1 / 21

Muscular Function Assessment

Muscular Function Assessment. Gallagher - OEH ch 21 Muscle strength is a complex function that can vary with the methods of assessment Garg - A comparison of isokinetic lifting strength - speed and box size Wolf - relationships between grip strength work capacity and recovery OUTLINE

joefisher
Télécharger la présentation

Muscular Function Assessment

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Muscular Function Assessment • Gallagher - OEH ch 21 • Muscle strength is a complex function that can vary with the methods of assessment • Garg - • A comparison of isokinetic lifting strength - speed and box size • Wolf - • relationships between grip strength work capacity and recovery • OUTLINE • Definitions and introduction • Assessment methods • Variables impacting performance • Recovery of performance

  2. Muscle Function • Gallagher • Strength - capacity to produce a force or torque with a voluntary muscle contraction • Power - Force * distance * time-1 • Endurance -ability to sustain low force requirements over extended period of time • Measurement of human strength • Cannot be measured directly • interface between subject and device influences measurement • Fig 21.1 Biomechanical eg. • Q = (F * a)/b or c or d • force from muscle is always the same • results are specific to circumstances • dynamic strength - motion around joint • variable speed - difficult to compare • static or isometric strength- no motion • easy to quantify and compare • not representative of dynamic activity

  3. Factors Affecting Strength • Gender • Age • Anthropometry • Psychological factors - motivation • table 21.1 • Task influence • Posture • fig 21.2 angle and force production • Duration • Fig 21.3 • Velocity of Contraction • Fig 21.4 • Muscle Fatigue • Static vs dynamic contractions • Frequency and work / rest ratio • Temperature and Humidity • inc from 20-27 C - dec 10-20% in capacity

  4. Strength Testing (intro) • Isometric strength testing • standardized procedures • 4-6 sec, 30-120 sec rest • standardized instruction • postures, body supports, restraint systems, and environmental factors • worldwide acceptance and adoption • Dynamic strength • isoinertial (isotonic)- mass properties of an object are held constant • Psychophysical - subject estimate of (submax) load - under set conditions • isokinetic strength • through ROM at constant velocity • Uniform position on F / V curve • Standardized • Isolated muscle groups

  5. Strength testing • Testing for worker selection and placement • Used to ensure that worker can tolerate physical aspects of job • similar rates of overexertion injuries for stronger and weaker workers • Key principles • Strength test employed must be directly related to work requirements • must be tied to biomechanical analysis • Isometric analysis fig 21.5 • for each task - posture of torso and extremities is documented (video) • recreate postures using software • values compared to pop. norms • industrial workers • estimate % capable of level of exertion • predict forces acting on lumbar spine

  6. Isometric Considerations • Discomfort and fatigue in isometrics thought to result from ischemia • Increasing force, increases intramuscular pressure which approaches then exceeds perfusion pressure - lowering then stopping blood flow • Partial occlusion at 20-25% MVC • Complete occlusion above 50% MVC • Fig 15-19 Astrand • Max hold time affected by % of MVC • Recommend less than 15% for long term requirements • Fig 15-20 Astrand • With repeated isometric contractions a combination of Force and Frequency determine endurance • Optimal work / rest ratio of 1/2 • Frequency important as well (Astrand)

  7. Isoinertial Testing • Consider - biomechanics and grip • Stabilization requirements • justification of cut off scores • Examples from industry • SAT - strength aptitude testing • air force standard testing • Pre-selected mass - increase to criterion level - success or failure • found incremental weight lifted to 1.83m to be best test as well as safe and reliable • PILE - progressive inertial lifting evaluation • lumbar and cervical lifts -progressive weight - 4 lifts / 20 seconds • standards normalized for age, gender and body weight • variable termination criteria • voluntary, 85 % max HR, 55-60% body weight

  8. Psychophysical testing • psychophysical methods • workers adjust demand to acceptable levels for specified conditions • provides ‘submax’ endurance estimate • Procedure - • subject manipulate one variable-weight • Either test : starting heavy or light • add / remove weight to fair workload • Fair defined as : without straining, becoming over tired, weakened, over heated or out of breath • Study must use large number’s of subjects • evaluate / design jobs within determined capacities by workers • 75% of workers should rate as acceptable • If demand is over this acceptance level; 3 times the injury rate observed to occur

  9. Psychophysical (cont) • Summary • Table 21.2 (Snook and Cirello) • Advantages • realistic simulation of industrial tasks • very reproducible - related to incidence of low back injury • Disadvantages • results can exceed “safe” as determined through other methodology • biomechanical, physiological

  10. Isokinetic Testing • Isokinetic testing • Evaluates muscular strength throughout a range of motion at a constant velocity • Consider - velocity, biomechanics • However; • humans do not move at constant velocity • isokinetic tests usually isolated joint movements • may not be reflective of performance ability • Redesign of isokinetic testing • multi joint simulation tasks for industry • fig 21.8 • Better, as they require core stabilization • still in development, therefore limited validity

