BioMech4 Test 1

Question 1

What is the most common joint in the extremities?

Answer 1

Synovial Joint.

Question 2

What is the biomechanical triad?

Answer 2

muscles, skeleton, joints.

Question 3

What makes up scar tissue and why is it different than regular tissue?

Answer 3

Fibroblasts make up the scar tissue and it is different from regular tissue because they orient themselves according to stress placed on them.

Question 4

What cell will make scar tissue?

Answer 4

Fibroblasts.

Question 5

How will fibroblasts lay scar tissue?

Answer 5

They orient themselves according to stress placed on them.

Question 6

What is the diaphysis?

Answer 6

Diaphysis- shaft or body of the long bone.

Question 7

What is the metaphysis?

Answer 7

Metaphysis- Between diaphysis and the epihyseal plate.

Question 8

What is the epiphyseal plates?

Answer 8

Epipyseal plate- growing lines.

Question 9

What is the epiphysis?

Answer 9

Epiphysis- Top part of the long bone.

Question 10

What is the name for a secondary growth center on a long bone (ie: for tubercles or other muscle/ligament attachments?

Answer 10

Apophysis.

Question 11

Epiphyseal plate is aka?

Answer 11

Physis.

Question 12

What is a closed physis?

Answer 12

Where the epiphyseal plate was but the cartilage is gone and growth has stoped, but a line is still there.

Question 13

Perisoteium is continous with what?

Answer 13

Fibrous capsule.

Question 14

What is the bone called that is deep to the articular cartilage in a synovial joint?

Answer 14

Subchondral bone.

Question 15

What is articular cartilage like in synovial joints?

Answer 15

Blue, slippery caps of adjacent bone ends and lines the bone

Question 16

Where is intra-articular cartilage found at? What type of cartilage is it?

Answer 16

Discs and menisci and it is fibrous cartilage between bones.

Question 17

What inner lining part of the synovial joint that lines the synovial cavity?

Answer 17

Synovial membrane.

Question 18

What is the synovial cavity?

Answer 18

Joint Cavity

Question 19

What does the synovial cavity contain?

Answer 19

Synovial fluid

Question 20

What is synovial fluid?

Answer 20

Viscous fluid in joint cavity

Question 21

What is the periosteum?

Answer 21

Membrane lining outer bone

Question 22

Will synovial joints have a perichondrium?

Answer 22

No.

Question 23

Where is synovial fluid secreted from?

Answer 23

The innermost layer (intima) of the synovial membrane.

Question 24

How much synovial fluid is there in synovial joints?

Answer 24

Just enough to form a film.

Question 25

What is synovial fluid like?

Answer 25

Transparent high viscosity rich in glycosaminoglycans (GAG’s).

Question 26

What is the major GAG in synovial fluid?

Answer 26

Hyaluronic acid.

Question 27

Hyaluronic acid injections are used to treat what in synovial joints?

Answer 27

Osteoarthritis.

Question 28

What are the functions of synovial fluid? (4)

Answer 28

Shock absorber, lubrication, supplies nutrients to cartilage, removes waste from cartilage.

Question 29

How many layers are there for synovial membranes?

Answer 29

two, Intima and sub-intima.

Question 30

What layer of the synovial membrane is closest to the synovial fluid and which layer is closest to the bone?

Answer 30

Intima- closest to the fluid. Sub-intima- closest to the bone.

Question 31

What is the intima like?

Answer 31

Epithelioid layer (like epithelium), but not epithelium.

Question 32

What is the sub-intima like?

Answer 32

Connective tissue that is a thicker outer layer.

Question 33

What are the 3 different types of sub-intima?

Answer 33

Areolar, fibrous, adipose.

Question 34

Is the synovial membrane innervated and vascularized?

Answer 34

Yes, but only the subintima not the intima.

Question 35

What are the functions of the synovial membrane?

Answer 35

Produce and resorbe synovial fluid and provide immunity to the joint cavity.

Question 36

What is found in the transition zones of cartilage?

Answer 36

Villi and fibrocartilage.

Question 37

Name the cells found in synovial membranes?

Answer 37

macrophages, secretory, fibroblast, lipocytes.

Question 38

What are synovial membrane capillaries like and why?

Answer 38

Fenestrated to increase the fluid exchange.

Question 39

Will Synovial membranes have lymphatic vessels?

Answer 39

Yes even the intima has lymphatic vessels as it needs to extract fluid from the synovial joint

Question 40

What is the function of the fibrous capsule of synovial joints?

Answer 40

Support, guide/ limit movement, absorb shock.

Question 41

What are the different cell types of the synovial membrane cells?

Answer 41

macrophages, secretory, fibroblast, lipocytes.

Question 42

What are fenestrated capillaries and what is the significance of them in the synovial joint?

Answer 42

Increase fluid exchange

Question 43

Other than synovial joints, where else are fenestrated capillaries also found?

Answer 43

Kidneys for fluid exchange

Question 44

With joint support what is the difference between dynamic and static?

Answer 44

Dynamic- muscles. Static- inter-locking bones and joint capsules.

Question 45

What happens when the fibrous capsule has scar tissue?

Answer 45

It will have abnormal wear and tear.

Question 46

What are extracapsular ligaments?

Answer 46

Those that are independent of the joint capsule. (don’t develop in the capsule)

Question 47

What are sharpey’s ligaments?

Answer 47

Ligaments that go into bone.

Question 48

What is Wolff’s law?

Answer 48

Bones grow from tension, the more tensile force on bone the more growth of bone occurs

Question 49

What is the innervation like for fibrous capsules?

Answer 49

well innervated with lots of proprioception.

Question 50

What is the vascularization like for fibrous capsules?

Answer 50

Not well vascularized, but is vascularized.

Question 51

If a joint has lots of bleeding or brusing involved what should be thought of?

Answer 51

Blood might come from a fracture, or muscle injury since bones and muscles are well vascularized.

Question 52

What is Bursae?

Answer 52

Synovial membrane lined extra-capsular pockets or pouches.

