Musculoskeletal System for the DAT PDF
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This document provides information on the musculoskeletal system, suitable for students preparing for the DAT exam. It details the structure and function of skeletal, smooth, and cardiac muscles. The document also addresses related topics such as bone structure and maintenance, and introduces different types of glands.
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Musculoskeletal System for the DAT shemmassianconsulting.com/premium/dat-content-guides/musculoskeletal-system-dat May 8, 2024 Part 1: Introduction to the musculoskeletal system Understanding the musculoskelet...
Musculoskeletal System for the DAT shemmassianconsulting.com/premium/dat-content-guides/musculoskeletal-system-dat May 8, 2024 Part 1: Introduction to the musculoskeletal system Understanding the musculoskeletal system is pivotal as it both sustains the body and enables movement. A comprehensive grasp of its structure and the typical mechanisms of muscle contraction is essential. This guide will teach you all you need to know for the DAT. In order to retain content, make note of any bolded terms. Want expert guidance on dental school admissions? Enter your name and email for high-yield admissions strategies we use to get students into programs like Harvard, UCSF, and NYU 100% privacy. No spam. Ever. ---- Part 2: Types of muscle The body houses diverse muscle types, each with distinct characteristics and functions. We'll explore three main types: skeletal, cardiac, and smooth muscle. Skeletal muscle drives voluntary movement, controlled consciously by the somatic nervous system. Identified by their striated appearance and multiple nuclei, these muscles contain two fiber types—slow-twitch (type I) and fast-twitch (type II). These fiber types differ in their contractile velocity, or how quick they can contract to produce movement. Slow-twitch fibers, rich in myoglobin and mitochondria, contract slowly but resist fatigue. Conversely, fast-twitch fibers contract rapidly but fatigue quickly due to lower myoglobin levels. Fatigue in skeletal muscles arises from oxygen debt, a mismatch between oxygen required for ATP energy production and available oxygen through breathing. Skeletal muscle contractions facilitate fluid movement, aiding blood and lymph circulation by 'squeezing' surrounding vessels. The fundamental unit of skeletal muscle, the sarcomere, comprises thick (myosin) and thin (actin) protein filaments. These thick and thin filaments interweave with each other in what is called the contractile apparatus. Troponin and tropomyosin assist actin and myosin in 1/19 muscle contraction. Sarcoplasmic reticulum, housing Ca²⁺ ions, plays a crucial role in this process. FIGURE 1: LABELED SARCOMERE Smooth muscle—regulated by the autonomic nervous system—operates involuntarily and lines essential organs like the digestive tract, bladder, uterus, and blood vessels. Smooth muscle facilitates material transport through peristalsis. Unlike skeletal muscle, smooth muscle lacks the organized sarcomeres of myosin and actin fibers. Remarkably, it exhibits myogenic activity, meaning it contracts without nervous system input. This myogenic activity often gives rise to the notion of a "second brain" in the gut. Additionally, smooth muscles lack striations and have a single nucleus at their core. In contrast, cardiac muscle is unique to the heart and shares attributes with both skeletal and smooth muscle. It's striated and comprised of sarcomeres similar to skeletal muscle, yet it functions involuntarily, with each cell housing a single nucleus. The interconnectedness of cardiac muscle cells through intercalated discs, packed with gap junctions, allows rapid ion flow and swift propagation of action potentials. This unique feature promotes synchronized contraction, unlike neuron action potentials that require sequential signal propagation. Cardiac muscle cells also exhibit myogenic activity that governs the heart's rhythm independently of the brain. This rhythmic activity originates from a distinct cluster of specialized cells located at the heart's apex, termed the sinoatrial node (SA node). From here, electrical signals spread across the heart, initiating muscle contractions. Progressing 2/19 through the atrioventricular (AV) node and the Bundle of His, these signals finally disseminate via the Purkinje fibers, situated within the ventricular walls, thereby prompting the contraction of cardiac muscle. FIGURE 2: FLOW OF ELECTRICITY THROUGH THE HEART Skeletal Smooth Cardiac Voluntary Involuntary Involuntary Somatic Automatic Automatic Innervation Innervation Innervation