Introduction to Therapeutic Exercise: Difference between revisions

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* Eccentric strength must be greater than concentric strength<ref>Hollander DB, Kraemer RR, Kilpatrick MW, Ramadan ZG, Reeves GV, Francois M et al. Maximal eccentric and concentric strength discrepancies between young men and women for dynamic resistance exercise. J Strength Cond Res. 2007;21(1):34-40. </ref>
* Eccentric strength must be greater than concentric strength<ref>Hollander DB, Kraemer RR, Kilpatrick MW, Ramadan ZG, Reeves GV, Francois M et al. Maximal eccentric and concentric strength discrepancies between young men and women for dynamic resistance exercise. J Strength Cond Res. 2007;21(1):34-40. </ref>
* The eccentric load must be greater than what an individual can lift concentrically
* The eccentric load must be greater than what an individual can lift concentrically
{{#ev:youtube|gCyNj-Upbe4}}<ref>Corporis. Easiest Way to Remember Contraction Types: Concentric vs Eccentric vs Isometric | Corporis. Available from: https://www.youtube.com/watch?v=gCyNj-Upbe4 [last accessed 14/03/2022]</ref>


== Overload Principle ==
== Overload Principle ==

Revision as of 01:10, 14 March 2022

Original Editor - Jess Bell based on the course by Richard Jackson
Top Contributors - Jess Bell, Wanda van Niekerk and Kim Jackson
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Introduction[edit | edit source]

When considering exercise prescription in physiotherapy practice, it is important to understand the difference between therapeutic exercise and general exercise. General exercise is essentially a “work out”. It is exercise for wellness, overall health, appearance, fun, leisure etc.[1]

Therapeutic exercise is specifically for individuals who have a physical problem / impairment, which is often painful.[1]

“Therapeutic exercise is distinguishable from other forms of recreation because it is a purposeful, body-building activity, often prescribed by experts [...], drawing on their knowledge of bodily function to engage in a powerful form of anatomo-politics”.[2]

Rehabilitation professionals must be able to assess, analyse, and determine what is going on to cause a client’s pain or impairment. Exercises are then prescribed in order to address deficits in:[1]

  • Mobility / flexibility
  • Strength and power
  • Neuromuscular control
  • Muscular endurance

Why Include Therapeutic Exercise in a Treatment Plan?[edit | edit source]

Much research exists to support the use of exercise in clinical practice:[3][4][5][6]

  • Research supports the use of exercise intervention for long-term changes versus manual therapy alone
  • Exercise is supported over any other therapeutic intervention
  • Exercise interventions enable individuals to self-manage their symptoms[1]

Table 1 provides definitions for terminology often used when discussing therapeutic exercise.

Table 1. Therapeutic exercise terminology[1][7]
Term Definition
Exercise Rotating joints in specific ways to challenge muscles
Form A "topography of movement" or a specific manner of performing an exercise to maximise safety and ensure muscle strength gains
Repetition / rep A cycle of controlled lifting and lowering of a weight
Set Several repetitions performed in a row without a break
1 repetition maximum / 1RM The maximum weight that an individual can only lift once
Agonist Prime mover
Antagonist Opposite of an agonist, can control rapid movement eccentrically
Synergist Muscle(s) that stabilise(s) a joint around which movement occurs
Tempo The speed at which the exercise is completed; tempo affects the amount of weight that can be moved and the muscle

Tissue Damage, Pathogenesis, Pain and Performance[edit | edit source]

Injury and tissue damage causes a disruption in joint biomechanics:[1]

  • Pain from an injury or surgery results in a cascade of changes that can cause disruptions to the joint and, potentially, continual pain for years. This, in turn, leads to degenerative changes such as facet arthritis, accelerated annular degeneration, and nerve root irritation.
  • Tissue damage occurs when excessive stress / strain is applied to a tissue (i.e. the force exceeds the strength of the tissue).[8] Injury may occur after a single insult or from repeated loads.[1] Tissue damage leads to motor control problems, and subsequently long-term pain and degenerative changes.

Injures can also result in motor changes.[1] Research has shown that individuals who report significant low back pain experience changes in their motor control systems.[9][10]

The challenge is to train the stabilising system during steady-state activities and during rapid voluntary motions to withstand sudden surprise loads.[1] However, the presence of pain prevents the re-establishment of “healthy” motor patterns. And just as motor patterns are affected by injury, inappropriate motor patterns can also cause injury. Therefore, perturbed motor control systems both cause, and are a consequence of injury.[1]

There is, however, considerable evidence to support the use of therapeutic exercise as an intervention for musculoskeletal injury or pain.[11][12] It can improve:[1]

  • Range of motion, flexibility and mobility
  • Muscle activation
  • Neuromuscular coordination
  • Joint stability
  • Strength and power
  • Muscle endurance

