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Restoring ROM & Improving Flexibility

Restoring ROM & Improving Flexibility. Chapter 8. Importance of Flexibility. Important Goal: Restore or improve to normal pre-injury range of motion With injury there is generally some degree of lost range of motion

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Restoring ROM & Improving Flexibility

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  1. Restoring ROM & Improving Flexibility Chapter 8

  2. Importance of Flexibility • Important Goal: Restore or improve to normal pre-injury range of motion • With injury there is generally some degree of lost range of motion • Due to pain, swelling, muscle guarding, &/or inactivity resulting in tissue shortening • Need to encourage stretching exercises • Restricted range of motion can impact performance & result in uncoordinated motion • Essential for successful physical performance & injury prevention

  3. Flexibility • Ability of neuromuscular system to allow for efficient movement of a joint or series of joint through a full, non-restricted pain free range of motion

  4. Flexibility • Flexibility refers to the total range of motion (ROM) of a joint or group of joints. • The ability of a joint to move freely through the full range of motion. • It differs from person to person and from joint to joint. • What affects the extent of movement around a given joint? • Structural characteristics of the joint • Mechanical properties of the connective tissues

  5. Flexibility • The GOAL should be to optimize joint mobility while maintaining joint stability. • Primary FOCUS should be on the systematic, safe and effective application of the range of motion techniques used. • You should be able to communicate to the client WHY they should devote time to improving flexibility • It will enhance their program.

  6. Flexibility • Keep the requirements of the activity in mind • A person’s activity level alone will not improve flexibility • Stretching exercises are essential if flexibility is to be maintained or increased

  7. Anatomic Factors Impacting Flexibility • Muscles • Increasing flexibility relies on the elastic properties of muscle • Length can be changed over time • Connective Tissue • Ligaments & joint capsules, while possessing some elastic properties, can lose their elasticity during periods of disuse & immobilization • Bony Structures • Can limit end point range • Bony prominences can also stop movements at normal end points in the range • Fat • Can act as a wedge between lever arms • Restricts movement wherever it is found

  8. Skin • Injury or surgical procedure may alter skin – variable in elasticity • Skin adheres to underlying tissue • Neural tissue • Develops tightness as a result of compression, chronic repetitive microtrauma, muscle imbalances, joint dysfunction or morphological adaptations due to posture • Could stimulate nociceptors & pain • Cause muscle guarding & spasm to protect irritated neural structures • Neural fibrosis ultimately results causing decreased elasticity & restricted motion • Except for bone structure, age & gender all other flexibility limiting factors can be modified & altered to increase range of motion

  9. Soft Tissue Properties that Affect Immobilization & Elongation • Responses that affect soft tissue during stretching • Velocity, intensity, frequency & duration of stretch force • Temperature of tissues • Elasticity – ability of soft tissue to return to its resting length after passive stretch • Plasticity– tendency of soft tissue to assume a new & greater length after stretch force has been removed

  10. Soft Tissue Properties that Affect Immobilization & Elongation • Contractile tissue: gives muscle characteristics of contractility & irritability • Noncontractile tissue: has same properties as all CT, including ability to resist deforming forces as well as viscoelasticity • CT structures of muscle-tendon unit • Epimysium – enveloping fascial sheath • Perimysium – encases bundles of fasciculi • Endomysium – innermost layer that separates individual m. fibers & myofibrils

  11. Benefits of Flexibility Training • Increases Range of Motion • Reduction of lower back pain and injury • Reduction in the incidence & severity of injuries • Improved posture & muscle symmetry • Delay in the onset of muscular fatigue • Prevents or alleviates muscle soreness post exercise • Increases the level of certain skills & muscular efficiency • Picking something up off the floor • Promotes mental relaxation

  12. Flexibility • It must be based upon the needs of the client. • Deliberate stretching should be done AFTER a general warm-up, but BEFORE the primary bout BUT…. • It is dependant upon the activity to be performed. • Stair climbing vs. Basketball

  13. General Warm Up • Full body rhythmic activities • Low-moderate intensities • ~ 5 minutes • Increase core temp • Should not lead to fatigue

  14. Specific Warm Up • Specific warm up for the activity • ~ 10 minutes

  15. Factors Affecting Flexibility • Joint Structure • Age • Gender • Muscle & Connective Tissue • Exercise History • Temperature • Resistance Training • Pregnancy

  16. Joint Structure • Joint Structure • Some joints allow more range than others

  17. Age & Gender • Young more flexible than older • Females more flexible than men • Youth become less flexible between ages 10-12 • Childhood is the ideal time to start a flexibility program • Seniors lose flexibility due to inactivity

  18. Muscle & Connective Tissue • Tendons, ligaments, fascia, joint capsules, skin • Elasticity – the ability to return to original resting length after passive stretch • Plasticity – the tendency to assume a new and greater length after passive stretch • Hyperlaxity – allows the joints to achieve a ROM that exceeds the normal range of motion