Question 53

Bursae communicate with what?

Answer 53

Synovial cavity, Thru passages/defects in the capsule. Others are separate.

Question 54

What are the 2 functions of bursae?

Answer 54

Lubricate and pad.

Question 55

What is another synovial membrane lined structure besides bursae that lines extra-capsular pockets or pouches?

Answer 55

Gastrocnemius and popliteus bursae.

Question 56

What is the purpose of gastrocnemius and popliteus bursae?

Answer 56

To help guide and lubricate tendons.

Question 57

What is the fluid like with bursae?

Answer 57

Thin film or fluid.

Question 58

What is the most common type of articular cartilage?

Answer 58

Hyaline cartilage.

Question 59

What is the leaste common type of articular cartilage and where is it found at?

Answer 59

Fibro-cartilage only 3.5 joints; AC, TMJ, 1/2 SI.

Question 60

What are the 3 things articular cartilage is made of?

Answer 60

water, collagen, GAG.

Question 61

What is the main component of articular cartilage?

Answer 61

H2O.

Question 62

What are the 2 parts of articular cartilage?

Answer 62

wet and dry parts.

Question 63

H20 makes up what % of total weight of articular cartilage?

Answer 63

80%.

Question 64

What makes up what % of the total dry weight of articular cartilage?

Answer 64

Collagen- 60-70%. GAG- 30-40%.

Question 65

What is the function of collagen in articular cartilage?

Answer 65

Holds things together and resists shear.

Question 66

What will give articular cartilage the rigid characteristics?

Answer 66

Strong water attraction from GAG’s.

Question 67

What is needed to make Collagen?

Answer 67

Vitamin C and amino acids.

Question 68

How are collagen fibers oriented at the articular surface?

Answer 68

Parallel.

Question 69

How will articular cartilage receive nutrition?

Answer 69

Synovial fluid, deep layers receive from bone diffusion. NO NUTRITION FROM BLOOD VESSELS.

Question 70

Name 2 important GAG’s in synovial joints?

Answer 70

chondroitin sulfate and glucosamine sulfate.

Question 71

Name 2 other GAG’s in synovial joints?

Answer 71

Keratin sulfate, hyaluronic acid.

Question 72

What is a dietary source of GAG’s?

Answer 72

Connective tissue, shellfish, cartilage.

Question 73

How will GAG’s pull water inside the articular cartilage?

Answer 73

It will attract H2O with the negative charged Sulfate and Carboxyl groups. This is why the Chondroitin sulfate and glucosamine sulfate GAG’s are important in articular cartilage.

Question 74

Synovial joint boundary lubrication is like what?

Answer 74

Teflon.

Question 75

What are small compressive loads of synovial joints like?

Answer 75

Weak inoic bonding and GAGs lubricate the surface.

Question 76

What are large compressive loads of synovial joints like?

Answer 76

Squeeze fluid film out of the cartilage.

Question 77

Why are slow oscillations of synovial joints good?

Answer 77

Fluid exchange.

Question 78

Why would rapid or no oscillations of synovial joints be bad?

Answer 78

Decreased fluid exchange.

Question 79

What happens to synovial joints with DJD?

Answer 79

Decreased cell # which leads to decreased GAGs and increased serous fluid which leads to decreased lubrication, which leads to increased calcification.

Question 80

subchondral or cancellous bone is aka?

Answer 80

Spongy bone.

Question 81

subchondral / cancellous / spongy bone is tuff stuff that does what?

Answer 81

Shock absorption.

Question 82

What happens with subchondral bone aka cancellous aka spongy bone with DJD?

Answer 82

Increases calcification which increases rigidity which increases thickness and impedes nutrient delivery, which decreases shock absorption.

Question 83

What is cartilage innervation in general like?

Answer 83

It is not innervated, but intra-articular cartilage is in the outer 1/3.

Question 84

What are the different types of intra-articular cartilage?

Answer 84

1. Disc. 2. Meniscus.

Question 85

Name 4 examples of disc intra-articular cartilage?

Answer 85

AC (in early 20s), SC, TMJ, Ulnocarpal (triangular fibrocartilage).

Question 86

Name 2 joints made of meniscus intra-articular cartilage?

Answer 86

Knee, AC (late 20’s to early 30’s).

Question 87

Intra-articular cartilage is made of what?

Answer 87

Fibrocartilage.

Question 88

What is the function of intra-articular cartilage?

Answer 88

Increases shock absorption, increases congruency(fits better), increases stability, decreases friction, increases motion.

Question 89

What type of innervation will intra-articular cartilage have?

Answer 89

Outer 1/3 transition with capsule, but has proprioception, nociception.

Question 90

What is the vascularizatino of intra-articular cartilage like?

Answer 90

Outer 1/3 is and inner 2/3 is avasular.

Question 91

In which part of the intra-articular carilage is it the furthest away from the nutrient source?

Answer 91

Middle of the intra-articular cartilage

Question 92

What happens to intra-articular cartilage with age?

Answer 92

Meniscus tear easier as we get older.

Question 93

How does intra-articular cartilage age?

Answer 93

Similar to IVD, increase vascularization, decrease chondrocytes, decrease GAGS, decrease collagen, increase collagen fiber size (more brittle_, decrease shock absorption, decrease flexibility

Question 94

Chiropractors are human ______.

Answer 94

Joint experts.

Question 95

Name the parts of synovial joints?

Answer 95

synovial membrane, fibrous capsule, articular cartilage, intra-articular cartilage, subchondral bone.

Question 96

What is the Number 1 disability encountered by the medical profession?

Answer 96

Joint disease.

Question 97

Synovial joint extends from where to where?

Answer 97

Metaphysis to metaphysis.

Question 98

Forces exerted on synovial joints and the tissues that provide support are generated how?

Answer 98

Partly by body weight, and mainly by muscle contraction across the joint.

Question 99

Synovial joints originate from what?

Answer 99

Mesenchymal “articular discs” between the primoridla bones.

Question 100

What happens to the mesenchyme in the zones where the joint will later appear?

