Cerebral hemisphere

The cerebral hemispheres are the two large, symmetrical halves of the cerebrum, the most significant part of the brain. They are divided into the left and right hemispheres, connected by a bundle of nerve fibers called the corpus callosum. Each hemisphere is responsible for controlling opposite sides of the body and contains regions responsible for various cognitive, sensory, and motor functions. The surface of each hemisphere is covered with gyri (ridges) and sulci (grooves), increasing the surface area for higher brain activity.

Location

The cerebral hemispheres are located in the uppermost part of the brain, covering the diencephalon and brainstem. They occupy the largest portion of the cranial cavity, resting above the brainstem and cerebellum, and extend from the frontal lobes to the occipital lobes.

Structure and Anatomy

The cerebral hemispheres are the largest and most prominent part of the brain, consisting of intricate structures responsible for complex cognitive, sensory, and motor activities. Each hemisphere is divided into several lobes, contains various cortical and subcortical structures, and is connected to other parts of the brain by nerve fibers. The left and right hemispheres are largely symmetrical but show some functional specialization.

Lobes of the Cerebral Hemispheres

Each hemisphere is divided into four major lobes, which are distinguished by prominent sulci and fissures:

Frontal Lobe

• Location: Situated at the front of each hemisphere, the frontal lobe is anterior to the central sulcus and superior to the lateral sulcus (Sylvian fissure).
• Boundaries: Bounded by the central sulcus (posteriorly) and the lateral sulcus (inferiorly).
• Notable Gyri:
  • Precentral Gyrus: Located just anterior to the central sulcus, containing motor cortex areas.

Parietal Lobe

• Location: Positioned behind the frontal lobe and above the occipital lobe, extending laterally.
• Boundaries: Separated from the frontal lobe by the central sulcus and from the occipital lobe by the parieto-occipital sulcus.
• Notable Gyri:
  • Postcentral Gyrus: Located immediately posterior to the central sulcus, containing sensory cortex regions.

Occipital Lobe

• Location: Located at the back of the cerebral hemisphere, primarily involved in visual processing.
• Boundaries: Bordered anteriorly by the parieto-occipital sulcus, separated from the cerebellum by the tentorium cerebelli.
• Notable Sulci:
  • Calcarine Sulcus: A prominent fissure that runs through the occipital lobe and contains the primary visual cortex.

Temporal Lobe

• Location: Located beneath the lateral sulcus, the temporal lobe lies inferior to the parietal and frontal lobes.
• Boundaries: Separated from the frontal and parietal lobes by the lateral sulcus (Sylvian fissure).
• Notable Gyri:

        Superior Temporal Gyrus: Found just below the lateral sulcus and contains key auditory processing areas.

Cerebral Cortex

The cerebral cortex is the outermost layer of the cerebral hemisphere, composed of gray matter (neuronal cell bodies). The cortex is highly convoluted, with ridges (gyri) and grooves (sulci) that increase surface area, allowing for more neurons and higher processing capabilities. The cortex is typically about 2 to 4 mm thick and is involved in various cognitive and sensory activities.

• Gray Matter: The cortex is made of gray matter, which contains neurons involved in processing sensory and motor signals, as well as higher cognitive functions.
• White Matter: Beneath the gray matter lies the white matter, which consists of myelinated axons that connect different parts of the brain.

Cerebral White Matter

The cerebral white matter lies beneath the cortex and consists of myelinated axons that form various tracts, connecting different regions within the hemisphere and with other parts of the brain. These tracts are divided into three types:

• Association Fibers: Connect different areas within the same hemisphere. For example, the arcuate fasciculus connects Broca’s area and Wernicke’s area in the left hemisphere.
• Commissural Fibers: Connect corresponding areas in the two hemispheres. The largest commissural fiber tract is the corpus callosum, which allows communication between the left and right hemispheres.
• Projection Fibers: Connect the cerebral cortex to other parts of the brain and spinal cord. The internal capsule is a prominent structure containing projection fibers, carrying information between the cortex and subcortical structures.

Basal Ganglia

• Location: Deep within the white matter of each cerebral hemisphere.
• Structure: The basal ganglia are a collection of nuclei, including the caudate nucleus, putamen, globus pallidus, and substantia nigra. These structures are involved in coordinating movement and other motor processes.
• Substructures:
  • Caudate Nucleus: Located alongside the lateral ventricles.
  • Putamen: Positioned laterally to the caudate nucleus.
  • Globus Pallidus: Found medial to the putamen.

