Term
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Definition
| Biomechanics is defined as the application of the laws of mechanics to animate motion. This can be broken up into mechanics (kinetics and kinematics) as well as anatomy. |
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Term
| How is movement referenced? |
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Definition
Movement is generally referenced from the anatomical position in a plane and about an axis.
There are 3 cardinal planes and 3 cardinal axes |
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Term
| Define the 3 planes in terms of how they are split up |
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Definition
1. Sagital plane splits the body into left and right
2. The transverse plane splits the body into up and down
3. The frontal plane splits the body into front and back |
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Term
| How many fundamental movements are possible in each plane and how are they determined? What do fundamental movements relate in a plane? in a joint? |
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Definition
There are two fundamental movements of a segment possible in each plane. This is determined by the distal segment orientation in relation to joint position.
Fundamental movements of a segment relate the segment motion only to rotation about an axis in a plane. Fundamental movements of a joint relate the rotation of one segment to the rotation of another. |
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Term
| Describe the 4 things loads can do |
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Definition
1. Stretch: 2 forces pull or 1 is anchored and the other pulls
2. Compress: 2 pressing or 1 anchored and 1 with a force
3. Shear: like pushing skin; 1 side can be anchored
4. Bend: 1 side is stretched and 1 side is compressed, like pushing on a finger |
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Term
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Definition
| σ = F/A. Force is measured in newtons |
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Term
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Definition
Ɛ = ΔL/L. It is usually given as a percent so there is no units |
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Term
| Define Modulus of Elasticity |
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Definition
| E = σ /Ɛ (stress divided by strain) |
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Term
| On a stress/strain graph, what does the slope indicate? |
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Definition
| A steeper slope means less deformation and a stiffer material |
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Term
| What are the two things you can determine from a stress/strain graph? |
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Definition
1. What type of material it is
2. The modulus of elasticity |
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Term
| What is the failure point? |
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Definition
| The failure point is the point at which the material breaks |
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Term
| What is the elastic Region? |
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Definition
| The elastic region is the limit it will reach when it can return back to original after |
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Term
| What is the elastic limit? |
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Definition
| The elastic limit is the yield point |
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Term
| What is the plastic region? |
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Definition
| The plastic region does not return to original length when released which results in residual strain |
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Term
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Definition
| The ultimate stress is the peak stress a material can withstand |
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Term
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Definition
| UO is the strain stored per unti volume of material (in elastic region) |
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Term
| Describe the principle of oscillating loading and unloading |
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Definition
| Oscillating loading and unloading occur in phase. When deformed, material stores strain energy. Strain energy is returned completely during unloading |
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Term
| Define Visco-elastic materials |
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Definition
| Viscoelastic materals show time-dependent properties. The magnitude of stress developed depends on the strain rate. Energy is dissipated within the material when it's stressed. Stress and Strain vary out of phase so that loading and unloading curves do not overlap. |
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Term
| What does the area below the stress/strain curve represent? |
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Definition
| The area below the curve represents the strain energy stored during loading; it is the energy dissipated due to viscous flow within the material |
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Term
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Definition
| The difference between the loading and unloading curves |
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Term
| What is the total energy equal to? |
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Definition
| Total Energy = hysteresis + energy recovered |
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Term
| What determines viscoelastic behavior? |
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Definition
| Viscoelastic behavior must have a time dependent property. A constant load leads to strain change while a constant deformation leads to stress change |
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Term
| What happens in the toe region? |
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Definition
| In thetoe region there is an uncrimping of collagen fibrils and a low stiffness area |
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Term
| What happens in the linear region? |
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Definition
| The majority of fibrils uncrimp, there's actual collagen strain, and stiffness increases |
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Term
| What happens in the yield region? |
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Definition
| In the yield region, collagen begins to fail |
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Term
| What are the problems with In-Vitro Testing? |
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Definition
1. determining the cross sectional area of a specimen
2. Clamping specimen to testing hardware
3. Determining the load rate
4. Properly pre-conditioning the specimen
5. Reducing the in-vivo environment as far as temperature, hydration, innervations, and kinematics/kinetics are concerned. |
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Term
| What is the function of the skeleton? |
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Definition
1. protect internal organs
2. allow for locomotion
3. provide stability
4. Site for RBC production |
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Term
| What are the two divisions of the skeleton? How many bones are in each? |
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Definition
The axial skeleton has 80 bones
The appendicular skeleton has 126 |
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Term
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Definition
| Cortical bone is a hard stabilizing structure, protective covering, and contains nutrient pathways |
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Term
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Definition
| Trabecular bones are inside the cortical bone. It is porous and cancellous bone that contains trabeculae (metabollic processes). This is where osteoporosis happens |
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Term
| What do both trabecular and cortical bones have in common? |
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Definition
| Both types of bone are arranged to try and resist bending. Long bones are most resistant to compression |
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Term
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Definition
| Osteons are the basic unit of a bone. They are lined upward to resist compression. |
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Term
| What is Wolff's Law of Adaptation |
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Definition