Answer 100

It is replaced by cartilage.

Question 101

After the mesenchyme is replaced by cartilage what happens?

Answer 101

The cartilage plate then cavitates.

Question 102

Synovial fluid is secreted by what?

Answer 102

Cells of the synovial membrane.

Question 103

What are the 2 functions of the synovial membrane?

Answer 103

secrete and remove synovial fluid.

Question 104

What are the 2 groups of cells in the synovial membrane and what do they do?

Answer 104

A or F- Rich in hyalurionic acid. B or M- immune cells.

Question 105

What is the fibrous capsule of synovial joints like?

Answer 105

A barrel shaped sleeve around the joint that is reinforced by thickenings called capsular ligaments.

Question 106

From what will the fibrous capsuel develop?

Answer 106

Perichondrium of the embryonic cartilaginous model and remains attached to the periosteum.

Question 107

What is the main cellular component of articular cartilage?

Answer 107

Chondrocytes.

Question 108

What are chondrocytes responsible for?

Answer 108

Maintenance and repair of the cartilage matrix.

Question 109

What are chondrocyte life cycles like?

Answer 109

They are long lived in normal adult cartilage there is no further mitosis and growth subsides. Repair and regeneration of articular cartilage will predictably diminish with age.

Question 110

What happens when 2 cartilage surfaces are rubbed together?

Answer 110

An interposed film of synovial fluid that is 40 times more slippery than teflon occurs.

Question 111

What are the 2 types of lubrication and what are they used for?

Answer 111

Boundary- small loads. Hydrostatic- high loads.

Question 112

What is subchondral bones stiffness like?

Answer 112

100 times less stiff than cortical bone.

Question 113

What is the purpose of subchondral bone being less stiff?

Answer 113

It forms an intermediate zone that protects both articular cartilage and the diaphysis.

Question 114

Why would it be better for subchondral bone to be injured vs. articular cartilage?

Answer 114

Bone can heal better.

Question 115

Intra-articular cartilage developed from what?

Answer 115

Mesenchyme.

Question 116

What happens when intra-articular cartilage is torn?

Answer 116

It is rarely abosorbed and becomes a foreign body that can accelerate wear and tear on articular cartilage surface and should be removed.

Question 117

When intra-articular cartilage is removed what happens?

Answer 117

It is replaced by a dense fibrous connective tissue.

Question 118

What is the vascularization like for synovial joints?

Answer 118

They are highly vascularized around each joint there is a plexus called a rete or periarticular plexus.

Question 119

What are the 3 groups of arteries or veins that reach the joint area?

Answer 119

1. Epiphysis/metaphysis. 2. Fibrous joint capsule. 3. Synovial membrane.

Question 120

Why will the articular, intra-articular cartilage and synovial cavity be avascular?

Answer 120

They contain a substance that specifically inhibits the incursion of blood vessels and only in diseased and dying cartilage will blood vessels invade.

Question 121

Will synovial joints have lymphatics?

Answer 121

Yes and they help with the removal of synovial fluid.

Question 122

What is the innervation of large joints like?

Answer 122

They receive pain fibers from several spinal levels and the pain may be poorly localized or even deceptive.

Question 123

Active protection of a synovial joint is done by muscle contraction and joint motion and this active protection is called what?

Answer 123

Negative work.

Question 124

Negative work is the most important factor in what?

Answer 124

Sparing synovial joints from excessive loading.

Question 125

80% of cases of idiopathic osteoarthritis at the hip joint are due to what?

Answer 125

Defects that produce joint incongruity and uneven or increased impact loading.

Question 126

What happens to Proteoglycan with lack of compression in synovial joints?

Answer 126

This will result in decreased proteoglycan synthesis and abnormal binding.

Question 127

What will excersise do to ligaments?

Answer 127

Hypertrophy and increased strength.

Question 128

Osteoarthritis is not associated with what?

Answer 128

Systemic phenomena that are features of primary inflammatory joint diseases like RA.

Question 129

Deterioratin is most common in what joints?

Answer 129

Those that are subjected to abnormal loads.

Question 130

What is the specific healing agent with osteoarthritis?

Answer 130

None aside from reducing the source of irritation which may allow healing to occur.

Question 131

Most extremity synovial joints are what type of joint?

Answer 131

diarthroidal and highly mobile.

Question 132

What are the 3 types of joints according to the # of articulations?

Answer 132

1. Simple- 2 articular surfaces (1 articulation). 2. Compound- 2 or more articulations. 3. Complex- 1 or more articulation plus intra-articular disc/meniscus.

Question 133

What is an example of a simple joint?

Answer 133

DIP joint

Question 134

What is an example of a compound joint?

Answer 134

tibiofemoral, subtalar, patellofemoral joint

Question 135

What is an example of a complex joint?

Answer 135

Knee, ulnocarpal, AC, SC, TMJ, knee joint & radiocarpal joint

Question 136

What is a joint complex?

Answer 136

Several joints acting together as a functional group. Like the knee, shoulder, wrist, elbow.

Question 137

What are the 6 types of joints based on anatomical/ morphological classifications?

Answer 137

1. Spheroid- ball and socket. 2. Ellipsoid- condyloid. 3. Arthroid- planar(gliding). 4. Sellar- saddle. 5. Ginglymus- hinge. 6. Trochoid- pivot.

Question 138

What is an example of a spheroid joint?

Answer 138

shoulders and hip (more moveable than ellipsoid

Question 139

What is an example of an ellipsoid joint?

Answer 139

Knee and occipital axial joint (spheriod in shape but moves in pairs)

Question 140

What is an example of a arthroid joint?

Answer 140

Planar = flat, radioulnar joint

Question 141

What is an example of a sellar joint?

Answer 141

First carpal metacarpal joint

Question 142

What is an example of a ginglymus joint?

Answer 142

knee, elbow, intercarpal joint

Question 143

What is an example of a trochoid joint?

Answer 143

humeral-radius joint at the capitellum

Question 144

What are the 4 joint motion classifications?