Multinucleated 1 nucleus per cell 1-2 nuclei per cell Appears striated Appears non- Appears striated striated Requires Ca2+ to Requires Ca2+ to Requires Ca2+ to contract contract contract Forceful Continuous Forceful contractions contractions contractions 3/19 Attached to bones Bladder, blood Found only in the throughout the vessel, uterus, heart body intestines TABLE 1: PROPERTIES OF MUSCLE TYPES ---- Part 3: Muscle contraction Muscle fibers house both thin and thick filaments, also known as actin and myosin, which drive skeletal muscle contractions through the actin-myosin crossbridge cycle. Before this cycle begins, a signal from the somatic nervous system travels through motor neurons to the junction between the nerve terminal and the muscle fiber, known as the neuromuscular junction's motor endplate. At this junction, the nervous system's motor neurons interact with muscles through a chemical synapse. Activation of an axon in the somatic nervous system prompts the release of acetylcholine into the synaptic cleft. Acetylcholine binds to the sarcolemma of the receiving muscle cell, initiating ion channel opening, depolarization, and subsequent action potential propagation through T-tubules. These actions facilitate the release of stored Ca²⁺ ions from the sarcoplasmic reticulum. At rest, actin and myosin in muscle cells typically interact with additional large proteins— tropomyosin and troponin. Tropomyosin normally shields the myosin-binding sites on actin in the muscle's noncontractile state. However, the release of Ca2+ from the sarcoplasmic reticulum triggers troponin to bind with it, causing a structural shift in tropomyosin. This alteration exposes the myosin binding site on actin, essentially enabling the formation of the actin-myosin crossbridge. 4/19 FIGURE 3: CA2+ IONS HELP IN INITIATING THE ACTIN-MYOSIN CROSSBRIDGE CYCLE 5/19 FIGURE 4: ACTION POTENTIAL PROPAGATION AT THE NEUROMUSCULAR JUNCTION. (1) ACTION POTENTIAL TRAVELS DOWN AXON AND ACETYLCHOLINE IS RELEASED INTO SYNAPTIC CLEFT. (2) ACETYLCHOLINE BINDS TO SARCOLEMMA, OPENING ION CHANNELS AND PROPAGATING ACTION POTENTIAL THROUGH T-TUBULES. Once exposed, the myosin head undergoes a power stroke. The power stroke is propelled by the release of ADP and inorganic phosphate from ATP, enabling the myosin to pull along the actin filament. Repeated power strokes of multiple myosin heads lead to sarcomere shortening. Post-power stroke, ATP binds to the myosin head, detaching it from actin. Tropomyosin promptly recovers the binding site. ATP hydrolysis enables the myosin head to return to its initial high-energy position, beginning the cycle anew. 6/19 FIGURE 5: ACTIN-MYOSIN CROSSBRIDGE CYCLE. (1) RESTING STATE; MYOSIN HEAD ALREADY COCKED BACK IN HIGH-ENERGY POSITION. (2) CA2+ BINDS TO TROPONIN TO EXPOSE THE BINDING SITE. (3) POWER STROKE; CONTRACTION. ADP + PI DISSOCIATE. (4) NEW ATP BINDS TO MYOSIN. MYOSIN DETACHES FROM ACTIN, CA2+ DETACHES FROM TROPONIN. (5) HYDROLYSIS OF ATP; RESETTING OF MYOSIN HEAD Muscle function is governed by the nervous system, with voluntary movements managed by the somatic nervous system and involuntary movements, such as shivering that assists in thermoregulation, controlled by the autonomic nervous system. The autonomic nervous system orchestrates sympathetic (e.g., dilation of blood vessel smooth muscle and slowed digestive tract) and parasympathetic responses (e.g., opposing effects), regulating innervated muscle behaviors. Looking for an experienced tutor who can help you maximize your DAT score? ---- Part 4: Additional connective elements 7/19 While muscles play a crucial role in our soft tissue, our body's shape and movement leverage rely on additional structural elements, primarily the bones and their connections where muscles attach. The human skeleton, being situated internally, is termed an endoskeleton. This structure differs from external structural elements known as exoskeletons found outside an organism's body. a) Bone structure Contrary to its appearance, bone is a dynamic living tissue, richly vascularized and innervated. Beyond safeguarding soft tissues and facilitating movement, bones serve essential functions like fat and mineral storage, as well as the production of red blood cells. In the skeletal framework, bones come in various forms, each with distinct characteristics and roles: Short bones, for instance, are as wide as they are long, mainly providing structural support. Commonly found in parts of the wrist, their compact nature contributes to stability and mobility within these regions. Flat bones, another category, predominantly function to safeguard vital organs and delicate tissues. For instance, the skull