ESTRUTURA DA SUBSTÂNCIA BRANCA E DO CÓRTEX CEREBRAL - PARTE 2

Name: ESTRUTURA DA SUBSTÂNCIA BRANCA E DO CÓRTEX CEREBRAL - PARTE 2
Uploaded: 2021-09-17T00:00:00.000Z
Duration: 1 h 4 min 11 s

Cerebral Cortex Structure and Function

Overview of the Cerebral Cortex

The cerebral cortex is a thin layer of gray matter that covers the white matter of the brain, receiving sensory impulses that become conscious.

It plays a crucial role in interpreting sensory information, highlighting its importance in processing and understanding stimuli.

Functions of the Cerebral Cortex

The cortex initiates voluntary movements and is linked to psychic phenomena, indicating its multifaceted role in both physical and mental functions.

Traumatic brain injuries can severely impact victims due to damage to the cortex, affecting either sensory or motor functions depending on the injury's location.

Layers of the Cerebral Cortex

The cortex consists mainly of isocortex (90%), which has six distinct layers: molecular, external granular, external pyramidal, internal granular, internal pyramidal, and fusiform.

Each layer has unique characteristics; for example, the molecular layer contains horizontal fibers for interconnecting different levels.

Neuronal Connections within Layers

The external and internal granular layers connect with neighboring neurons through interneurons to enhance information interpretation.

The external pyramidal layer primarily sends descending projections to white matter areas while also being involved in sensory reception.

Functional Classification of the Cortex

The internal pyramidal layer projects towards critical areas like the brainstem and spinal cord; it plays a significant role in motor function.

Anatomically, cortical classification relies on sulci (grooves) and gyri (ridges), aiding in locating cortical lesions effectively.

Important Sulci and Gyri

Key anatomical features include major sulci such as the central sulcus (Rolando), which separates important gyri: precentral (motor control) and postcentral (sensory perception).

Neuroanatomy Overview

Key Structures of the Brain

The discussion begins with an overview of the occipital, parietal, and temporal lobes, highlighting their anatomical features.

The cingulate gyrus is identified as a significant structure located between the corpus callosum and other gyri, emphasizing its importance in brain function.

The parieto-occipital sulcus is introduced, along with the calcarine sulcus which houses the primary visual area of the brain.

Lobes and Their Functions

The frontal lobe is defined as being anterior to the central sulcus, with specific mention of its gyri: superior frontal gyrus, middle frontal gyrus, and inferior frontal gyrus.

In relation to the parietal lobe, key structures such as the postcentral gyrus are discussed alongside superior and inferior parietal lobules.

Interactions Between Lobes

The supramarginal gyrus is noted for its association with both parietal and temporal lobes; it plays a role in sensory integration.

The angular gyrus is highlighted as another important structure within this region that contributes to various cognitive functions.

Temporal Lobe Features

Three distinct gyri within the temporal lobe are mentioned: superior temporal gyrus, middle temporal gyrus, and inferior temporal gyrus.

A deeper look into medial views reveals additional structures like the parahippocampal gyrus and uncus.

Structural Classification of Cortex

Moving towards structural classification, distinctions between allocortex (primitive cortex with 3 to 5 layers) and isocortex (more complex cortex with 6 layers) are made clear.

Allocortex relates to older evolutionary developments while isocortex represents more recent advancements in brain complexity.

Summary of Telencephalic Lobes

An overview concludes by summarizing five telencephalic lobes: frontal (pink), parietal (blue), occipital (green), temporal (yellow), and insula located deep within lateral sulci.

Understanding the Brain's Cortical Areas

Mapping Designated Areas of the Cortex

The speaker identifies 52 designated areas in the brain, referencing specific coordinates (e.g., area 1147 22/45 4486 41237), which are well-known in clinical and medical research contexts.

Experiments involving stimulation of specific cortical areas have been conducted on dogs, monkeys, and humans, revealing that subjects report various experiences and feelings during stimulation.

Specific movements can be elicited from certain regions of the cortex, indicating a direct relationship between cortical areas and motor functions.

Structural Classification of the Cortex

The classification of cortical architecture includes isocortex and allocortex; isocortex is more recent evolutionarily and consists of six distinct layers.

Within isocortex, there are heterotypic regions where individualization of layers varies; these can be granular or agranular based on neuron types present.

Neuronal Populations in Sensory Areas

Sensory areas show a predominance of granular neurons to process incoming information effectively from subcortical centers.

In contrast, motor regions exhibit a higher population of pyramidal cells compared to granular cells due to their role in motor projection.

Phylogenetic Development of the Cortex

The cortex comprises three main parts: archicortex, paleocortex, and neocortex. Archicortex and paleocortex have fewer layers (3 to 5), representing more primitive structures.

Neocortex occupies about 90% of the cerebral cortex area with six organized layers that facilitate complex processing.

Functional Classification of Cortical Areas

Images illustrate locations such as paleocortex within the temporal lobe; specifically highlighting structures like the hippocampus which plays a crucial role in memory.

Understanding Cortical and Subcortical Connections

Overview of Cortical Projections

The subcortical centers project to the cortex, indicating a bidirectional relationship between these areas.

Secondary unimodal areas in the cortex interpret specific sensory and motor information from primary areas.

Auditory Information Processing

Auditory information travels from the inner ear through the cochlear nerve (eighth cranial nerve) to nuclei in the brainstem known as cochlear nuclei.

From the cochlear nuclei, fibers project to the inferior colliculus and then to the lateral geniculate body, ultimately reaching the primary auditory cortex.

Interpretation of Sound

Distinguishing sound involves recognizing pitch, intensity, and tone; however, understanding its meaning requires additional cognitive processing.

Secondary association areas are larger with more neuronal populations, enhancing memory formation related to sounds.

Unimodal vs. Supramodal Areas

Each primary sensory area has a corresponding secondary unimodal area dedicated to that specific modality (e.g., auditory, olfactory).

Tertiary association areas are supramodal; they integrate multiple sensory inputs for complex cognitive functions like planning and decision-making.

Complexity of Cognitive Processing

These supramodal regions converge diverse sensory and motor information, contributing significantly to our behavior and internal perceptions.