Answer 144

1. angular. 2. Translational. 3. Rotational. 4. Circumduction.

Question 145

What is angular motion?

Answer 145

Flexion, extension, abduction, adduction.

Question 146

What is translational motion?

Answer 146

Primarily gliding non-angular.

Question 147

What is rotational motion?

Answer 147

Non-angular (not spin).

Question 148

What is circumduction motion?

Answer 148

A combinatino of all of the above 3 motions.

Question 149

What are 4 motions based on axes of motion?

Answer 149

1. Uniaxial. 2. Biaxial. 3. Polyaxial. 4. Nonaxial.

Question 150

What is uniaxial motion?

Answer 150

Can only move in 1 plane. (ankle joint (plantar and dorsiflexion))

Question 151

What is biaxial motion?

Answer 151

Can move in only 2 planes. (knee, most bicondylar joints)

Question 152

What is polyaxial motion?

Answer 152

Can move in many planes. ( shoulder and hip)

Question 153

What is nonaxial motion?

Answer 153

Gliding.

Question 154

Why are joint surfaces irregular and ovoid in shape?

Answer 154

Non linear accessory motions.

Question 155

What is the function of crooked or crank shaped bones?

Answer 155

actions differ from joint motion.

Question 156

MacConail coined the term osteokinematics which is based on what?

Answer 156

Mechanical axis not axis of rotation.

Question 157

What are the 2 types of mechanical axis aka osteokinematics?

Answer 157

Spin and swing.

Question 158

What is spin?

Answer 158

Stationary mechanical axis (not always the same as rotation).

Question 159

What is swing?

Answer 159

Mechanical axis moves.

Question 160

With spin is the mechanical asix stationary or moving?

Answer 160

Stationary.

Question 161

Spin may rotate when?

Answer 161

The mechanical axis is parallel to the long axis.

Question 162

Why will spin usually not equal rotation?

Answer 162

Bones are crooked/ bent and the mechanical axis does not parallel the long axis.

Question 163

How often will pure spin occur?

Answer 163

Not often.

Question 164

What does spin usually accompany?

Answer 164

swing

Question 165

Why don’t we use spin and rotation synonymously?

Answer 165

Spin can produce angular motion or rotation so they are not the same (for example: shoulder internal and external rotation is actually swinging because the humerus is swinging along the glenohumeral joint)

Question 166

What are the motions of swing?

Answer 166

Straight line, chord, arc.

Question 167

What is impure swing?

Answer 167

Spin + swing. (typical motion)

Question 168

What is conjoint/conjunct rotation?

Answer 168

Relates to impure swing.

Question 169

Screw home mechanism is what?

Answer 169

External rotation of the tibia with knee extension.

Question 170

Screw home mechanism at the knee is a good example of what?

Answer 170

Conjoint rotation.

Question 171

How rare is pure swing?

Answer 171

Rare.

Question 172

Arthrokinematics is based on what?

Answer 172

Movement at articular surfaces.

Question 173

What are the 3 types of movements with arthrokinematics?

Answer 173

Roll, slide/glide, spin.

Question 174

What would the name be of the movement of all 3 arthrokinematic motions combined?

Answer 174

Accessory rotation.

Question 175

Roll only results in what?

Answer 175

Progression. (ie: car lifting off ground with high acceleration

Question 176

What are the 3 problems created with roll?

Answer 176

Progression, distraction, impingement.

Question 177

What are the 3 problems created with slide?

Answer 177

Progression, distraction, impingement.

Question 178

Can convex and concave surfaces both roll?

Answer 178

Yes

Question 179

What is the arthrokinematic motion used with manipulations?

Answer 179

Slide.

Question 180

What are the 2 rules used when combining roll and slide?

Answer 180

Convex and concave rule.

Question 181

What is the convex rule?

Answer 181

Direction of slide is opposite the direction of angular, roll is in same direction of angular motion and slide and roll occur in opossite directions.

Question 182

What is the concave rule?

Answer 182

Direction of slide and roll are in the same direction of angular movement. Slide and roll occur in same direction

Question 183

What surface is longer the concave or convex?

Answer 183

Convex.

Question 184

What is conjunct or conjoint rotation?

Answer 184

Accessory rotation that is combining the arthrokinematic movements.

Question 185

What is the difference between closed and open positions in kinematics?

Answer 185

Closed aka tight packed position is when the joint is stabilized as the joint capsule is tense and this inhibits movement. Open aka loose packed position is necessary for movement.

Question 186

What are the different types of open and closed positions?

Answer 186

Open there are an infinite amount of positions. Closed there is only 1 closed packed position.

Question 187

What is the difference between resting and neutral position with kinematics?

Answer 187

Resting position- the loosest packed position or the most open position. Every joint has a resting position. Position patients get in when they have a problem. Resting position is just a part of the loose pack position they are not synonyms. Neutral position- This is a position that was decided upon by a group of people and is often the anatomical position. This position is known as zero which is between the different types of motion for the joint (like between flexion and extension).

Question 188

What is the difference between end play and joint play?

Answer 188

end play- accessory movements that occur within motion that the person can create. Joint play- a movement in a direction that cant be normally produced.

Question 189

Name 7 muscle functions?

Answer 189

shock absorption, dynamic joint stabilization, dynamic joint alignment, acceleration, deceleration, heat production, venous circulation.

Question 190

Name the static joint stabilizers?

Answer 190

Hydrostatic, capsular, and bone fit.

Question 191

What muscle functions will be concentric and what will be eccentric contractions?

Answer 191

Acceleration- concentric. Deceleration- eccentric.

Question 192

What is an isometric muscle contraction?

Answer 192

No movement or length change.

Question 193

What is an isotonic muscle contraction?

Answer 193

Produces joint motion, muscle length change, variable velocity.

Question 194

What is an isokinetic muscle contraction?

Answer 194

Same as isotonic except velocity remains constant.

Question 195

What is the line of progression?

Answer 195

A line that is in the middle of the legs when walking and is the line that shows the progression made.

Question 196

What is step, step length?