is primarily composed of flat bones, serving as a protective shield for the brain. Sesamoid bones, embedded within tendons, are specialized in aiding muscle function. These bones, such as the kneecap, contribute to efficient muscle-pulling mechanisms and enhance movement and stability. Irregular bones, as the name suggests, display an irregular shape and structure. Examples include the pelvis, showcasing diverse forms to cater to their unique roles within the body's framework. Long bones, such as those in our arms and legs, showcase a fascinating composition. They consist of a dual structure, featuring a dense, compact outer layer called cortical bone and inner pockets of spongy, cancellous bone. Among the defining features of these long bones are the epiphysis, diaphysis, medullary cavity, metaphysis, and the vital epiphyseal plate. The epiphysis, situated at the ends of these long bones, establishes joints with neighboring bones and houses red bone marrow. This bone marrow is a hub for the synthesis of blood cells, particularly hematopoiesis. The diaphysis, on the other hand, is the elongated hollow shaft within the bone and encapsulates the medullary cavity. This cavity is a space containing both red and yellow bone marrow—acting as a storage site for fats. 8/19 The metaphysis is an interesting structural component that is akin to the epiphysis. It is positioned between the medullary cavity and epiphyseal plates, exerting a role in bone growth and development. Speaking of which, the epiphyseal plate, commonly referred to as the "growth plate," is crafted from hyaline cartilage. This specialized structure actively lengthens the diaphysis by facilitating both growth and ossification processes. In a fully developed, mature bone, the epiphyseal plate becomes the epiphyseal line. Delving further into bone microstructures, cortical bone is the sturdy outer layer of long bones. The functional units of cortical bone are osteons, which are multi-layered bone cylinders that are often referred to as Haversian systems. These osteons are meticulously arranged around Haversian canals, crucial 'tubes' that house blood vessels and ensure the nutrient supply essential for bone vitality. Lamellae are concentric layers that make up the osteons. They encompass small spaces known as lacunae that are interconnected through minute channels called canaliculi. It is in these lacunae where bone cells known as osteocytes can be found. Furthermore, Volkmann's canals act as connectors, linking the Haversian canals to the periosteum—the bone's outer layer. Volkmann’s canals serve as a conduit for nutrient distribution. Within the bone's inner layer, known as cancellous bone, a spongy network of trabeculae forms a matrix that efficiently absorbs red bone marrow. This inner layer, distinct from the dense cortical bone, plays a significant role in supporting cancellous bone structure. The intricate design of bone, comprised of these varied structures and functionalities, contributes significantly to the bone's resilience and its role in maintaining overall physiological balance. 9/19 FIGURE 7: A VIEW OF THE SYSTEMS WITHIN BONE MATRIX b) Bone maintenance Bones undergo a constant cycle of breakdown and reconstruction to preserve mineral balance in our bloodstream. Notably, a significant portion of the body’s Ca2+ resides within a mineral called hydroxyapatite in the bone matrix. To uphold the adequate levels of Ca2+ in our blood, specialized cells are tasked with both bone degradation and formation. These cells—osteoclasts and osteoblasts—play crucial roles. Osteoclasts resorb the bone matrix, releasing minerals into the bloodstream, while osteoblasts facilitate bone reformation and growth. (Remember: osteoblasts build, osteoclasts consume.) The actions of osteoblasts and osteoclasts are regulated by peptide hormones: calcitonin and parathyroid hormone (PTH). Calcitonin, released by the thyroid gland, steps in when blood calcium levels are excessively high. It prompts osteoblasts to fortify bones, drawing Ca2+ from the bloodstream and storing it within bones. Conversely, when blood Ca2+ levels dip too low, the parathyroid glands release PTH. This hormone stimulates osteoclasts to consume bone, releasing Ca2+ back into the bloodstream. The thyroid and parathyroid glands work in tandem with the urinary system to maintain the body's calcium balance. 