| Stress has different effects on bones, has an effect on growth, modeling, and remodeling. Growth of a bone is influenced by heredity. The type of loading influences bone formation and/or remodeling which is why dynamic loading is better than static |
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Term
| Describe the properties of Bone |
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Definition
| Bone is a non-homogenous and anisotropic material. The mechanic properties changed as a function of the location of the applied force. Stiffness in tension is maximal for axial forces and minimal for perpendicular forces. Stiffness for axial forces is roughly 2x the magnitude for perpendicular forces. Bone stress/strain capacity is related to osteon stress/strain |
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Term
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Definition
| in both compression and tension, strain mode provide stimuli for bone formation |
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Term
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Definition
| Osteons are oriented in principal loading direction (compression) |
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Term
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Definition
| Bone formation occurs as a result of intermittent loads. Dynamic is better than static. |
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Term
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Definition
| Repetitive bone strain promotes net bone formation |
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Term
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Definition
| Strain stimulus is required to effect net bone formation and depends on the pattern of loading. Necessary strain stimulus is lowe for unusual patterns of loading (running = usual) |
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Term
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Definition
| The product of stress and strain |
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Term
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Definition
| Bone fracture may be caused by excessive stress due to external force being excessive, small dimensions of bone, geometry of external force is unfavorable, or excessive frequency of load application |
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Term
| What are the functions of connective tissue? |
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Definition
| Connective tissue helps maintain or transmit forces by providing various amounts of strength and elasticity, binds together the cells of the body in various tissue, supports the organs holding them in place, provides stability and shock absorption in joints, provides flexible links between bones in certain types of joints, and transmits muscle force |
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Term
| Describe the make up of connective tissue |
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Definition
| A connective tissue has relatively few cells (fibroblasts) distributed within a large amount of non-cellular material called a matrix. Each type of connective tissue has a different composition of matrix depending on the function of the connective tissue. They are classified according to their function into ordinary and special connective tissue. |
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Term
| Ordinary Connective Tissue |
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Definition
| Ordinary connective tissue binds together the cells of the body in various tissue and provides a mechanical link between bones and between muscles and bone. |
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Term
| Special Connective Tissue |
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Definition
| Special connective tissues include bone and cartilage |
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Term
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Definition
| Elastin fibers are proteins. The molecules are randomly randomly arranged in terms of shape, orientation, and attachment to each other. When elastin undergoes tension, the molecules straighten and then stretch. It can be stretched by 200% of its original length |
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Term
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Definition
| Collagen fibers are proteins. They're regulary running in the same overall direction and are aligned parallel to each other. When subjected to tension in the direction of their orientation, the fibers straighten then stretch. Amount of extension is relatively small. They break after being stretched by 10% |
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Term
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Definition
| The ground substance forms the non-fibrous part of the matrix. Its a viscous gel consisting of large carb molecules suspending in a large amount of water. Water determines the viscosity of ground substance. The only purpose is to provide mechanical support |
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Term
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Definition
| The matrix of cartilage consists mainly of collagen and elastin fibers embedded in ground substace which is highly specialized consisting of large carb-protein molecules (proteoglycans) suspended in water which is the chief constituent of cartilage. It's stronger than any of the materials that make up cartilage |
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Term
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Definition
| Hyaline cartilage is the most abundant and comprises articular cartilage in synovial joints. Poor Recovery. |
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Term
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Definition
| has a very dense network of collagen fibers arranged parallel to each other in several layers, strong material with little elasticity, found in certain joints to improve congruity |
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Term
| What does microfracture regenerate? |
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Definition
| Microfracture regenerates fibrocartilage, not hyaline cartilage |
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Term
| Describe elastin cartilage |
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Definition
| dominated by elastin fibers and thus has a moderate to high degree of elasticity. This is the least abundant and is found in the larynx, inner ear, and eustachian |
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Term
| What is the purpose of Articular Cartilage? |
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Definition
| Articular cartilage transfers forces between articulating surfaces, distributing forces in joints, allows relative movement between surfaces with minimal friction. It is a thin layer of fibrous connective tissue and consists of celss (5%) and intracellular matrix (95%) which is mostly water. |
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Term
| Impulse Momentum Relationship |
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Definition
| Distribute forces over a long period of time is better than direct force over short time |
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Term
| Describe the cells of articular cartilage |
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Definition
| The cells in articular cartilage are called chondrocytes which are metabollically active |
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Term
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Definition
| The matrix consisting of structural macromolecules and tissue fluid - tissue fluid (60-80%) and structural macromolecules (20-40%). Structural macromolecules are collagen, proteoglycans (which resist compression) and other proteins. The tissue fluid is mosely water found in form of a viscous gel. Most of fluid is free to move in and out of cartilage, closely associated with synovial fluid. In cartilage, fluid closely associated with proteoglycans, pores of cartilage are small inhibiting any rapid escape of fluid when cartilage is compressed. Low permeability enables cartilage to maintain its stiffness under compression. Articular acrtilage is structurally heterogenous and changes with depth from the joint surface. |
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Term
| What are the zones of articular cartilage? |
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Definition
1. Superficial: made of 2 layers (surface and deeper). The surface layer has flat bundles of collagen fibers which are crimped. The deep layer has dense collagen fibers lying parallel to the joint surface. The superficial zone contains a high percentage of water.