Answer 196

one step with one limb.

Question 197

What is stride?

Answer 197

One complete cycle of gait so it is 2 steps.

Question 198

What is a normal amount of foot flare while walking?

Answer 198

5-7 degrees.

Question 199

Increased foot flare leads to what?

Answer 199

Decreased efficiency.

Question 200

Foot flare decreases with what?

Answer 200

Increased cadence (flow or rhythm. Running).

Question 201

Too much toe out leads to what?

Answer 201

Increased stress on the lower extremity leading to injury. Also leads to inefficient so muscles need to work more and stride length is decreased.

Question 202

What are the 2 phases of the gait cycle?

Answer 202

1. Stance - support (foot in contact with ground). 2. Swing. - recovery (foot is not in contact with ground)

Question 203

What is the kinetic chain like for the 2 phases of a gait cycle?

Answer 203

stance- closed. Swing- open.

Question 204

Running and walking will each involve what parts of the gait phases?

Answer 204

Running- 40% stance, 60% swing. Walking- 60% stance, 40% swing.

Question 205

Why will increased speed during gait cycles lead to more injury?

Answer 205

When speed is increased the following will also be increased; compression, distraction, torsion, shear, bending, inertia. Also Increased ground reaction forces and increased muscle activity.

Question 206

Of the forces that are increased when speed is increased with gait which ones are the most damaging?

Answer 206

Torsion, shear.

Question 207

The stance phase of the gait cycle is from when to when?

Answer 207

From footstrike to take off.

Question 208

What is the difference between toe off and take off?

Answer 208

Toe off- is the very end of take-off. So toe off is just a part of take-off.

Question 209

When will the swing phase of gait happen at?

Answer 209

From toe-off to heel strike.

Question 210

What is a closed kinetic chain?

Answer 210

The distal end of limb is connected to a fixed object (ie: the ground) - foot strike to toe off

Question 211

What is an open kinetic chain

Answer 211

The distal end of the limb is not connected/attached to a fixed object - from toe off to footstrike

Question 212

What is double support and float and when will they happen?

Answer 212

Double support- one foot is in foot strike while the other is in take-off, this only happens during walking. Float- both limbs in swing, this only happens while running.

Question 213

What are the 3 subdivisions of the stance phase of gait and what % of the stance phase will each take up?

Answer 213

1. Contact aka foot strike- 25%. 2. Midstance or midsupport- 50%. 3. Take-off aka proplusive- 25%.

Question 214

During the contact or foot strike phase the foot lands where?

Answer 214

Ahead of the center of gravity.

Question 215

Name 2 important functions of the contact phase of gait?

Answer 215

1. Abosrb shock. 2. adapt to ground uneveness.

Question 216

Pronation of the foot is what?

Answer 216

Medial rotation of foot.

Question 217

What is a pronated foot like?

Answer 217

more flexible and can absorbe more energy.

Question 218

Name the 2 important joints involved in the contact phase of gait?

Answer 218

subtalar and midtarsal. (for pronation and supination)

Question 219

What are the motions of the calcaneus and talus during the contact phase of gait?

Answer 219

Eversion in general. And some abduction of foot and calcaneus to talus and dorsiflexion of calcaneous relative to the talus (ie: talus plantar flexes)

Question 220

What is heel rocker?

Answer 220

dorsiflexion of calcaneus and forefoot; talus at ankle plantar flexes (heel rocker) completed before pronation is complete.

Question 221

During contact phase what is the motion of the forefoot in relation to the the rearfoot?

Answer 221

dorsiflexion.

Question 222

When is the foot most pronated?

Answer 222

At the end of the contact period or at the beginning of the midstance period

Question 223

What position is the foot in when it lands while we are walking?

Answer 223

it is 2 degrees supinated.

Question 224

While walking after the foot lands 2 degrees supinated what happens?

Answer 224

The talus plantar flexes and then the foot begins pronating.

Question 225

What is the ideal and clinical pronation range while walking?

Answer 225

Ideal- 6-10 degrees. Clinical- 5-15 degrees.

Question 226

Why is it important that the tibia and femur internally rotate during the contact phase while walking?

Answer 226

This will reduce torque. (if the leg and foot rotate in opposite directions, torque is increased)

Question 227

What 2 types of stress seem to be most deleterious to connective tissue?

Answer 227

Torsion and Shear

Question 228

During the gait cycle what is the action of the foot relative to the leg?

Answer 228

Subtalar rotates with leg, but not at ankle. Calcaneus moves with the foot.

Question 229

While walking the foot lands 2 degrees supinated and then what will happen before it pronates?

Answer 229

Plantar flexion.

Question 230

When will people be rearfoot strikers or forefoot strikers?

Answer 230

Rearfoot- walking, slow running, jogging. Forefoot- fast running.

Question 231

While walking what happens right after rearfoot strikers strike?

Answer 231

Foot/talus plantar flexes.

Question 232

With rearfoot strikers how is the plantar flexion accomplished?

Answer 232

Tibialis anterior eccentrically controls plantar flexion at the subtalar and midtarsal joint and it also controls pronation of the foot and it also pulls the leg forward.

Question 233

What large thigh muscle will the tibialis anterior assist?

Answer 233

Quadriceps.

Question 234

How will the peroneus tertius aid the tibialis anterior?

Answer 234

in dorsiflexion and it will counteract the tibialis anterior induced inversion.

Question 235

While running what muscle will be very active at lowering the ankle and what will this accomplish?

Answer 235

Gastrocosoleus and it will be a shock absorber.

Question 236

While running after forefoot strikes what happens?

Answer 236

The foot dorsiflexes after the metatarsal heads strike the ground and the heel moves toward ground.

Question 237

While running the forefoot strike is in what position?

Answer 237

2-4 degrees supinated.

Question 238

While running will the foot pronate after it lands 2-4 degrees supinated?

Answer 238

yes at subtalar and midtarsal joints.

Question 239

While running what muscle will control the pronation?

Answer 239

tibialis anterior and posterior.

