CASE 9 - bone, stress fractures, muscle Flashcards
what is woven bone?
- primary bone
- appears in embryonic development and fracture repair as it can be laid down rapidly
- consists of osteoid (unmineralised ECM), with the collagen fibres arranged randomly
- it is a temporary structure, soon replaced by mature lamellar bone
what is lamellar bone?
- secondary bone — the bone of the adult skeleton
- consists of highly organised sheets of mineralised osteoid — this organised structure makes it much stronger than woven bone
- can be divided into 2 groups — compact and spongy
what is endochondral ossification?
where hyaline cartilage is replaced by osteoblasts secreting osteoid (eg. occurs in femur)
what is intramembranous ossification?
where mesenchymal (embryonic tissue) is condensed into bone. forms flat bones such as the temporal bone and scapula
what are the steps involved in the repair of a bone fracture?
- formation of a haematoma at the site of fracture
- migration of fibroblasts to the fracture site
- bridging of broken ends by a fibrocartilaginous callus
- osteoblast production of trabeculae and bony callus formation
- resorption of remaining bone fragments and remodelling of bone
describe osteogenesis
- osteoblasts secrete collagen molecule and ground substance (extrafibrillar matrix)
- collagen molecules combine to form collagen fibres
- the resultant tissue is called osteoid (non-calcified bone)
- hydroxyapatite crystals form on the collagen fibres. the osteoid is now calcified and this is bone
what produce new bone, secrete osteoid and are responsible for mineral depostition?
osteoblasts
what are mature bone cells located in lacunae and maintain the matrix?
osteocytes
how do osteoclasts work?
- osteoclasts adhere to an area of trabecular bone
- they dig a pit by secretion H+ and proteolytic enzymes (osteolysis)
- this secretes cytokines such as IGF-1 and TGF-B that have been embedded into the osteoid
- these cytokines recruit and activate ostoblasts that have been stimulated to develop from osteoprogenitor cells
- osteoblasts invade the site, synthesising and secreting the organic matrix of the bone (the osteoid) and secreting IGF-1 and TGF-B
- the osteoid is then calcified into bone
- some osteoblasts become embedded in the osteoid, forming terminal osteocytes
where are osteogenic stem cells found?
endosteum and periosteum
what do osteogenic stem cells develop into?
osteoblasts
what is a stress fracture?
= a fracture occurring in normal bone that has been subject to excessive and repeated trauma resulting in cumulative microscopic fractures
- over time, these micro fractures exceed the capacity of the normal healing process, resulting in the development of a macrofracture
micro damage > repair process —> stress response —> stress fractures
where do stress fractures commonly occur?
in poorly vascularised areas eg. 5th metatarsal, navicular, anterior tibia
signs and symptoms of stress fracture
- pain, localised tenderness and swelling gradually develop
- percussion of bone away from fracture may illicit pain
X-RAYS in stress fractures
- initially normal
- plain x-ray is 1st line imaging — initially normal or very subtle with radiolucency and poor definition of the cortex
- later on, thickening and sclerosis of endosteum and periosteum new bone formation
MRI in stress fracture?
- has taken over from bone scan
- can pick up a stress response before a stress fracture
what would be measured in bloods for a stress fracture?
vitamin D levels, bone profile, hormone levels
when is a bone scan good for stress fractures?
if worried about multiple non-continuous stress fractures eg. 2nd or 5th metatarsal fracture in combination with tibial fracture
management of stress fractures?
- rest and immobilisation
- avoid NSAIDs (can slow down bone healing)
- get patient on board
- pulsed ultrasound or extracorporeal shock wave therapy (ESWL)
describe pulsed ultrasound
upregulates chondrocytes and increases endochondral ossification
describe ESWL
induces periosteal detachment and micro trabecular fracture — stimulates fracture healing
what is the indication for surgery for a stress fracture?
the presence of the “dreaded black line” in tibia. surgery is only used when conservative management has failed
what is shin splints caused by?
repeated trauma to the connective muscle tissue surrounding the tibia
what is a common cause of shin splints?
over pronation
- pronation occurs when the ankle bone moves downward and towards the middle to create a more stable point of contact with the ground (ie. the ankle rolls inwards so that more of the arch has contact with the ground)
- this abnormal movement causes muscles to fatigue more quickly and unable to absorb any shock from the foot hitting the ground
pain associated with shin splints is caused from a disruption of what?
Sharpey’s fibres that connect the medial soleus fascia through the periosteum of the tibia where it inserts into the bone
with repetitive stress, impact forces fatigue the ____ and created repeated ___ bending
- soleus
- tibial
the impact causing shin splints is worsened by what?
running uphill, downhill, on uneven terrain or on hard surfaces
also wearing improper footwear
how are shin splints treated?
- rest
- applying ice to shin to reduce blood flow
- elevation of legs reducing swelling and pain killers/anti-inflammatories
why might ACL tears be more common in women?
- physical conditioning
- muscular strength
- neuromuscular control
- pelvis size — females have wider hips and so working their legs will cause the vastus lateralis to develop more than the vastus medialis, thus pushing the patella laterally and causing the tear in the ligament
- lower extremity (leg) alignment
- increased looseness in ligaments
- effects of oestrogen on ligament properties
what are causes of ACL tears?
- changing direction rapidly
- stopping suddenly
- slowing down while running
- landing from jump incorrectly
- direct contact or collision eg. football tackle
what are the symptoms of an ACL tear?
- pain with swelling — within 24 hours the knee swells. swelling and pain may resolve on its own. however if sports resumed, the knee will be unstable and there’s risk of further damage to the cushioning cartilage (meniscus)
- loss of full range motion
- tenderness along joint line
- discomfort while walking
why do you get an over rotated hip and how can it cause knee pain?
- internal rotation of femur due to weak gluteus medius, vastus medialis
- creates shear force in femur
- shear force is moving lateral —> medial around knee
what are 3 major factors contributing to the aetiology of patellofemoral pain syndrome?
- quadriceps muscle imbalance and/or weakness
- lower extremity and patellofemoral malalignment
- physical overload of the patellofemoral joint
what is the Q angle?
- angle between force vector of the quadriceps tendon and the force vector of the patella tendon
- women have a greater Q angle
what exacerbates the Q angle?
- a weak gluteus medius —> internal rotation of femur
- over pronation of ankle
management of patellofemoral pain syndrome?
- recovery
- gait analysis
- strengthening
- avoid running downhill and only uphill in recovery face
- orthotics don’t ultimately cure problem
- needs to not be a heel striker
- retrain to become a midfoot to forefoot striker to alleviate pressure to the heel and force transmission into the left leg and right leg — help running gait
what physical activity is recommended for everyone a week?
- 150 mins moderate intensity activity a week, with muscle strengthening activity at least 2 days a week
- minimise sedentary behaviour
what does the stance phase consist of?
- begins with a heel strike, when the heel hits the ground and begins to assume the body’s full weight (mid stance), and ends with a push off by the forefoot — a result of plantarflexion
what muscles are involved in heel strike?
tibialis anterior and gluteus maximus
what is the loading response?
- foot flat
- part of stance phase
what muscle is used in loading response?
quadriceps
what muscles are used in mid stance?
gluteus medius and minimus
function of titin?
- one end of the titin molecule is elastic and is attached to the Z disc, acting as a spring and changing length as the sarcomere contracts and relaxes
- the other part of the titin molecule tethers it to the myosin thick filament