10/19 FIGURE 8: ENDOCRINE REGULATION OF CALCIUM c) Ossification There are two types of embryonic ossification: Intramembranous ossification represents a bone formation method wherein bone tissue originates directly within fibrous membranes, particularly influencing the development of flat bones. This process begins with specialized bone-forming cells called osteoblasts. These cells initiate formation by secreting a substance known as osteoid, which gradually mineralizes to house and embed osteocytes within its structure. Over time, the accumulation and organization of this mineralized matrix leads to the generation of cortical bone. This also contributes to the development and structure of flat bones across the body. Examples of flat bones influenced by this process include those within the skull (like the parietal and frontal bones) and some facial bones. 11/19 Endochondral ossification represents an alternate method of bone formation that occurs indirectly through a pre-existing cartilage model. This method of ossification primarily influences the formation and growth of long bones within the body. The process primarily begins during fetal development, where a cartilage model forms in the shape of the future bone. As the cartilage model matures, it undergoes calcification, a process where calcium salts are deposited, leading to the hardening of the cartilage. The calcified cartilage serves as a foundation for the development of ossification centers, which are specialized regions where bone tissue begins to replace the calcified cartilage. This replacement is orchestrated by osteoblasts, which create new bone tissue. Ultimately, this process helps shape and define the structural features of long bones, such as the humerus, femur, and tibia, among others, as they grow and mature within the body. d) Tendons, ligaments, cartilage, and joints Tendons, ligaments, and cartilage serve as vital connections that act as bridges between bones and muscles. They play crucial roles in the skeletal system's functionality. Tendons, specifically, serve to link muscles to bones. Tendons enable the transmission of muscular force for movement and stabilization. Ligaments, on the other hand, directly connect bone to bone, reinforcing the structural integrity of joints. Both tendons and ligaments predominantly consist of robust, pliable collagen-based fibrous connective tissue. Cartilage, yet another resilient and flexible connective tissue, forms a crucial part of the skeletal system. It comprises a matrix rich in collagen and elastin secreted by chondroblasts, making it avascular and not innervated, unlike bone. Among the various types of cartilage, hyaline cartilage stands out for its prevalence and its significant role in reducing friction while absorbing shock within joints. Hyaline cartilage ensures smooth movement and stability. Notably, in early human development, the skeletal structure primarily relies on cartilage to facilitate the rapid growth of organs like the brain. Over time, this cartilaginous material gradually transforms into hardened bone, contributing to the development of the skeletal framework. Moreover, the joints, essential sites where bones meet and articulate, exhibit their own vascularization and innervation. They come in various types, each with distinct functionalities and degrees of movement. Synarthroses, characterized by dense, fibrous connections, remain fixed without any movement. Amphiarthrosis, on the other hand, are cartilaginous joints that allow limited movement. Finally, diarthroses, often termed synovial joints, offer full mobility and flexibility. They typically feature hyaline cartilage for smooth articulation. Additionally, within the bone structure, membranes such as the periosteum and endosteum play pivotal roles in bone maintenance and support. The periosteum encompasses a vascularized outer fibrous layer and an inner/cambium layer that aids in attachment to cortical bone. The endosteum is situated between cortical and cancellous bone and plays 12/19 pivotal roles in bone maintenance and support. These membranes, along with the varied connective tissues, collectively contribute to the dynamic functionality and structural integrity of the skeletal system. Looking for a trusted advisor to help you get into dental school? ---- Part 5: Skin a) Structure The skin, originating from the ectoderm, stands as the body's largest organ. It is composed of three distinct layers: the epidermis, the dermis, and the hypodermis. The epidermis, or outermost layer, is further divided into five strata or layers housing essential cell types you need to know for the DAT: Keratinocytes: These cells produce keratin, a protective protein guarding against pathogens and injuries. Melanocytes: Responsible for generating melanin pigment, offering defense against UV radiation. Langerhans cells: A type of macrophage assisting in immune system activation. The different strata of the epidermis are summarized below: Layer of