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Summary
This document contains information on the Peripheral Nervous System, including anatomical divisions, functional divisions, white and gray matter organization, spinal cord, spinal reflexes, and more. Key concepts are discussed, along with learning objectives for each section. The document is a study guide for a course on Human Anatomy and Physiology, but the content structure isn't a standard exam paper.
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Learning Objectives: 1. Divisions of Peripheral Nervous System (PNS): ◦Functional Divisions: ▪ Somatic Sensory (skeletal muscles, skin, joints) ▪...
Learning Objectives: 1. Divisions of Peripheral Nervous System (PNS): ◦Functional Divisions: ▪ Somatic Sensory (skeletal muscles, skin, joints) ▪ Visceral Sensory (internal organs) ▪ Special Sensory (smell, taste, vision, hearing, balance) ▪ Somatic Motor (skeletal muscle) ▪ Autonomic Motor (internal organs): includes Parasympathetic (rest/ digest), Sympathetic ( ght/ ight), Enteric (gastrointestinal system) ◦ Anatomical Divisions: ▪ Cranial Nerves (12 pairs, Roman numerals) ▪ Spinal Nerves (31 pairs, named by vertebral region) 2. White and Gray Matter Organization: ◦ Brain: ▪ Gray Matter: Outer layers (cerebral and cerebellar cortex) and inner areas (basal nuclei, thalamus) ▪ White Matter: Myelinated axons forming tracts (association, projection, commissures) ▪ Primary Motor Cortex: Controls body movement; located in the frontal lobe. ▪ Somatosensory Cortex: Receives sensory input; located posterior to the motor cortex. ▪ Both cortices feature body maps (homunculi) for sensory and motor functions. 3. Spinal Cord White and Gray Matter: ◦ Gray Matter: ▪ Dorsal horns (sensory nuclei) ▪ Ventral horns (motor nuclei) ▪ Lateral horns (visceral motor, only in thoracic and lumbar regions) ◦ White Matter: Axon columns (anterior, posterior, lateral) forming tracts for sensory and motor communication. 4. Spinal Re exes: ◦ Patellar Re ex: Involves stretch receptors in muscle spindles, afferent neuron activation, and motor neuron response. ◦ Withdrawal Re ex: Activated by pain, involves ipsilateral (same side) contraction of exor muscles and inhibition of extensor muscles. ◦ Crossed-Extensor Re ex: Opposite-side response to maintain balance during withdrawal re ex. Learning Objectives: fl fl fl fl fl fi fl fl 1. Divisions of the Motor Nervous System: ◦ Autonomic Nervous System (ANS): ▪ Controls viscera (smooth muscle, cardiac muscle, glands). ▪ Comprises two main divisions: ▪ Parasympathetic Nervous System (PNS): "Rest and Digest" (decreases cardiac output, stores energy). ▪ Sympathetic Nervous System (SNS): "Fight or Flight" (increases cardiac output, mobilizes energy). ◦ Both divisions are continuously active to maintain homeostasis. 2. Neural Pathways: ◦ The ANS uses a two-neuron chain: ▪ Preganglionic neuron (cell bodies in the CNS). ▪ Postganglionic neuron (cell bodies in peripheral ganglia). ◦ The PNS has long preganglionic and short postganglionic neurons. ◦ The SNS has short preganglionic and long postganglionic neurons. 3. Adrenergic and Cholinergic Receptors: ◦ Adrenergic Receptors: Bind norepinephrine/epinephrine (Alpha and Beta subtypes). ◦ Cholinergic Receptors: Bind acetylcholine (Nicotinic and Muscarinic subtypes). ◦ Nicotinic receptors are ion channels (ionotropic), while muscarinic and adrenergic receptors use second messenger systems (metabotropic, GPCRs). 4. Sympathetic vs. Parasympathetic Neurotransmitters: ◦ Parasympathetic: ▪ Preganglionic and postganglionic neurons both release acetylcholine (ACh). ▪ Nicotinic receptors (preganglionic), muscarinic receptors (postganglionic). ◦ Sympathetic: ▪ Preganglionic neurons release ACh (nicotinic receptors). ▪ Postganglionic neurons release norepinephrine (adrenergic receptors). 