Question 240

What will more inertia that comes from running cause?

Answer 240

more eccentric muscle activity —> increased risk of injury.

Question 241

When will midstance happen?

Answer 241

From foot flat to heel off.

Question 242

During midstance where will the center of gravity be?

Answer 242

over the stance limb.

Question 243

While in midstance with a single support what position is the other limb in?

Answer 243

Swing.

Question 244

What position is the foot in during midstance?

Answer 244

pronated relative to neutral.

Question 245

During midstance the foot is pronated and what motions will it undergo?

Answer 245

supination.

Question 246

How is supination done while in the midstance?

Answer 246

ankle/talus dorsiflexes as center of gravity continues to move forward relative to stance foot. This is dorsiflexion of the foot “ankle rocker”.

Question 247

What position will the leg and thigh be in during midstance? Why?

Answer 247

Leg and thigh extend and externally rotate and this will reduce torque.

Question 248

When should heel lift occur during running, walking and what will this mean?

Answer 248

Running- after swing limb passes stance limb. Walking- at heel strike of opposite limb. The significance is overloading the gastrosoleus.

Question 249

What should arm swing be like compared to the midstance?

Answer 249

counterbalancing arm swing (crawl mechanism right upper and left lower limb move back and forth together).

Question 250

Where is the center of gravity during take off?

Answer 250

anterior to stance foot.

Question 251

During take off what muscles lift the heel?

Answer 251

gastrocsoleus. (d/t stretch) but push off in running

Question 252

What muscle will rapidly invert the calcaneusto complete rearfoot supination at take-off?

Answer 252

Tibialis posterior rapidly inverts the calcaneus.

Question 253

What happens to the foot when supination is completed?

Answer 253

The foot is ridgid lever except toes.

Question 254

What will allow roll on ball of foot during take off?

Answer 254

Passive toe extension.

Question 255

The toe extension tenses what?

Answer 255

The plantar fasciae escpecially the hallux. (Hallux extends 60 degrees)

Question 256

What muscles will eccentrically control the toe extension?

Answer 256

Toe flexors.

Question 257

How will weight shift on the plantar surface during the take-off phase?

Answer 257

It shifts medially across metatarsal break.

Question 258

What is the metatarsal break?

Answer 258

Oblique angle of metatrasal heads.

Question 259

What motion happens at the end of take-off and why?

Answer 259

Slight pronation and this will increase the load bearing on the 1st and 2nd metatarsals.

Question 260

What is the last part of the take-off phase?

Answer 260

Toe off.

Question 261

What ray is most important to forefoot control just prior to toe off?

Answer 261

1st

Question 262

What 5 muscles are important to 1st ray stabilization and control of pronation prior to toe off?

Answer 262

P. longus, Flexor Hallucis Longus, Flexor Hallucis Brevis, Adductor Hallucis, Abductor Hallucis (since they all attach to the first ray)

Question 263

What are the tibia and femur doing during take off and why?

Answer 263

They are externally rotating to reduce torque.

Question 264

What happens if there is too much late pronation in take-off?

Answer 264

Overwork of muscles and torque on osseous and fibrous tissues that may affect the foot, ankle or leg (may lead to stress fractures). Usually a first sign is posterior shin splints.

Question 265

What is the peroneus longus doing during take-off?

Answer 265

Lifts cuboid and lateral foot (pronates), depresses and plantar flexes first ray which helps shift weight medially along metatarsal break. It also maintains contact between ground and 1st metatarsal head during take off.

Question 266

What muscle will help the peroneus longus maintain contact between ground and 1st metatarsal head during takeoff?

Answer 266

Toe plantar flexors.

Question 267

How will foot supination and foot pronation affect the leverage of the peroneus longus?

Answer 267

supinated foot- increases leverage. Pronated foot- decreases its leverage.

Question 268

What will happen with a hypermobile dorsiflexed 1st metatarsal / hallux valgus?

Answer 268

It will lead to late pronation which will increase torque and therefore increase injury.

Question 269

During the swing phase how is inertia produced?

Answer 269

acceleration and decelleration.

Question 270

What are the 3 divisions of the swing phase and what will the limb be doing in these phases?

Answer 270

1. Initial or follow through- limb moves back and stops. 2. Mid-swing or forwar/anterior swing- limb moves forward and stops. 3. Terminal swing or foot descent- limb moves back again.

Question 271

What are the knee and tibia doing during the intial swing part of the swing phase?

Answer 271

Knee flexes and tibia internally rotates.

Question 272

What is the hip doing during initial swing?

Answer 272

Hip extends and externally rotates. (increases internal tibial rotation)

Question 273

What muscles eccentrically decelerate the hip and knee in the initial swing phase?

Answer 273

hip flexors.

Question 274

What muscles will accelerate the hip and knee during the first part of mid-swing phase and how will they do this?

Answer 274

Hip flexors, concentrically.

Question 275

Will there be more initial swing during walking or running?

Answer 275

Running.

Question 276

Where is the opposite limb at during the initial swing while walking and running?

Answer 276

Walking- end of foot strike. Running- terminal swing.

Question 277

The early part of mid-swing phase is like what?

Answer 277

The bowling ball effect- momentum pulls forward. (caused by hip flexors)

Question 278

What hip flexor is the most vulnerable to injury?

Answer 278

Rectus Femoris

Question 279

What muscles will slow the swinging limb during mid-swing and how?

Answer 279

Gluteal and hamstrings eccentriaclly slow the forward swinging limb and hip and knee.

Question 280

What is the foots position during mid-swing and why?

Answer 280

Neutral to slightly dorsiflexed to prevent foot dragging.

Question 281

What is happening to the hip during mid-swing and why?

Answer 281

The hip is being internally rotated by the adductors which brings the foot back to the line of progression.

Question 282

What muscles will accelerate the limb backwards during terminal swing phase?

Answer 282

Hip extensors and knee flexors

Question 283

What is determined during the swing phase?

Answer 283

foot flare and amount of rearfoot inverions and pronation during the next stance phase.