2. Transitional: Contains large diamete collagen fiberrs that lie parallel tothe joint surface, but less parallel than in the superficial zone
3. The deep zone: large number of large collagen bundles running perpendicular to the joint surface. There is a high proteoglycan content and low water content
4. Calcified: marks the transition from cartilage to stiffer subchondral bone. The collagen fibers from deep zone anchor the cartilage to the bone by fixing themselves into the subchondral bone |
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Term
| What accounts for much of the structure of cartilage? What purpose does it serve? |
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Definition
| Collagen accounts for much of the structure of cartilage to give it its tensile stiffness and strength since it offers little resistance to compression |
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Term
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Definition
| Proteoglycans are glycoproteins which are present in connective tissue and are resistant to compressive forces |
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Term
| Describe tensile properties |
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Definition
| Tensile properties vary from one structural zone to another due to the differen in orientation of collagen fibers. The tensile properties are highly anisotropic. Tensile modulus decreases with increasing depth due to the orientation of collagen fibers. |
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Term
| Describe Compressive Properties |
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Definition
| Vary with zone tested and is related to proteoglycan concentration. Proteoglycan content is greatest in deeper zone which means greatest compressive stiffness |
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Term
| Describe Shear properties |
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Definition
| They are not yet measued with respect to the depth of tissue. Interactions of solid components of the matrix are responsible which may put collagen fibrils under tension |
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Term
| What happens to cartilage when it is subjected to a load? |
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Definition
| Water is forced out. Proteoglycans restore original level of owater when load is removed. The ability to deform and restore is called viscoelasticity. |
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Term
| What is the function of tendons? |
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Definition
Tendons attach muscle to bone and transmits tensile loads from muscle to bone
A tendon transmits force from the associated muscle to the bone. It connects to the muscle at the myotendinous junction. Tendons are surrounded by a loose connective tissue that forms a sheath that protects the tendon during gliding. |
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Term
| What are the functions of ligaments? |
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Definition
| Ligaments transmit forces for extreme ROM, connect bone to bone, augments the mechanical stability of joints, guides motion of joints, and prevents excessive joint motion |
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Term
| What do tendons and ligaments have in common? |
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Definition
Both tendons and ligaments are dense connective tissue referred to as parallel-fibered collagenous tissue. They are sparsely vascularized which makes it difficult to repair and regenerate. They are compose largely of collagen and function best in tension. The great mechanical stability of collagen gives tendons and ligaments their strength and flexibility. They both consist of relatively few cells called fibroblasts (20%) and an extra-cellular matrix (80%). Although they are made of the same material, they are built differently. |
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Term
| In what ways to tendons attach muscle to bone? |
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Definition
| 1. Directly into the bone, 2. Via a tendon, and 3. Via an aponeurosis (an extended tendon that fans out) |
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Term
| Describe the 4 zones of insertion into bone |
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Definition
· Zone 1- at the end of the tendon
· Zone 2 – The collagen fibers intermesh with fibro-cartilage
· Zone 3 – Fibro-cartilage becomes mineralized fibro-cartilage
· Zone 4 – Mineralized fibrocartilage merges into cortical bone |
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Term
| Explain the similarities and differences in tendonds and ligaments? |
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Definition
Both tendons and ligaments are viscoelastic structures. Tendons are strong to sustain high tensile forces resulting from muscle contraction. Tendons are flexible enough to angulate around bony surfaces to change direction of muscle pull. Ligaments are pliable and flexible allowing natural movements of bones. Ligaments are sufficiently strong and inextensible to offer resistance to applied forces. They both sustain predominantly tensile loads. |
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Term
| Explain the safety factor and the limits of tendons and ligaments |
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Definition
Under normal conditions in vivo, tendons and ligaments are stressed only to about 1/3 of Pmax which is the safety factor. The upper limit for physiological strain in tendons and ligaments is from 2 to 5% (during running and jumping). Experiments in sheep suggest that, during normal activity, a tendon in vivo is subjected to less than ¼ of its ultimate stress. |
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Term
| What are the injury mechanisms for tendons and ligaments? |
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Definition