Limbic System

The limbic system, involved in emotions and memory, is situated on the medial side of each hemisphere. Key structures include:

• Hippocampus: Located in the temporal lobe, the hippocampus plays a crucial role in memory formation.
• Amygdala: Positioned near the hippocampus, the amygdala is involved in emotional processing and response.
• Cingulate Gyrus: A prominent ridge located above the corpus callosum, involved in emotional regulation and cognitive control.

Ventricles

Each cerebral hemisphere contains a lateral ventricle, a C-shaped cavity filled with cerebrospinal fluid (CSF), which cushions the brain and removes waste. The lateral ventricles are connected to the third ventricle via the foramen of Monro, allowing CSF to flow through the brain.

Meninges

The cerebral hemispheres, like the rest of the brain, are covered by three layers of connective tissue called the meninges:

• Dura Mater: The tough outermost layer that protects the brain.
• Arachnoid Mater: The middle layer that lies beneath the dura mater.
• Pia Mater: The thin innermost layer that adheres closely to the surface of the brain.

Between the arachnoid and pia mater is the subarachnoid space, which contains cerebrospinal fluid that provides additional cushioning for the brain.

Blood Supply

The cerebral hemispheres receive their blood supply primarily from two major arterial systems:

• Internal Carotid Arteries: These arteries supply the anterior and middle parts of the brain, including the frontal, parietal, and temporal lobes.
• Vertebral Arteries: These arteries form the basilar artery and contribute to the posterior circulation of the brain, supplying the occipital lobe and the cerebellum.

The Circle of Willis is a ring of interconnected arteries at the base of the brain that provides collateral circulation to the cerebral hemispheres, ensuring consistent blood flow even if one artery is blocked.

Corpus Callosum

The corpus callosum is a thick bundle of commissural fibers that connects the left and right cerebral hemispheres. It enables communication between the hemispheres, allowing for the integration of sensory and motor information. The corpus callosum is divided into four regions: the rostrum, genu, body, and splenium.

Function

The cerebral hemispheres play an essential role in controlling a wide range of bodily functions, from sensory perception to complex thought processes. Each hemisphere is responsible for different aspects of cognitive, sensory, and motor functions, with some degree of lateralization, meaning certain functions are more dominant in one hemisphere than the other. Below is a detailed breakdown of the functions of the cerebral hemispheres, organized by specific areas and lobes.

Frontal Lobe Functions

The frontal lobe is responsible for higher-level cognitive processes, motor control, and personality. It is often considered the control center of the brain due to its role in decision-making and voluntary movement.

Motor Control

• Primary Motor Cortex (located in the precentral gyrus): This area controls voluntary movements by sending motor signals to muscles throughout the body. Each region of the motor cortex is mapped to a specific part of the body, a concept known as the motor homunculus.
• Premotor Cortex: This region is involved in planning and coordinating complex movements. It sends signals to the primary motor cortex to execute movement.
• Supplementary Motor Area: This area contributes to the coordination of both sides of the body during complex tasks, such as bimanual coordination.

Executive Functions

Prefrontal Cortex: The prefrontal cortex, located in the anterior part of the frontal lobe, is responsible for higher cognitive functions such as decision-making, problem-solving, planning, and social behavior. It is also involved in personality development and emotional regulation.

Language Production

Broca’s Area: Located in the left frontal lobe (in most people), Broca’s area is involved in speech production and language processing. Damage to this area can result in expressive aphasia, where individuals struggle to form coherent speech.

Emotional Regulation

The frontal lobe, particularly the prefrontal cortex, plays a key role in regulating emotions and impulses, ensuring appropriate social behavior.

Parietal Lobe Functions

The parietal lobe processes sensory information from the body and integrates it with other senses to provide a coherent perception of the surrounding environment. It is also crucial for spatial awareness and movement coordination.

Somatosensory Processing

Primary Somatosensory Cortex (located in the postcentral gyrus): This area receives and processes sensory input from the body, including touch, temperature, pain, and proprioception (body position). Like the motor cortex, the sensory cortex is organized into a sensory homunculus, with different regions corresponding to different parts of the body.

Spatial Awareness and Navigation

The parietal lobe integrates sensory information to help the brain understand spatial relationships and navigation. It enables you to perceive where your body is in space and how it moves relative to your surroundings.

Coordination of Movement

Posterior Parietal Cortex: This region integrates sensory input with motor commands to guide movement, particularly movements involving hand-eye coordination and spatial awareness.