  19. Active & Passive Range of Motion • Active range of motion (AROM) • Dynamic flexibility • Joint movement via muscle contraction • Ability to move a joint with little resistance • Passive range of motion (PROM) • Static flexibility • Motion of joint to end points without muscle contraction • Critical in injury prevention • Muscles can be forced to stretch beyond “normal” limits • Without elasticity it is likely that the musculotendinous unit will be injured • During athletic activity • Must be able to move through unrestricted range • Must have elasticity for additional stretch encountered during activity

  20. Measuring Range of Motion • Essential to assess improvement during rehabilitation • Goniometer • Utilizes alignment of two arms parallel to longitudinal axis of two segments involved in motion • Relatively accurate tool • Ensures accuracy standardize techniques & methods of recording AROM & PROM

  21. Agonist vs. Antagonist Muscles • Joints are capable of multiple movements • Example: • Quadriceps will extend knee with contraction • Quads (muscle producing movement) = agonist • Hamstrings will stretch during knee extension • Hamstrings undergoing stretch = antagonist • Agonist & antagonist work together to produce smooth coordinated movements • Muscles that work together function synergistically • What is another pair of agonist/antagonist muscles?

  22. Stretching Strategies • 2 times per week, for 5 weeks, has been shown to improve flexibility • Varies depending upon the sport / activity • General warm up for ~ 5 minutes • Activity specific warm up ~ 10 minutes • Post activity stretching ~ 5 minutes • Hold each stretch for about 30 - 60 seconds • Do 3 - 4 reps

  23. Proprioceptors & Stretching • Muscle Spindles • Within muscle • Causes stretch reflex • Muscle contracts when stretch too fast • Golgi Tendon Organs • MT Junction • Produces inverse stretch reflex • Relaxes muscle when there is too much tension

  24. Types of Stretching • Static – slow & steady • Ballistic - bouncing type movements • Dynamic– avoids bouncing but includes movements specific to the activity • PNF – generally involves a 10 second passive stretch followed by the specific technique: • Hold-Relax • Contract-Relax

  25. Static Stretching • Most commonly used • Safe & effective • Muscle gradually stretched to the point of mild tension • If discomfort is felt, back off a little • Does not activate the stretch reflex • Beginners should hold the stretch for 15-20 s; progress to 30 s • Longer holds do not reap more rewards • Significant improvements can occur • Repeat 3-5 times

  26. Ballistic Stretching • Rapid, jerky, uncontrolled movement • Difficult to control the motion • Higher risk of injury • No longer considered acceptable however, is appropriate for some activities • Disadvantages: • Increased danger of exceeding the extensibility limits of involved tissues • Higher energy requirements • Greater chance of causing muscle soreness • Activation of the stretch reflex

  27. Dynamic Stretching • Similar to ballistic but avoids bouncing • Puts an emphasis on functionally based movements • Includes movements specific to the activity • Example  lunge walk • Requires balance and coordination • Clients may experience muscle soreness initially

  28. PNF Stretching • Widely accepted as an effective method for increasing range of motion • Performed with a partner • Uses both passive movement & active muscle action • Technique: • Take the muscle into a static stretch while relaxing muscle • Hold stretch for 10 s, then contract muscle for 6 s with a strong isometric contraction against partner • Following a 1-2 s rest, repeat another 30 s passive stretch • Repeat

  29. Proprioceptive Neuromuscular Facilitation • Three techniques that combine alternating isometric or isotonic contractions & relaxation of both agonist & antagonists • Slow-reversal-hold-relax • Contract-relax • Hold-relax • Hold Relax (HR) • Isometric contraction of antagonist followed by concentric contraction of agonist with light pressure • Facilitates stretch of antagonist • Effective with muscle tension on one side of joint

  30. Contract Relax (CR) • Moves body passively into agonist pattern • Athlete instructed to contract antagonist isotonically against resistance • Athlete then relaxes & allow athletic trainer to push body further (passively) into agonist pattern • Utilized when flexibility is limited due to muscle tightness • Slow Reversal-Hold-Relax (SRHR) • Isotonic contraction of agonist • Follow with isometric contraction of antagonist • During relax phase antagonist is relaxed while agonist contracts in agonist pattern • Results in stretch of antagonist • Useful to stretch antagonist

  31. Comparing Stretching Techniques • Ballistic stretching is recommended for athletes engaged in dynamic activity • Static stretching most widely used • Safe & effective • PNF techniques • Capable of producing dramatic increases in ROM • Limitation – partner is required • Maintaining flexibility • Can decrease considerable after only 2 weeks • Should be engaged in at least once per week

  32. Specific Stretching Exercises

  33. Stretching Neural Structures • Requires differentiation between musculotendinous & neural tightness • Assess movements that create tension in neural structures • May cause numbness & tingling • Straight-leg raise example

  34. Myofascial Release Stretching • Techniques used to relieve abnormally tight fascia • Myofascial restrictions are unpredictable & may occur in different planes & directions • Requires specialized training & in depth understanding of fascial system • Fascia • Connective tissue that runs throughout the body & establishes interconnectedness of body • If altered or injured can result in localized response at focal point of injury or away from injury site • Responds to gentle pressure