Progression and Regression Design Principles[edit | edit source]

When prescribing exercises, it is important to understand how to progress and regress exercises. If patients are improving, exercises can be progressed. However, if they experience an increase in pain/symptoms, it may be necessary to alter certain parameters, including:[1]

  • Sets
  • Repetitions
  • Speed
  • Resistance

Phases of Exercise[edit | edit source]

  • Activation
    • Initially, it is necessary to determine if the patient can activate the muscle / is there a connection between muscle and brain?
  • Tissue healing
    • The phase of healing will have a significant impact on which exercises are given
  • Stabilisation
    • Joints are stabilised by the muscles
  • Mobility
    • As stability increases, range can be added
  • Muscle performance improvement
  • Advanced coordination and skill
    • Progressively add difficulty in movement patterns to restore normal functional abilities[1]

Teaching Methods for Exercise[edit | edit source]

  • Verbal cues
  • Mental imagery
  • Visual feedback
  • Manual cues[1]

The various cues used to assist motor learning are discussed in more detail here.

Types of Muscle Contraction[edit | edit source]

Types of muscle contraction are:[1][6][13]

  • Isotonic
    • Concentric (shortening)
    • Eccentric (lengthening)
  • Isometric
    • Static / holding
  • Isokinetic

Eccentric exercise:[1][14]

  • Negative force of a muscle contraction
  • Leads to muscle hypertrophy
  • Beneficial for tendons
  • Causes delayed onset muscle soreness
  • Should take no less than 4 seconds

Isometric exercise:[6]

  • Muscle contraction without any movement / change in muscle length

Concentric exercise:[1][14]

  • Positive force of a muscle contraction
  • Used to build endurance and increase tolerance to exercise
  • Should take no less than 3 seconds

Concentric vs eccentric:[1]

  • Eccentric strength must be greater than concentric strength[15]
  • The eccentric load must be greater than what an individual can lift concentrically

[16]

Overload Principle[edit | edit source]

In order to improve strength, increased load must be applied to a muscle. This will increase the muscle's capability. Progressively adding stress to the system means that it can adapt. It also prepares the body to do more in the future.[1]

[17]

Preparing the Patient[edit | edit source]

In order to prepare the patient for therapeutic exercise, please consider the following:[1]

  • Educate for success:
    • Discuss how to progress
    • Encourage them to keep going once they have finished therapy
  • Set expectations:
    • What is normal muscle soreness?
      • 24-48 hours
    • How often should exercises be performed?
    • How long will it take to make changes?
      • It takes 4-6 weeks to achieve physiological changes in the muscles
      • After beginning strength training, early increases in force production are associated with neural adaptations[18]
      • A patient may ‘feel’ stronger before 4-6 weeks have passed

Programme Design[edit | edit source]

Table 2 provides a summary of the traffic light system that can be used to determine exercise level.

Table 2. Traffic light system for therapeutic exercise[1]
Traffic Light Action
Red light
  • Movement hurts and may cause further injury
  • Pain before resistance
  • “Hands-off” approach or isometrics
Orange light
  • Movement does not hurt unless over pressure is applied
  • Pain at resistance
  • Treat with minumum to moderate manual techniques, exercise before
Green light
  • Pain after resistance
  • Decreased chance to cause further injury
  • Treat directly

General Principles[edit | edit source]

It is essential to target an exercise intervention and focus on the impairment (i.e. weakness versus sensorimotor or neuromotor deficit). Consider:[1]

  • Irritability and current level of function
  • Reps and sets scheme
  • Targeted impairment category
  • Progressions (necessary to see changes)

Neuromuscular Education[edit | edit source]

Sensorimotor control is defined as "afferent and efferent information streams, as well as the central processing of these two, contributing to joint stability."[19]

Sensorimotor impairment is associated with various musculoskeletal conditions, including neck pain,[19] hand disorders,[20] back pain,[21] etc.

Mechanisms for sensorimotor deficiency include:[22]

  • Impairments in the integration and processing of information in various parts of the sensorimotor system (e.g. sensory input, integration and processing in the central nervous system, motor output)
  • Neural inhibition is associated with pain, swelling, inflammation, joint laxity, and damage to the afferents of joints[23]
  • In knee pain, sensorimotor deficiencies have also been found in the non-injured leg:
    • This may be due to physical inactivity post-injury, reduced function, impaired sensory feedback from the injured joint[22]

For a detailed discussion of the sensorimotor system, please see this article, and figure 1 in particular: The sensorimotor system, part I: the physiologic basis of functional joint stability[24]

Neuromuscular Training[edit | edit source]

Neuromuscular training programmes have been found to be effective in improving function and reducing symptoms for various injuries.[25][26]