Mathematical and Logical Reasoning

The parietal lobe is also associated with mathematical skills and logical reasoning, particularly in the left hemisphere, where it contributes to number manipulation and spatial reasoning.

Occipital Lobe Functions

The occipital lobe is primarily responsible for visual processing. It receives, interprets, and processes visual stimuli, allowing for the perception of light, color, and shapes.

Visual Processing

• Primary Visual Cortex (located along the calcarine sulcus): This region is the first to receive visual input from the eyes via the optic nerve. It processes basic visual information such as light intensity, contrast, and color.
• Visual Association Areas: Surrounding the primary visual cortex are association areas that further process visual input, allowing for the recognition of objects, movement, and spatial relationships. This enables complex visual tasks such as reading, recognizing faces, and navigating the environment.

Visual Spatial Processing

The occipital lobe, through connections with the parietal lobe, is involved in interpreting the spatial relationships of objects and understanding how they move in space.

Temporal Lobe Functions

The temporal lobe plays a critical role in auditory processing, memory formation, and language comprehension. It also contributes to emotion and facial recognition.

Auditory Processing

• Primary Auditory Cortex (located in the superior temporal gyrus): This area processes auditory information, including pitch, volume, and tone. It receives input from the ears and processes it for basic sound interpretation.
• Auditory Association Areas: Surrounding the primary auditory cortex, these areas interpret more complex auditory stimuli, such as recognizing speech, music, and environmental sounds.

Memory Formation

Hippocampus: Located deep within the temporal lobe, the hippocampus is essential for the formation of new memories and the consolidation of short-term memory into long-term memory. It plays a key role in spatial memory and navigation.

Language Comprehension

Wernicke’s Area: Located in the left temporal lobe (in most people), Wernicke’s area is responsible for language comprehension. Damage to this area results in receptive aphasia, where individuals can produce fluent speech but struggle to understand language or produce meaningful sentences.

Facial and Object Recognition

Fusiform Gyrus: Located in the temporal lobe, this area is involved in the recognition of faces and objects. Damage to this region can result in prosopagnosia, a condition in which individuals are unable to recognize familiar faces.

Cerebral Hemispheric Lateralization

While both hemispheres of the brain share many functions, certain tasks are more dominant in one hemisphere than the other. This phenomenon is called lateralization.

Left Hemisphere Specialization

• Language: The left hemisphere is dominant for language in most people, housing both Broca’s and Wernicke’s areas. This hemisphere is critical for speech production, language comprehension, and reading.
• Analytical Thinking: The left hemisphere is associated with logical reasoning, mathematical computations, and detailed analysis.

Right Hemisphere Specialization

• Spatial and Visual Skills: The right hemisphere is more involved in spatial reasoning, visual-motor integration, and the perception of shapes and patterns.
• Creative and Emotional Processing: The right hemisphere is linked to creative activities such as art and music, as well as interpreting and expressing emotions. It also helps in understanding context and tone in communication.

Limbic System Functions (within the Temporal and Frontal Lobes)

The limbic system, which spans the temporal and frontal lobes, is involved in regulating emotions, memory, and behavior.

Emotional Regulation

Amygdala: This structure is involved in processing emotions, particularly fear, anger, and pleasure. It helps trigger emotional responses and is important in emotional learning.

Memory

Hippocampus: Beyond memory formation, the hippocampus plays a role in emotional memory, helping individuals associate emotions with past experiences.

Corpus Callosum

The corpus callosum is a thick band of nerve fibers connecting the left and right hemispheres, allowing them to communicate and coordinate. It facilitates the transfer of sensory, motor, and cognitive information between the hemispheres, ensuring unified brain function.

Clinical Significance

The cerebral hemispheres are critical for numerous functions, including movement, sensation, cognition, language, and emotion. Damage or dysfunction in any part of the hemispheres can lead to significant neurological and psychological disorders. Strokes, traumatic brain injuries, tumors, infections, or degenerative diseases can affect specific regions of the hemispheres, leading to symptoms such as paralysis, speech difficulties, memory loss, or personality changes.

For example, damage to the left hemisphere can result in aphasia (speech and language impairments), while right hemisphere damage may cause difficulties with spatial awareness and attention (hemispatial neglect). Conditions like epilepsy often originate in the cerebral cortex, requiring careful neurological management or surgery. Diagnosing and localizing damage in the cerebral hemispheres is essential for effective treatment and rehabilitation.