epidermis Key features Stratum corneum Contains flattened keratin producing cells, keratinocytes, to protect against pathogens Stratum lucidum Found in hairless skin (e.g., palms) Stratum granulosum Contains dead keratinocytes Stratum spinosum Contains Langerhans cells Contains live keratinocytes 13/19 Stratum basale Site of proliferation for keratinocytes Contains melanocytes Contains stem cells TABLE 2: LAYERS OF THE EPIDERMIS FROM MOST SUPERFICIAL (STRATUM CORNEUM) TO MOST DEEP (STRATUM BASALE) The dermis constitutes a substantial portion of the skin. It is characterized by dense connective tissue and is primarily composed of collagen and elastic fibers. The dermis acts as a supporting framework for various structures and plays a pivotal role in sensory perception and bodily regulation. The dermis is composed of two regions, the papillary region and the reticular region. The papillary region is the upper 20% of the dermis that houses a thin vascular network within upward projections known as papillae. These papillae serve multiple functions, supplying nutrients to the epidermis and assisting in temperature regulation. Meissner’s corpuscles— sensitive touch receptors—reside within these papillae and contribute to tactile sensitivity. Importantly, these structures form the distinctive fingerprint ridges. The reticular region comprises dense connective tissue, collagen, and elastic fibers. This region forms the majority of the dermis and accommodates oil glands, sweat gland ducts, fat, and hair follicles. Its primary roles include providing strength and elasticity to the skin. Notably, dermal tears in this layer result in the formation of stretch marks. Within the dermis, an array of sensory receptors play crucial roles in tactile perception: Tactile Corpuscles (Meissner’s Corpuscles): These sensory receptors are highly responsive to light touch, contributing to tactile sensitivity. Bulbous Corpuscles (Ruffini Endings): Known mechanoreceptors sensitive to skin stretching, providing information about skin elongation. Pacinian Corpuscles: Mechanoreceptors particularly sensitive to vibration and pressure, assisting in perceiving these tactile sensations. In addition to sensory functions, the dermis also serves as a canvas for tattooing, where ink is injected into the dermal layers. During the healing process, macrophages consume the ink particles, and dermal fibroblasts interlock the ink-containing macrophages into a collagen network, embedding them just beneath the dermis-epidermis junction. Finally, the hypodermis—the skin's base layer—serves as connective tissue linking the skin to the body's muscles and bones. Laden with adipose tissue, it stores fat for thermal insulation and shock absorption, thereby providing additional protective functions. 14/19 b) Glands The integumentary system has diverse glands essential for bodily equilibrium. These glands can be categorized as sudoriferous (sweat) or sebaceous. There are two types of sudoriferous glands: eccrine and apocrine. Eccrine Glands: Widely distributed over the body surface, eccrine glands are pivotal in regulating body temperature. These glands secrete a watery substance that aids in cooling the body during elevated temperatures. Apocrine Glands: Located in specific regions like the armpits and groin, apocrine glands discharge their secretions into hair follicles. They produce earwax (ceruminous glands) and milk (mammary glands), contributing to unique bodily functions beyond temperature control. Sebaceous glands are present throughout the body, excluding the palms and soles. These glands produce sebum, a blend of oils and wax that lubricates and moisturizes the skin and hair. Sebum serves as a natural defense against external elements, nurturing the skin's health. Understanding these glands' functions and locations illustrates their crucial roles in maintaining skin health and their diverse contributions to bodily processes in various regions. c) Homeostasis The skin serves a pivotal role in maintaining the body's internal balance. Initially, its impermeability to water aids in preserving the body's osmolarity. Additionally, it houses various structures and mechanisms crucial for regulating body temperature. During shivering, swift muscle contractions convert mechanical energy into thermal energy. Piloerection, commonly known as goosebumps, elevates hair to trap heat within the body's immediate air layer. Furthermore, vasoconstriction—the narrowing of blood vessels— retains heat in chilly conditions. In warmer climates, sweat becomes the body's cooling mechanism. Sweat glands release a mix of water and ions onto the skin that initiates evaporative cooling. Evaporative