Injury mechanisms for tendons and ligaments are similar. When a ligament is subjected to loading that exceeds the physiological range, micro failure takes place even before the yield point. When Plim is exceeded, the ligament begins to undergo gross failure and the joint begins to displace abnormally. |
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Term
| What are the categories of ligament injury? |
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Definition
Category 1 of ligament injuries – produce negligible clinical symptoms but some pain and no joint instability
Category 2 – produce severe pain, some joint instability; progressive failure of collagen fibers; strength and stiffness decreases by 50%
Category 3 – severe pain during trauma but less afterward; joint completely unstable; most collagen fibers are ruptured |
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Term
| How does aging and immobilization affect cartilage? |
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Definition
Aging causes physical properties of collagen closely associated with number and quality of cross-links. During maturation, number and quality of cross-links increases thus increasing tensile strength. As aging progresses, collagen reaches a plateau to strength and stiffness eventually decreasing
Immobilization causes tissues to remodel in response to mechanical demands. Physical training increases tensile strength in tendons and ligament-bone interface. |
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Term
| How do NSAIDs affect tendons? |
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Definition
Nonsteroidal and anti-inflammatory drugs are frequently used in the treatment of musculoskeletal conditions. It’s used in treatment of soft-tissue inflammatory disorders. Studies have shown that treatment with these drugs (indomethacin) increased tensile strength of tendon (i.e. increase total collagen content). Short-term administration of these drugs would not hurt tendon healing and would increase the rate of biomechanical restoration of the tissue. As strength increases, the tendons become stiffer. |
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Term
| What are the two types of joints? |
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Definition
In terms of structure, there are two types of joints. Joints in which the articular surfaces of the bones are united by fibrous tissue or cartilage are fibrous or cartilaginous joints. Joints in which the articular surfaces are not attached to each other but are held in contact by a sleeve of fibrous tissue supported by ligaments are called synovial joints. |
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Term
| What are the types of fibrous joints? |
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Definition
Fibrous joints are called syndesmosis joints. The degree of movement is determined by the amount of fibrous tissue between the articular surfaces. In general, the smaller the amount of fibrous tissue the more limited the movement. Two types of fibrous joints are membraneous and sutural |
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Term
| What are two types of cartilagenous joints? |
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Definition
There are two types of cartilaginous joints: synchondroses, symphyses. |
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Term
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Definition
Each articular surface is covered by hyaline cartilage. Hyaline cartilage enhances cartilage because there is a small coefficient of friction (.0025). |
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Term
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Definition
The type of movement in a joint depends on the type of the joint and the shape of the articular surfaces. Degrees of freedom – with respect to the joint axes, there are 6 degrees of freedom. The 6 DOF are: 3 linear directions (along each axis) and 3 rotations (about each axes). Not all synovial joints have all six DOF. In multi-joint movements, the DOF in the segmental chain is the sum of the DOF in all joints. |
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Term
| Joint Flexibility and Stability |
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Definition
Joint stability refers to the strength of the bond between the bones. The stronger the bone, the more stable the joint. Joint flexibility refers to the degree of movement in the joint. In general, the greater stability of the joint, the lower flexibility of the joint. |
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Term
| Describe the different DOFs for different joints |
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Definition
The condyloid joint allows movement in two directions. The saddle joint allows flex/ext, ab/adduction and circumduction. Rotation joint allows a rotation about the longitudinal axis of bone. The hinge joint allows only one movement, flex/ext. Gliding joint allows short gliding movements in many directions not around any specific axis. Ball and socket joint allows movement about an indefinite number of axes. Allow flex/ext, ab/ad, circumduction, and int/ext rotation. |
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Term
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Definition
Skeletal muscle attaches to the skeleton and causes movement. This type of muscle is the most abundant tissue in the human body (accounting for 40-45% of total body weight). There are 430 skeletal muscles found in pairs on the right and left sides of the body. The most vigorous movements are produced by fewer than 80 pairs. |
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Term
| What is the purpose of muscles? |
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Definition
| Muscles act to produce movement, maintain posture, stabilize joints, and support and protect organs. |
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Term
| Describe the structural unit of the skeletal muscles |
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Definition
