the cortex so those are the hemispheres and then we'll kind of move a little bit deeper to some of these deeper areas as we head to the homestretch here so the thalamus is a very important structure and this is one of the two parts of the diencephalon so the diencephalon is made up of the thalamus and the hypothalamus the thalamus which means inner room is is a very interesting structure located deep in the brain there's two of them they look like these small hard-boiled eggs connected to each other they form the walls of the third ventricle and and they're really kind of a cutoff person if you will between the brain and the peripheral nervous system so information that comes up to the brain almost always relays through the thalamus so sensory information visual information coming up will almost always synapse in the thalamus and then the thalamus shoots it up to the cortex so the thalamus plays is a very important role in that way if you look at a brain the thalamus is this structure here so it's sitting right in the middle of the brain if we look at a cartoon here the thalamus are these two paired blue structures there's an inter thought lamech adhesion that connects the two and then the thalamus just like everything else in anatomy is broken up into sub regions we're not going to go over these this is you know whole lecture itself the lamech Anatomy is a big textbook I have which is very scary that goes over the thalamus but you know some kind of just basic things just to put it in the context so we talked about sensory input for example from the hands and feet comes into the thalamus and it goes to the VP L the ventral posterior lateral nucleus of the thalamus which is this big blue area and then this shoots it up to that primary sensory cortex so all the input that the primary sensory cortex gets gets from the thalamus so again you can think about someone who's had a thalamic stroke or thalamic tumor you know they have major major deficits cortex is fine sensory in the hand is fine but input doesn't get there if you don't have the cut off person vision for example runs through the thalamus it goes to lateral geniculate nucleus auditory input goes to the medial geniculate nucleus a lot of the sensory information has to run through the thalamic relay and the thalamus for that reason is an area that we're very interested in with deep brain stimulation and neuromodulation because it is a very critical cutoff or relay structure that can be modulated so you can maybe turn it up or turn it down one interesting area the thalamus is this inter laminar nuclei which kind of run in the middle here this is an area that in a patient gosh it's been ten years now I think that was minimally responsive in a vegetative state a group of surgeons put a stimulator in this area and actually were able to increase wakefulness in that patient this was someone that started feeding themselves and communicating and before they weren't doing that at all because the inter laminar nuclei or an area that that take input from the activating system the reticular activating system that wakes you up in the morning and relays it to the brain to turn on the brain so the thalamus is a very interesting area and it's one that a lot of very smart people are researching to try to better understand how we can modulate thalamic function below the thalamus is the hypothalamus so if this is a thalamus then below it as a hypothalamus hypothalamus is a very more basic area of the brain it functions on its own so it's not a relay center like the thalamus and it it's really focused on a lot of autonomic type of basic functions in the brain so emotional response is body temperature hunger thirst sex drive sleep-wake cycle control your hormones the pituitary gland is under the control of the hypothalamus these are very important structures so if you had someone with a hypothalamic injury if you've seen a child with hypothalamic seizures for example those manifests as a jelastic kind of laughing seizure I mean it's a very very interesting area of the brain if a young child has injury to the hypothalamus like with a tumor like a cranium for angioma they can become severely obese because they have total disruption of their normal satiety function so hunger and thirst are here's a very very critical deep brain structure different from the thalamus because it's not focused on interfacing with the cortex it's a very basic function in the brain that lies below them and then moving beyond the diencephalon now we'll go down to the brainstem so we're working our way down so the brainstem really sits now in the posterior fossa so we're below the cortex below the diencephalon and a lot of automatic programs reflexive type of behaviors come from here so this is not conscious processing in the brainstem and it is broken down into three areas as you know so if we look at that ventral surface of the brain we can take that brainstem and break it up into a midbrain of pons and the medulla and the anatomy means is very complex you can't really see them much from the outside so a lot of the anatomy that we learned in school is to slice through this and look at the slice which means on a good MRI you could also see this and you can identify different structures within the midbrain the midbrain is going to sit right on this upper third of the brainstem same thing with the pons it occupies this middle third of the brainstem if you kind of slice through it you can see the anatomy within the pons which is also very complex and then if you get down to the medulla which is just the very very bottom where we transition to the spinal cord again very very complex to summarize the brainstem I didn't want to go into brain stem a lot because it is very complicated but all the cranial nerves come from the brainstem so all the nerves that go to the head face neck so control of eye movement control of hearing speaking speech swallow even shrugging your shoulders they crayon there 11 that goes to your neck muscle is sternocleidomastoid are coming from the brainstem the brainstem is also taking sensory input from the head and neck and face so hearing taste balance these are things that are going to come into the brainstem and then gets sent up to the thalamus before they go up to the cortex so the the brainstem is a very important direct communication through the cranial nerves and then finally is a cerebellum the cerebellum is means the little brain it kind of is a little brain it sits down below it's connected to the brainstem it doesn't have a complicated you know prefrontal cortex so fortunately it's not thinking for you but what it does do primarily is coordinating n't it does have other functions too as a lot of interesting work on on the cerebellum but the most basic function that it performs is coordinating movement and the cerebellum has a very complicated structure of what we call folia they look like leaves so they don't have the gyri and sulci but they have the folio and fissures in them and the more central part of the cerebellum controls movement in the in the head and neck and trunk so it's more axial coordination whereas the more lateral cerebellum is more appendicular or arms hands and legs so those of you that have had patients with either cerebellar tumor cerebellar stroke you've certainly seen that if it involves the the medial part of the cerebellum you're going to have more truncal instability but patients might do really well with their arms and hands if it's more lateral cerebellum than you see things like dysmetria to synergy at the statical kinesia these deficits of distal appendicular arm and hand movement and the cerebellum does also process some sensory input most of his balance related and proprioception related because that's really critical for coordinating movement okay so that is my neuroanatomy made ridiculously simple I prefer the cartoon that you

Info

Channel: World Federation of Neuroscience Nurses

Views: 546,273

Rating: 4.9054551 out of 5

Keywords:

Id: gvX5ao5SCjE

Channel Id: undefined

Length: 27min 43sec (1663 seconds)

Published: Wed Dec 30 2015