To improve sensorimotor control, it is beneficial to focus on closed kinetic chain exercises in a range of positions.[22]

Progress function through motor learning principles:[1]

  • Consider the type of practice (components, variety)
  • Closed to open chain; simple to complex

Progress function through movement:[1]

  • Frequency, intensity, duration
  • Endurance
  • Single- to multi-joint; closed to open

The process is as follows:[1]

  • Activation
  • Re-education
  • Motor learning
  • Functional movement training

Remember that:[1]

  • The core musculature is key to the movement of the extremities
  • The extremities are tied to the spine
  • The spine must be stable

Strength and Conditioning[edit | edit source]

Strength is defined as the amount of force that a specific muscle or muscle group can generate.[1]

Conditioning (endurance) is defined as the ability to “perform repetitive muscular contraction against some resistance for an extended period”.[27]

"Strength does not equal stability".[1]

Strength and endurance training have many benefits:[1]

  • Increased tissue vascularisation
  • Increased structural integrity of connective tissue
  • Improved lean muscle mass
  • Increased metabolic rate
  • Decreased body fat

Tolerance:[1]

  • Every individual has a tolerance for work
  • Tissues are damaged if their load tolerance is exceeded
  • Tolerance is lower in tissues that are already weakened by injury
  • Understanding each individual’s tolerance will assist in choosing the appropriate dosage / load for each stage of training

Capacity:[1]

  • Every individual has a capacity for work
  • Capacity is defined as “the sum total of all activities over a period of time”[1] (i.e. the maximum physical exertion that someone can sustain[28])
  • People use up a portion of their daily capacity with every task they perform, including warm-up activities, poor posture (sitting or standing)
  • Ideal training occurs when capacity and tolerance are increased together

Principles of Conditioning[edit | edit source]

  • Warm up / cool down
  • Motivation
  • Overload
  • Consistency
  • Progression
  • Intensity
  • Specificity
  • Individuality
  • Minimise stress[1]

SAID Principle[edit | edit source]

The Specific Adaptation to Imposed Demands (SAID) principle is a framework on which strength and conditioning programmes can be designed.[29]

  • All training is specific to a particular task
  • Specific skills or training may not be easily generalised or transferred to distinct activities[1]

Principles of Progression[edit | edit source]

Progressive overload:[1]

  • Increase or decrease difficulty with:
    • Reps
    • Sets
    • Speed
    • Complexity of exercise
    • Balance
    • Closed vs open chain
      • Best results come from both
      • Open to closed, closed to functional

Exercises can also be progressed by challenging the balance system:[1]

  • Unstable surfaces
  • Head-turning
  • Eyes closed
  • Visual distraction

More information on balance training is available here.

References[edit | edit source]

