Muscle locomotion in locomotion Flashcards
What is force?
Load, resistance, stress
What are requirements for terrestrial locomotion?
Move body centre of mass (COM)
Support body weight against gravity, should be as stable and economical as possible
Move limbs into position for stance
How do Newton’s laws relate to motion and forces?
Gravity exerts a downward accleration (constant) 9.81 ms-2 - force is proportional to mass x gravity (mg)
- To remain standing up, the legs must exert a balanced force upwards
- F vertical = mg + F legs = 0
- F legs = - Mg - When legs push against the ground, the ground pushes back - ground reaction force (GRF or F or G)
How do we measure F?
Measured by a force plate
- push down = vertical force
- push up = horizontal force
- vector sum = resultant force
What role to ground reaction forces play in steady locomotion?
Average vertical force must support bodyweight
- average Fv = mass x gravity
More legs that are on the ground = lower force per leg
Horizontal (fore-aft) forces average zero to maintain average speed
- average Fk =Ma = zero
How do forces vary with speed and gait?
Peak force increases with speed as duration of contact (tc) decreases
Magnitude of peak force 𝛂1/tc
What is the average force that a horses front limbs experience?
Walk ~ 0.5 x body weight
Trot ~ 1 x body weight
Canter ~ 2.5 x body weight
How do the GRF and limb posture determine the required muscle force and work?
Muscles contract to resist these locomotor forces
- to do this they must produce work & power to move the limb at an appropriate speed
Work = force x displacement, required work to move mass
Power = work/time, requires power to do work quickly
What does a muscle do?
Produces force (in tension only) - contraction means generate force Produces movement Muscles do not flex they contract - joints flex and extend
What are the three possible motions of muscle during “contraction”?
Shortening = positive work, most energetically expensive Isometric = no work, contract to resist load, cost proportional to force Lengthening = negative work, most economic but also most likely to leave muscle injury
How does muscle function relate to it’s anatomy?
- muscle cells (fibres) are made from sarcomeres in series (end-to-end)
- muscle tissue is made from fibres arranged in parallel (side-by-side)
- musculoskeletal level systems, trade-off between force and displacement
- work = force x distance, for the same work:
- large force, small distance
- small force, large distance
What is the moment arm?
Fout = output side where you want to move a mass
Fin = input side where muscles act
Force x moment arm = torque, balance on to sides of the joint
- Fin x r = Fout x R, Torque in = Torque out
- push down (small force input), effective mechanical advantage : r/R
What is a musculoskeletal lever system?
Muscle force required to resist ground reaction force (Fg) - force x distance balance on two sides of the joint
- Fmuscle x r = Fg x R, Fmuscle = Fg x (R/r)
- Fg = Fmuscle x (r/R)
What is the effective muscle advantage?
EMA = r/R
If R decreases EMA increases, resulting in lower muscle force required to support Fg but also less speed and foot displacement
What is the relationship between EMA and R?
If R decreases EMA increases, resulting in lower muscle force required to support Fg but also less speed and foot displacement