Question 284

What is the tension like on the hamstrings during terminal swing?

Answer 284

The tension is highest.

Question 285

Why would the foot rotate in the same direction as the leg and thigh during gait?

Answer 285

To reduce torque and injury.

Question 286

What is the general trend during the contact phase?

Answer 286

Everything is medially rotating

Question 287

What is the general trend during the mid stance phase?

Answer 287

Everything is laterally rotating

Question 288

How many bones, muscles and joints are there in the foot and ankle

Answer 288

Bones- 28. Joints- 35 or more. 18 foot and 11 leg muscles.

Question 289

Name the 6 important joints of the foot and ankle?

Answer 289

1. Talocural. 2. Subtalar. 3. Choparts aka midtarsal. 4. Lisfranscs. 5. 1st tarsometatarsal. 6. first metatarsophalangeal.

Question 290

Where is the subtalar joint at?

Answer 290

Talocalcaneal. (2 concave and 1 convex)

Question 291

What is the lisfrancs joint?

Answer 291

1-5 TMT joint.

Question 292

During gait, which two joints are important lisfranc joints?

Answer 292

First tarsometatarsal and first metatarsophalangeal

Question 293

What is another name for the tarsometatarsal joint?

Answer 293

Cuneometatarsal joint.

Question 294

What is the midline of the foot and why will this matter?

Answer 294

It is the 2nd metatarsal and it is a reference point for abduction and adduction of the toes.

Question 295

What are the midtarsal and subtalar joint most important for?

Answer 295

Medial and lateral rotation of the foot

Question 296

Name the three arches of the foot and the keystones that go with them?

Answer 296

Medial arch- talus. Lateral arch- cuboid. Transverse arch- second metatarsal.

Question 297

What is the largest of the 3 arches of the foot?

Answer 297

Medial longitudinal arch.

Question 298

What % of body weight is on which part of the foot while standing?

Answer 298

Heel-60%. Metatarsal head- 26%(of the 26% 50% is on the first and second metatarsal heads).

Question 299

How will static weight distribution happen with heel inversion?

Answer 299

Inversion aka rearfoot varum will shift weight to the lateral side of the foot and can cause more ankle sprains.

Question 300

How will static weight distribution happen with heel eversion

Answer 300

Eversion aka rearfoot valgum and shifts weight to medial side of heel and might affect the knee and helps bend big toe out.

Question 301

How will static weight distribution happen with high heels or tight gastrocsoleus?

Answer 301

Causes shift in weight to forefoot (ball of foot) and shortens the gastrocnemius. (forefoot can’t usually handle constant weight)

Question 302

How will static weight distribution happen with a dorsiflexed first ray and a plantar flexed first ray?

Answer 302

Dorsiflexed- collapsed medial longitudinal arch and pronation may be affected. Plantar- Changes arch with higher arch more supinated less pronation and shifts weight to outside foot.

Question 303

How will static weight distribution happen with a fixed 1st Metatarsaophalangeal joint?

Answer 303

Prevents big toe from extending and shifts weight to lateral side of foot.

Question 304

How will static weight distribution happen with a long 2nd ray? What is this also known as?

Answer 304

aka mortons foot and increases weight on 2nd metatarsal and may cause stress fractures and may interfere with first ray and take off.

Question 305

How will static weight distribution happen with Forefoot varus and forefoot valgum?

Answer 305

Varus (rigid foot)- shifts weight to outside of foot. Valgum- shifts weight to inside of foot.

Question 306

How will static weight distribution happen with splay foot?

Answer 306

Splay- loss of transverse arch causing metatarsals to spread apart. Increases weight bearing to middle 3 metatrsals and can cause stress fractures.

Question 307

How will static weight distribution happen with pes planus?

Answer 307

Pes planus- Flat foot, causes a weight distribution evenly and this is not good.

Question 308

How will static weight distribution happen with pes cavus?

Answer 308

Pes Cavus- increases tripod effect to the extreme and this is bad. Heel first metatarsal and not so much weight everywhere.

Question 309

How will static weight distribution happen with rear foot valgus?

Answer 309

shifts weight to Medial side of foot

Question 310

How will static weight distribution happen with rear foot varum?

Answer 310

shifts weight to Lateral side of foot

Question 311

What are the 3 keystones in the foot for arch support?

Answer 311

Talu, Cuboid and 2nd metatarsal and cuneiform

Question 312

Which bone is the keystone for the medial longitudinal arch?

Answer 312

Talus

Question 313

Which bone is the keystone for the lateral longitudinal arch?

Answer 313

Cuboid

Question 314

Which bone is the keystone for the transverse arch?

Answer 314

2nd metatarsal and 2nd cuneiform

Question 315

What are the 4 ligaments that act as staples/ mortor for the foot and ankle?

Answer 315

Spring (plantarcalcanealnavicular), long plantar, short plantar, transversemetatarsal ligaments.

Question 316

What ligament acts as the staple/mortor for the medial longitudinal arch?

Answer 316

Spring ligament

Question 317

What ligament acts as the staple/mortor for the lateral longitudinal arch?

Answer 317

Long plantar and short plantar ligaments

Question 318

What ligament acts as the staple/mortor for the transverse arch?

Answer 318

Transverse metatarsal ligament

Question 319

For foot and ankle support what will act as tie beams (bowstrings)?

Answer 319

Foot intrinsics, Tibialis poster, Flexor Digitorum longus and Flexor Hallucis Longus (Tom, Dick and Harry), Peroneus longus, plantar fasciae.

Question 320

What is the most important part of the plantar fasciae for foot and ankle support?

Answer 320

Medial part.

Question 321

What are the 4 suspensors of foot and ankle support?

Answer 321

Tibialis Anterior, Tibialis posterior ,Peroneous Longus, Peroneus Brevis, Peroneus Teritius

Question 322

What are the 2 stirrup muslces that support the foot and ankle?

Answer 322

Peroneus Longus, Tibialis Anterior.

Question 323

OF the 4 tie beams which one will be dynamic?