The structural unit of skeletal muscle is the fiber which are long cylindrical cells with many nuclei. Fibers range in thickness from 10 to 100 um and in length from about 1 to 30cm. Each fiber is covered by loose connective tissue called endomysium. Fibers are organized into various size bundles called fascicles which are covered by the perimysium. Surrounding the whole muscle is fascia called the epimysium. |
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Term
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Definition
Each muscle fiber is composed of myofibrils (the contracting element of the muscle). The myofibrils lie parallel to each other within the sarcoplasm of the muscle fiber. Myofibrils vary in number depending on the diameter of the fiber. |
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Term
| Theory of Muscle Contraction |
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Definition
The theory of muscle contraction that is most widely held is the sliding filament theory which says the actin and myosin slide towards the center. There is an active shortening of the sarcomere which results from the relative movement of the acting and myosin filaments past on another (each filament retains its original length). The force of contraction is developed by the myosin heads (or cross-bridges) in the region of overlap (A band). This movement of the cross-bridges in contact with the actin filaments produces a sliding of the actin towards the center of the sarcomere. |
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Term
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Definition
An electrical impulse causes an action potential which releases ACH and opens up a gate. Sodium (+) rushes in and Potassium (-) rushes out which depolarizes this. This triggers sarcomere to release Ca+ which floods the actin and myosin. These bind to troponin and pulls it off the actin. |
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Term
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Definition
· There are 5 different shapes of parallel fiber arrangements: flat, fusiform, strap, radiate, and convergent
o The fiber force in a parallel muscle fiber arrangement is in the same direction as the musculature which results in a greater range of shortening and greater movement velocity. |
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Term
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Definition
· In a pennate arrangement, the fibers run diagonally with respect to a central tendon running the length of the muscle. The general shape of a pennate muscle is feather-like with fascicles being short and at an angle to the length of the muscle. The force generate by each fiber is in a different direction than the muscle force. The fibers are shorts and the change in individual fiber length is not equal to the change in muscle length. Pennate muscles have a large cross sectional area and generate more strength than parallel muscle fibers.
· There are three types of pennate muscles: unipennate, bipennate, multipennate. |
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Term
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Definition
· Type 1 slow twitch fibers – slow contraction times for prolonged, low intensity work
· type IIa fast twitch oxidative glycolytic – can sustain activity for long periods of contract with a burst of activity and then fatigue
· type IIb fast twitch glycolytic – generate rapid force production and then fatigue quickly. |
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Term
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Definition
The motor unit is the functional unit of a skeletal muscle. A motor unit includes a single motor neuron and all of the fibers innervated by it (this is the smallest part of the muscle that can be made to contract independently). When stimulated, all muscle fibers in a motor unit respond as one (i.e. all-or-none response). The number of muscle fibers forming a motor unit closely related to the degree of control required of the muscle. In small muscles that perform fine movement, the motor unit may contain less than a dozen muscle fibers. In large muscles that perform coarse movements, the motor unit may contain from 1000 to 2000 muscle fibers. |
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Term
| Three Types of Contraction |
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Definition
- In a concentric contraction muscles develop sufficient tension to overcome the resistance (muscle shortens while developing tension). In eccentric contraction muscles cannot develop sufficient tension to overcome the resistance (muscle lengthens while developing tension). In isometric contraction muscles develop sufficient tension to balance the resistance (muscle length stays the same while developing tension).
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Term
| Length Tension Relationship in muscles |
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Definition
Length-tension relationship states that the force that a muscle can generate varies with the length at which it is held when stimulated. If the relationship is measured in a whole muscle, the tension produced by both active and passive components must be considered. |
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Term
| Force Time relationship in muscles |
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Definition
In the force time relationship, the force generated by a muscle is proportional to the contraction time. The longer the contraction time, the greater the force developed up to the point of maximum tension. |
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Term
| Increasing the Temp for Muscles |
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Definition
Increasing the temperature increases the conduction velocity across the sarcolemma thus increasing the frequency of stimulation and the muscle force. Increasing the temp also causes greater activity of muscle metabolism thus increasing the efficiency of contraction. Muscle performs more work when it shortens immediately after being stretched from a concentrically contracted state. This may be a result of the elastic energy stored during stretching and also due to energy stored in the contractile tissue. |
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