5. Adrenal Medulla's Role in Sympathetic Response: ◦ The adrenal medulla releases epinephrine (EPI) into the bloodstream in response to sympathetic activation, amplifying the body's ght or ight response. 6. Neurotransmitter Removal: ◦ Acetylcholine: Broken down by acetylcholinesterase in the synaptic cleft. ◦ Norepinephrine: Reuptake by presynaptic neurons and enzymatic breakdown by monoamine oxidase (MAO) and catechol-O-methyl transferase (COMT) in the liver Learning Objectives: 1. Microanatomy of the Skin: fi fl ◦ Epidermis (outer layer): Avascular, strati ed squamous epithelium with 4-5 layers. ▪ Layers of the Epidermis: 1. Stratum Basale: Deepest layer, contains stem cells, melanocytes, and Merkel cells. 2. Stratum Spinosum: Contains keratinocytes, Langerhans cells (immune function). 3. Stratum Granulosum: Cells accumulate keratin and glycolipids. 4. Stratum Lucidum: Found only in thick skin (e.g., palms, soles). 5. Stratum Corneum: Outermost layer, dead keratinocytes forming a protective barrier. ◦ Dermis: Below the epidermis, contains blood vessels and sensory receptors. ▪ Papillary Layer: Loose areolar tissue with Meissner’s corpuscles. ▪ Reticular Layer: Dense connective tissue, contains mechanoreceptors and thermoreceptors. ◦ Hypodermis (subcutaneous layer): Contains adipose tissue, anchors skin to muscle. 2. Functions of the Integumentary System: ◦ Protection, temperature regulation, vitamin D synthesis, waste excretion, sensation, and immune defense. 3. Appendages of the Skin: ◦ Sweat Glands: ▪ Eccrine (merocrine) glands: Widely distributed, release watery secretion for thermoregulation. ▪ Apocrine glands: Located in axillary and genital regions, secrete lipid- rich uid. ◦ Sebaceous Glands: Secrete oily sebum, provide lubrication and waterproo ng. ◦ Hair/Hair Follicles: Dead keratinized cells. Growth regulated by hormones (e.g., androgens). ◦ Nails: Keratinized cells; function for protection and as tools. 4. Skin Pigmentation: ◦ Melanin: Produced by melanocytes, provides UV protection. ◦ Carotene: Yellow-orange pigment. ◦ Hemoglobin: Oxygenated (red) or deoxygenated (purple/blue) pigment in blood. 5. Skin Conditions and Cancers: ◦ Skin color changes: erythema, cyanosis, jaundice, pallor, bronzing. ◦ Skin cancers: ▪ Basal Cell Carcinoma: Most common and least lethal. ▪ Squamous Cell Carcinoma: More aggressive. ▪ Malignant Melanoma: Most aggressive, early detection is key (ABCDE rule). 6. Thermoregulation: fl fi fi ◦ Sympathetic nervous system regulates blood ow and sweat gland activity. ◦ Vasodilation/vasoconstriction of blood vessels and increased eccrine sweat gland activity help regulate body temperature Learning Objectives: Function of Bone: 1. Support, Movement & Protection: ◦ Provides body shape, supports weight, and protects organs like the lungs. ◦ Facilitates movement. 2. Metabolic Functions: ◦ Hematopoiesis: Blood cell formation in red bone marrow. ◦ Storage: Calcium salts and lipids (yellow bone marrow). Bone Tissue (Osseous Tissue): Components: ◦ Mineral Salts (2/3): Hydroxyapatite, mainly calcium phosphate, gives hardness and resistance to compression. ◦ Collagen Fibers (1/3): Provides strength and exibility. Bone Cells: ◦ Osteoprogenitor Cells: Stem cells that produce osteoblasts. ◦ Osteoblasts: Cells that build the bone matrix (ECM). ◦ Osteoclasts: Cells that break down bone matrix. ◦ Osteocytes: Mature bone cells in lacunae, maintaining bone tissue. Types of Bone: 1. Compact Bone (Cortical Bone): ◦ Dense, located beneath the periosteum, and provides strength and protection. ◦ Contains osteons (Haversian systems), with lamellae surrounding Haversian canals. 