Answer 323

Muscles are always the dynamic supports

Question 324

What is the keystone of the medial longitudinal arch?

Answer 324

Talus

Question 325

What is the staples of the medial longitudinal arch?

Answer 325

Spring ligament (plantarcalcanealnavicular)

Question 326

What are the beams of the medial longitudinal arch?

Answer 326

Plntar fascia, intrinsics (hallicus), plantar aponeurosis, abductor hallucis and flexor digitorum brevis of first 2 toes, tibialis posterior (in hind foot)

Question 327

What are the suspenders of the medial longitudinal arch?

Answer 327

Tibialis anterior and posterior

Question 328

What is the keystone of the lateral longitudinal arch?

Answer 328

Cuboid

Question 329

What is the staples of the lateral longitudinal arch?

Answer 329

Long and short plantar ligaments

Question 330

What are the beams of the lateral longitudinal arch?

Answer 330

Lateral part of plantar fascia, long and short plantar ligaments and lateral foot intinsics

Question 331

What are the suspenders of the lateral longitudinal arch?

Answer 331

Peroneals

Question 332

What is the keystone of the transverse arch?

Answer 332

2nd metatarsal and 2nd cuneiform

Question 333

What is the staples of the transverse arch?

Answer 333

Transverse metatarsal ligament

Question 334

What are the beams of the transverse arch?

Answer 334

Peroneus Longus tendon, adductor hallicus (transverse head), plantar aponeurosis and plantar fascia

Question 335

What are the suspenders of the transverse arch?

Answer 335

None

Question 336

What do the intrinsics of the foot and ankle act like?

Answer 336

Spring like dynamic tie beams.

Question 337

Fatigue of the plantar fascia from overuse leads to what?

Answer 337

Pronation syndrome and foot cramps.

Question 338

Is the plantar fascia and elastic or inelastic tie beam?

Answer 338

Inelastic.

Question 339

Is the plantar fascia static or dynamic?

Answer 339

Static.

Question 340

The plantar fascia connects what two structures together?

Answer 340

Medial and lateral calcaneal tubercles to the bones and fasciae of the toes.

Question 341

When the toes extend what toe attachment of the plantar fascia is most important?

Answer 341

first toe is important and it extends during takeoff

Question 342

Why is there more stress on the medial tubercle?

Answer 342

When the big toe extends passively it leads to the forward pull on the calcaneus leading to a decrease of stress on muscles

Question 343

During toe extension the plantar fascia allows the foot to do what?

Answer 343

Roll and act as a rigid lever.

Question 344

What is the windlass effect of the plantar fascia?

Answer 344

maintains the arches and allows gastrocsoleus to act at the ball of foot like a pully.

Question 345

Where does the plantar fascia or aponeurosis extend?

Answer 345

Extends the Achilles’ tendon to forefoot

Question 346

What will the plantar fascia do for the arch of the foot?

Answer 346

Support it and functions as a pulley

Question 347

What is another name for supinated foot and pronated foot (not eversion/ inversion)?

Answer 347

Supinated- pes cavus. Pronated- pes planus.

Question 348

What happens to the arch of the foot with pes cavus and pes planus?

Answer 348

Pes cavus- high arch. Pes planus- low arch.

Question 349

Which foot will be curved and which one is straigth pes cavus or pes planus?

Answer 349

Pes cavus- curved. Pes planus- straight.

Question 350

What happens to shock absorption for pes cavus and pes planus?

Answer 350

They both decrease shock absorption.

Question 351

What part of the shoe will break down faster with pes cavus and pes planus?

Answer 351

Pes cavus- lateral shoe. Pes planus- medial shoe.

Question 352

What are the static listings of the calcaneus with a pronated foot and what happens with these?

Answer 352

everted calcaneus- decreases inversion joint play. Posterior calcaneus- decreases anterior slide at subtalar joint.

Question 353

What are the static listings of the talus, navicular with a pronated foot and what happens with these?

Answer 353

Medial talus- talus swings medial with the leg plantar flexed head which leads to head swing medial with leg not at ankle joint. Inferior navicular (didn’t give rationale)

Question 354

What happens to the metatarsals with a pronated foot in static weight bearing position?

Answer 354

Dorsiflexed- at Tarsometatarsal joints.

Question 355

What happens to the proximal phalanges with a pronated foot in static weight bearing position?

Answer 355

Flexed- straight toe.

Question 356

What type of shoe will be prefered by someone with a pronated foot?

Answer 356

Stiff supportive, straight last, medial post.

Question 357

What foot will be longer and what foot will be shorter a pronated or supinated foot?

Answer 357

Pronation- functionally decreases leg length and supination increases leg length.

Question 358

What are the static listings for the calcaneus for a supinated foot in static weight bearing position?

Answer 358

Inverted calcaneus. Anterior calcaneus- dorsiflexed to the ground, but plantar flexed relative to talus.

Question 359

What are the static listings for the talus, and navicular for a supinated foot in static weight bearing positions?

Answer 359

Lateral talus- head swings lateral with head. Superior navicular.

Question 360

What happens to the metatarsals and proximal phalanges with a supinated foot in static weight bearing position?

Answer 360

Plantar-flexed metatarsals. Extended proximal phalanges (claw toes).

Question 361

What type of shoe will be prefered by someone with a supinated foot?

Answer 361

Slip last- no stiff board, curved last, shock absorbing innersole and mid-sole.

Question 362

What is the torque converter between the leg and foot?

Answer 362

Subtalar joint.

Question 363

What is the key that locks and unlocks the midtarsal joints?

Answer 363

Subtalar joint.

Question 364

What foot will be more rigid and what foot will be more flexible a pronated or supinated foot?

Answer 364

Pronated- flexible. Supinated- rigid.

Question 365

What can cause abnormal or excessive foot pronation?

Answer 365

Rearfoot varum, forefoot varum, forefoot valgum, leg length asymmetry, muscle imbalance, fatigue, weakness or injury.

Question 366

What happens with a tibialis anterior and posterior fatigue or injury?

Answer 366

Shin splints.