cooling is a process where heat disperses, effectively lowering the body temperature. This cooling strategy often pairs with vasodilation, widening blood vessels to transfer warmth from the blood to the skin's surface. These processes allow the body to shed heat and cool off. ---- 15/19 Part 7: Questions and answers Question 1: What is the key difference between slow-twitch and fast-twitch muscle fibers in terms of their metabolic activity during contraction? A) Presence of multiple nuclei B) Variations in contractile velocity C) Different myoglobin levels D) Diverse mitochondrial content Question 2: Which muscle type possesses a unique structural characteristic contributing to synchronized contractions, despite being predominantly under involuntary control? A) Skeletal muscle B) Smooth muscle C) Cardiac muscle D) Visceral muscle Question 3: Which cellular component involved in muscle contraction undergoes a conformational change due to the binding of Ca2+ ions, enabling the actin-myosin interaction? A) Troponin B) Tropomyosin C) Sarcolemma D) Actomyosin Question 4: In the bone matrix, where is the greatest portion of the body's calcium stored? A) Haversian canals B) Red bone marrow C) Compact bone D) Hydroxyapatite 16/19 Question 5: Which layer of the skin contains the strata responsible for producing keratin? A) Epidermis B) Dermis C) Hypodermis D) Reticular layer Question 6: Which hormone, released by the parathyroid glands, prompts osteoclasts to resorb bone matrix when blood calcium levels decrease? A) Calcitonin B) Thyroxine C) Parathyroid hormone (PTH) D) Growth hormone Question 7: What is the primary function of tendons within the musculoskeletal system, specifically in relation to bone and muscle connectivity? A) Facilitate joint movement B) Store and release calcium C) Link bone to bone D) Connect muscle to bone Question 8: Which skin layer houses sensory receptors responsive to light touch and skin stretching, aiding in tactile perception? A) Epidermis B) Dermis C) Hypodermis D) Reticular layer Question 9: In muscle contraction, what directly facilitates the detachment of myosin from actin, resetting the myosin head for another power stroke? A) ATP hydrolysis 17/19 B) Calcium influx C) Troponin binding D) Tropomyosin conformation Question 10: What mechanism plays a crucial role in cooling the body during warm conditions, where sweat glands release a mixture onto the skin to initiate heat dispersion? A) Constriction of blood vessels B) Piloerection C) Evaporative cooling D) Vasoconstriction Answer key 1. Answer choice C is correct. Slow-twitch fibers, rich in myoglobin and mitochondria, contract slowly but resist fatigue due to their abundant oxidative capacity and high oxygen supply. Fast-twitch fibers contract rapidly but fatigue quickly due to the lower level of myoglobin. 2. Answer choice C is correct. Cardiac muscle, although involuntary like smooth muscle, shares striated characteristics with skeletal muscle and displays synchronized contractions through intercalated discs. Smooth muscle, on the other hand, is much less organized in its arrangement. 3. Answer choice A is correct. Troponin undergoes a conformational change due to Ca²⁺ binding, leading to the exposure of myosin binding sites on actin. This change allows for the actin-myosin interaction. 4. Answer choice D is correct. The largest portion of the body's calcium is stored in the bone matrix within hydroxyapatite, contributing to the regulation of blood calcium levels. 5. Answer choice A is correct. The strata within the epidermis house keratinocytes responsible for producing keratin, a protective protein against pathogens and injuries. 6. Answer choice C is correct. Parathyroid hormone (PTH), released by the parathyroid glands, stimulates osteoclasts to resorb bone matrix. This resorption releases calcium into the bloodstream when blood calcium levels decrease. 7. Answer choice D is correct. Tendons primarily connect muscles to bones within the musculoskeletal system. Ligaments, on the other hand, connect bone to bone. 18/19 8. Answer choice B is correct. Sensory receptors responsive to light touch and skin stretching are housed within the dermis, aiding in tactile perception. 9. Answer choice A is correct. ATP hydrolysis facilitates the detachment of myosin from actin, resetting the myosin head for another power stroke in muscle contraction. 10. Answer choice C is correct. Evaporative cooling is the process by which sweat glands release a mixture onto the skin, initiating heat dispersion, and helping to cool the body during warm conditions. Looking for comprehensive dental school admissions coaching? Dr. Shemmassian/ 0 Likes Share 19/19