  11. Comparing Isokinetic Strength (Garg) • Goal of research • determine effects of speed of lifting and box size on isokinetic strength • compare isokinetic with • static lifting strength • psychophysically determined maximal acceptable weight (MAW) • Relevance of Research • Measurement of human strength is important for job design • Important to match physical strength requirements with worker capabilities to prevent injury • Measurement of dynamic strength is complex • Isokinetic strength is commonly used to measure dynamic strength • The use of boxes instead of a bar is a better simulation of actual lifting tasks

  12. Methods • 9 male college students - range in age 22-36 (table 1) • 12 lifts per hour (every 5 minutes) • lift floor to bench (.8 m) • 3 box sizes 25 - 50 cm wide • open technique - subjects choice ** • Measure MAW, static strength, isokinetic strength • MAW - adjust weight till comfortable • Static measured at origin of lift • Isokinetic evaluated at 3 speeds • RPE on low back evaluated for all lifts

  13. Results • Progressive decline in mean and peak isokinetic strength • with inc speed and inc box width • Fig 1 and 2 • speed had greater impact than width • Recommend lifting slowly • However, high speed lifting perceived to be less stressful • RPE 10.7 (fast) vs 12.7 (slow) • Fig 3 • static strength and MAW higher correlation with mean than peak isokinetic strength • high speed - mean isokinetic - within 6% of MAW • low speed - mean - equal to mean static strength • Fig 4

  14. Recommendations • recommend • both speed of lifting and box width should be controlled carefully • using MAW and Static strength testing • Static testing results in higher allowable limits for workers • MAW - effectiveness not yet as well documented • the complexities of isokinetic strength testing and its relationship to safe lifting capability are not fully understood

  15. Grip Strength, Work Capacity and Recovery • Wolf • Investigates relationships between strength, fatigue and work capacity that are central to occupational rehabilitation • Musculoskeletal impairments are often expressed as loss of strength • % disability • correlation between strength and endurance is greater than .90 • endurance tests • often assess repetitions to failure using a % of body weight • strength test often use one rep max (isotonic) ; not always appropriate • 1 RM= (weight) / [1- (RM * .02)]

  16. Grip Strength, Work Capacity and Recovery • questions in paper • how important is strength as a component of work capacity? • how do work capacity and strength affect recovery time? • Relevant research • Capacity to sustain work activity is inversely related to power required • exponential decrease in endurance, as demand approaches max • Walsh (Fig 1 and 2) • after injury - loss of power leads to loss of capacity • rest from injury - often increases impact due to muscular de-conditioning

  17. Background • Rehabilitation • strengthen and condition worker to improve capacity • Various programs (functional restoration, work conditioning, work hardening) • Often difficult to establish and define dose of intervention precisely • The goal is to accelerate the rate of rehab and shorten treatment time • Physical training goals in the workplace are different from those ot athletes • Athlete: improve capacity to enhance performance • Worker: improve capacity to minimize the risk of injury and reduce the strain of performing tasks

  18. Background • Prediction equations for muscular endurance at a given % of max contraction - constants for each muscle group (Sato) • results 10-35 % decline in strength • longer bout, lower recovery strength • Fatigue - theory • short - high intensity exercise - metabolic inhibition • longer duration - fatigue may be at level of E-C coupling - ? K+ ? • Relevance of isometric evaluation • low - due to low prevalence of isometric activity • Greater relevance for hand

  19. Relationships • Research goals of Wolf study • develop technology necessary to support a treatment strategy • dose of exercise is able to be closely tied to expected levels of recovery • Address issues of ; • expected work duration and capacity • and recovery rates • Methods- 40 healthy subjects-1/2 male • Standard body position and instructions • Measure isometric and isotonic max’s • Repetitive isotonic gripping task at 25, 50 and 75 % of pre-trial max to failure • measure isometric grip strength after 1, 5 10 and 20 min of recovery • Take average of three trials • Plot recovery rates of return to max strength

  20. Results • correlation between isometric and isotonic strength maximums (.63) • poor correlation between isometric or isotonic strength and duration (time) of work at either 75 or 50 % • strong relationships between isotonic strength and work capacity (strength * time) at 75 and 50% levels (>.8) • Isotonic strength best predictor of work capacity at 75 % level - • When compared with duration • Work duration and isotonic strength had a similar predictive ability fro work capacity at the 50% resistance

  21. Recovery Results • No significant gender differences • either for recovery time or % at any time points • table III and fig 1 • Recovery rate and time to recovery • subjects categorized based on their time to reach 100% • significant differences in initial degree of recovery Fig 2 after fatigue • no differences in rate • similar slope, different starting points - • Rate of recovery, therefore related to degree of initial strength loss (%) • This is therefore a good predictor of length of recovery (time) • Healthy standards - avg 20% decline in strength with protocol - 20 min recovery • variation - abnormal - intervention • standards - tables 4 and 5

More Related