  35. Sometimes called: Soft-tissue Mobilization • Treatment • Localize restriction • Considerably more subjective component & relies heavily on clinician’s experience • Focuses on large treatment area • Work superficial to deep • Joint mobilizations may follow • Tissue stretching & elongation as well as strengthening should follow • Postural re-training may also be required • Dramatic results may occur • Treatment should be done at least 3 times per week • Perform manually or via foam roller

  36. Neurophysiological Basis of Stretching Stretch Reflex • Muscle is placed on stretch – muscle spindle • Muscle spindles fire relaying info. to spinal cord • Spinal cord relays message to golgi tendon & increases tension • After 6 seconds, golgi tendon organ (GTO) relays signal for muscle tension to decrease • Cause reflex relaxation • Prevents injury - protective mechanism • Ballistic stretching does not allow this overriding response by GTO

  37. With static stretching GTO’s are able to override impulses from muscle spindle following initial reflex resistance • Allows muscle to remain stretched without injury • PNF benefits greatly from these principles • With slow-reversal hold technique, maximal contraction of muscle stimulates GTO reflex relaxation before stretch applied

  38. Autogenic inhibition • Relaxation of antagonist during contraction • During relaxation phase, antagonist is placed under stretch but assisted by agonist contraction to pull further into stretch • GTO is protective mechanism that inhibits tension in the muscle • Reciprocal inhibition • Isotonic contraction of an agonist muscle elicits a reflex relaxation of antagonist muscle group - (protect against injury)

  39. Effect of Stretching on Physical & Mechanical Properties of Muscle • Physical lengthening of muscle occurs due to reflex relaxation • Contractile & non-contractile elements of muscle dictate capability of deformation & recovery • Both resist deformation • Deformation is dependent on degree of stretch & velocity • Non-contractile – limit degree • Contractile – limit velocity • Greater stretch = more non-contractile components contribute

  40. Stretches sustained long enough (autogenic inhibition) result in viscoelastic & plastic changes in collagen & elastin • Viscoelastic changes allow slow deformation & imperfect recovery (not permanent) • Plastic changes result in permanent changes in length • Greater velocity = greater chance for exceeding tissue capacity (viscoelastic & plastic)

  41. Effects of Stretching On Kinetic Chain • Joint hypomobility causes: • Faulty posture • Muscular imbalance • Abnormal neuromuscular control • Alteration in arthrokinematics • Change in muscle tension to reduce translation • Alters degrees of tension & activation in synergist, stabilizers & neutralizers • Compensatory response

  42. Impact on length-tension relationships Alters force couples & arthrokinematics Impacts normal force couple relationships & creates kinetic chain reaction Impacts synergistic function of kinetic chain Causes abnormal joint & tissue stresses, neural compromise & vascular/lymphatic stasis Alters recruitment strategies & stabilization Alters neuromuscular efficiency impacting activation/firing sequence Additionally altered joint function & stress response Can causes reciprocal inhibition Increases muscle spindle activity May impart inhibitory response (decreased neuromuscular control) Result = synergistic dominance – synergist compensatory action for weak & inhibited muscle Muscle Tightness & Hypertonicity

  43. Importance of Warm-up Prior to Stretching • Intramuscular temperature should be increased prior to stretching • Positive effect on ability of collagen & elastin to deform • Enhances reflexive relaxation associated with golgi tendon organs • Optimal temperature 39oC/103oF • To increase = low intensity, warm-up type exercise or modalities • Exercise should be primary means of warm-up • Environment - Heat vs. Cold

  44. Flexibility vs. Strength • Co-exist • Muscle bound • Negative connotation • Loss of motion • Encourage full pain free movements during rehabilitation • Strength training will provide individual with ability to develop dynamic flexibility through full range of motion • Develop more powerful & coordinated movements

  45. Warm-up Overload or stretch beyond normal range Not to point of pain Stretch to point of resistance Increases in range will be specific to muscle being stretched Use caution when stretching around painful joints Avoid overstretching ligaments & capsules Exercise caution with low back & neck stretches Stretch from seated position to reduce stress on back Continue normal breathing while stretching For improvements in ROM, utilize static & PNF stretching techniques Ballistic stretching should be used by those who possess flexibility & are accustomed to it Ballistic stretching should follow period of static stretching Stretching should be performed a minimum of 3 times per week For maximum gains stretching 5-6 times per week is ideal 5-10 second stretch prepares muscles for activity, 30-60 second stretch increases flexibility. Guidelines & Precautions for Stretching

  46. Summary • Assess client’s flexibility to pinpoint strengths & weakness • Design program that stretches the specific muscles used by the client during activity • Warm up before stretching to increase temp • Perform stretches daily • Stretch all major muscle groups and opposing groups

  47. Summary • Focus on technique during the stretch • Hold stretches for 30 seconds initially; later 60 seconds • Do 4 reps each stretch for optimal gains • Stretch to mild discomfort, not pain • Keep breathing slow and rhythmical during stretch • Stretch muscles in different positions and planes • Stretch after primary bout

  48. Neck Shoulders & Chest Torso Upper Back Lower Back Hips Posterior Arm Anterior Thigh & Hip Flexor Posterior Thigh Adductors “Groin” Calf Stretching Body Regions

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