  1. 1.00 1.01 1.02 1.03 1.04 1.05 1.06 1.07 1.08 1.09 1.10 1.11 1.12 1.13 1.14 1.15 1.16 1.17 1.18 1.19 1.20 1.21 1.22 1.23 1.24 1.25 1.26 1.27 1.28 1.29 1.30 1.31 1.32 1.33 1.34 1.35 Jackson R. Therapeutic Exercise Course. Physioplus. 2022.
  2. Nicholls D, Jachyra P, Gibson BE, Fusco C, Setchell J. Keep fit: marginal ideas in contemporary therapeutic exercise. Qualitative Research in Sport, Exercise and Health. 2018;10(4):400-11.
  3. Maestroni L, Read P, Bishop C, Papadopoulos K, Suchomel TJ, Comfort P et al. The benefits of strength training on musculoskeletal system health: practical applications for interdisciplinary care. Sports Med. 2020;50(8):1431-50.
  4. Prall J, Ross M. The management of work-related musculoskeletal injuries in an occupational health setting: the role of the physical therapist. J Exerc Rehabil. 2019;15(2):193-9.
  5. Lin I, Wiles L, Waller R, Goucke R, Nagree Y, Gibberd M et al. What does best practice care for musculoskeletal pain look like? Eleven consistent recommendations from high-quality clinical practice guidelines: systematic review. Br J Sports Med. 2020;54(2):79-86.
  6. 6.0 6.1 6.2 Bielecki JE, Tadi P. Therapeutic Exercise. [Updated 2021 Sep 29]. In: StatPearls [Internet]. Treasure Island (FL): StatPearls Publishing; 2022 Jan-. Available from: https://www.ncbi.nlm.nih.gov/books/NBK555914/
  7. Wikipedia. Strength training. Available from: https://en.wikipedia.org/wiki/Strength_training (accessed 14 March 2022).
  8. Kalkhoven JT, Watsford ML, Impellizzeri FM. A conceptual model and detailed framework for stress-related, strain-related, and overuse athletic injury. Journal of Science and Medicine in Sport. 2020;23(8):726-34.
  9. Van Dieën JH, Reeves NP, Kawchuk G, van Dillen LR, Hodges PW. Motor control changes in low back pain: divergence in presentations and mechanisms. J Orthop Sports Phys Ther. 2019;49(6):370-379.
  10. Meier ML, Vrana A, Schweinhardt P. Low back pain: the potential contribution of supraspinal motor control and proprioception. Neuroscientist. 2019;25(6):583-96.
  11. Bailey DL, Holden MA, Foster NE, Quicke JG, Haywood KL, Bishop A. Defining adherence to therapeutic exercise for musculoskeletal pain: a systematic review. Br J Sports Med. 2020;54(6):326-31.
  12. Babatunde OO, Jordan JL, Van der Windt DA, Hill JC, Foster NE, Protheroe J. Effective treatment options for musculoskeletal pain in primary care: A systematic overview of current evidence. PLoS One. 2017;12(6):e0178621.
  13. Padulo J, Laffaye G, Chamari K, Concu A. Concentric and eccentric: muscle contraction or exercise? Sports Health. 2013;5(4):306.
  14. 14.0 14.1 Hody S, Croisier JL, Bury T, Rogister B, Leprince P. Eccentric muscle contractions: risks and benefits. Front Physiol. 2019;10:536.
  15. Hollander DB, Kraemer RR, Kilpatrick MW, Ramadan ZG, Reeves GV, Francois M et al. Maximal eccentric and concentric strength discrepancies between young men and women for dynamic resistance exercise. J Strength Cond Res. 2007;21(1):34-40.
  16. Corporis. Easiest Way to Remember Contraction Types: Concentric vs Eccentric vs Isometric | Corporis. Available from: https://www.youtube.com/watch?v=gCyNj-Upbe4 [last accessed 14/03/2022]
  17. National Council on Strength and Fitness. What is Overload, Progression & Specificity. Available from: https://www.youtube.com/watch?v=TocsLwo7l9A [last accessed 14/03/2022]
  18. Škarabot J, Brownstein CG, Casolo A, Del Vecchio A, Ansdell P. The knowns and unknowns of neural adaptations to resistance training. Eur J Appl Physiol. 2021;121(3):675-85.
  19. 19.0 19.1 De Zoete RMJ, Osmotherly PG, Rivett DA, Snodgrass SJ. Seven cervical sensorimotor control tests measure different skills in individuals with chronic idiopathic neck pain. Braz J Phys Ther. 2020;24(1):69-78.
  20. Röijezon U, Faleij R, Karvelis P, Georgoulas G, Nikolakopoulos G. A new clinical test for sensorimotor function of the hand – development and preliminary validation. BMC Musculoskelet Disord. 2017;18:407.
  21. Goossens N, Rummens S, Janssens L, Caeyenberghs K, Brumagne S. Association between sensorimotor impairments and functional brain changes in patients with low back pain: a critical review. Am J Phys Med Rehabil. 2018;97(3):200-11.
  22. 22.0 22.1 22.2 Ageberg E, Roos EM. Neuromuscular exercise as treatment of degenerative knee disease. Exerc Sport Sci Rev. 2015;43(1):14-22.
  23. Rice DA, McNair PJ. Quadriceps arthrogenic muscle inhibition: neural mechanisms and treatment perspectives. Semin Arthritis Rheum. 2010;40(3):250-66.
  24. Riemann BL, Lephart SM. The sensorimotor system, part I: the physiologic basis of functional joint stability. J Athl Train. 2002;37(1):71-9.
  25. Zech A, Hubscher M, Vogt L, Banzer W, Hansel F, Pfeifer K. Neuromuscular training for rehabilitation of sports injuries: a systematic review. Med Sci Sports Exerc. 2009;41(10):1831-41.
  26. Taulaniemi A, Kankaanpää M, Tokola K, Parkkari J, Suni JH. Neuromuscular exercise reduces low back pain intensity and improves physical functioning in nursing duties among female healthcare workers; secondary analysis of a randomised controlled trial. BMC Musculoskelet Disord. 2019;20(1):328.
  27. Prentice WE. Regaining muscular strength, endurance, and power [Internet]. Musculoskeletal Key. 2021 [cited 13 March 2022]. Available from: https://musculoskeletalkey.com/regaining-muscular-strength-endurance-and-power/
  28. Goldstein RE. Exercise Capacity. In: Walker HK, Hall WD, Hurst JW, editors. Clinical Methods: The History, Physical, and Laboratory Examinations. 3rd edition. Boston: Butterworths; 1990. Chapter 8. Available from: https://www.ncbi.nlm.nih.gov/books/NBK404/
  29. Johnson AM, Sandage MJ. Exercise science and the vocalist. J Voice. 2021;35(4):668-77.
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