2. Spongy Bone (Cancellous Bone): ◦ Less dense and more porous, found inside bones, housing bone marrow and blood vessels. Microanatomy of Bones: Compact Bone: Organized into osteons with lamellae and Haversian canals. Spongy Bone: Trabeculae with osteocytes in lamellae, and bone marrow in spaces. Bone Marrow: fl fl Red Marrow: Involved in blood cell synthesis, found in spongy bone. Yellow Marrow: Stores lipids, found in the cavity of long bones in adults. Bone Growth and Development: Periosteum: Outer layer covering compact bone, containing osteoprogenitor cells. Endosteum: Lines the trabeculae and Haversian canals, also containing bone cells. Structure of Long Bones: Diaphysis: The shaft, consisting of compact bone surrounding the medullary cavity. Epiphysis: Ends of the bone with spongy bone inside and compact bone outside, covered by articular cartilage. Learning Objective Key De nitions: Appositional Growth: Growth from the outside (increases width). Interstitial Growth: Growth from the inside (increases length). Longitudinal Growth: Length increase in bones. Bone Resorption: Breakdown of bone. Bone Deposition: Formation of bone. Ossi cation: Formation of bone tissue. Bone Remodeling: Reorganization of existing bone. Bone Modeling: Formation of the bony skeleton during embryonic development. Learning Objective 1: Bone Modeling and Ossi cation Bone Modeling: ◦ Occurs during embryonic development starting in Week 8. ◦ Hyaline cartilage model forms the skeleton before bones develop. Endochondral Ossi cation: ◦ Formation of bone from a hyaline cartilage model. ◦ Occurs in bones below the skull (except the clavicles). ◦ Involves primary ossi cation in the diaphysis (midsection) during fetal development, followed by secondary ossi cation in the epiphysis (ends of the bone) from birth through puberty. Intramembranous Ossi cation: ◦ Formation of bones directly from brous membranes, especially in the skull and clavicles. ◦ Begins around 8 weeks of gestation and completes by about 2 years of life. Learning Objective 2: Growth at Epiphyseal Plate fi fi fi fi fi fi fi fi Elongation at Growth Plate (Interstitial Growth): ◦ Resting Zone: Non-proliferative chondroblasts. ◦ Zone of Proliferation: Mitosis of chondroblasts. ◦ Zone of Hypertrophy: Chondrocytes enlarge, and the matrix expands. ◦ Zone of Calci cation: Matrix calci es, and chondrocytes die. Growth in Width (Appositional Growth): ◦ Osteoblasts deposit new bone at the periosteum. ◦ Osteoclasts resorb bone at the endosteum. Learning Objective 3: Bone Remodeling and Regulation Bone Remodeling: ◦ Continuous replacement of old bone with new bone. ◦ Spongy bone is replaced every 3-4 years, while compact bone is replaced every 10 years. ◦ Involves osteoblasts (bone deposition) and osteoclasts (bone resorption). Regulation of Remodeling: ◦ Mechanical Forces: Bone responds to stress (Wolf’s Law: bone grows in response to demand). ◦ Calcium Homeostasis: Controlled by Parathyroid Hormone (PTH), which increases calcium resorption from bones when blood calcium levels are low. Factors In uencing Bone Growth: Vitamins: ◦ Vitamin C: Required for collagen synthesis. ◦ Vitamin D: Aids calcium absorption. Hormones: ◦ Growth Hormone: Stimulates bone growth. ◦ Thyroid Hormones: Promote osteoblast and chondrocyte activity. ◦ Sex Hormones: Stimulate bone growth and closure of the growth plates during puberty. Fractures and Repair: Types of Fractures: Closed (internal), open (through the skin), transverse, spiral, etc. Fracture Repair: 1. Hematoma Formation: Blood clot at the fracture site. 2. Soft Callus Formation: Formation of a cartilaginous callus. 3. Hard Callus Formation: Osteoblasts replace cartilage with bone. 4. Bone Remodeling: Replacement of woven bone with mature, organized bone. fl fi fi