Forces in Rehabilitation: Difference between revisions
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=== Tension Force === | === Tension Force === | ||
* Forces are oriented primarily in opposite directions | * Forces are oriented primarily in opposite directions<ref>Matsumoto T, Nagayama K. Tensile properties of vascular smooth muscle cells: Bridging vascular and cellular biomechanics. Journal of Biomechanics. 2012 Mar 15;45(5):745-55. doi: 10.1016/j.jbiomech.2011.11.014.</ref> | ||
* Tension stimulates muscle, tendon, ligament and in some cases neurological tissue. | * Tension stimulates muscle, tendon, ligament and in some cases neurological tissue. | ||
* Overload with “tension” leads to sprains, strains and in some cases peripheral nerve injury. | * Overload with “tension” leads to sprains, strains and in some cases peripheral nerve injury. | ||
* Examples: hamstring tear, patellar tendonopathy, brachial plexopathy, MCL tear. Insufficient loading leads to muscle atrophy, and weak ligaments and tendons for example. | * Examples: hamstring tear, patellar tendonopathy, brachial plexopathy, MCL tear. Insufficient loading leads to muscle atrophy, and weak ligaments and tendons for example. | ||
=== Gravitational force === | |||
* Gravitational forces exerted on the human body influence biomechanical responses during various activities, such as standing, walking, and jumping | |||
* it play a significant role in postural control, as the body continuously adjusts its orientation and center of mass to maintain stability against the pull of gravity <ref>Winter, D. A. (1995). Human balance and posture control during standing and walking. Gait & posture, 3(4), 193-214.</ref> | |||
* it affect gait patterns by influencing the distribution of forces and moments across joints during locomotion, impacting walking efficiency and stability <ref>Mills, P. M., & Barrett, R. S. (2017). Methodological factors affecting joint moments estimation in clinical gait analysis: a systematic review. BioMedical Engineering OnLine, 16(106). <nowiki>https://doi.org/10.1186/s12938-017-0375-5</nowiki></ref> | |||
* also contributes to musculoskeletal loading during weight-bearing activities, influencing bone density, muscle activation patterns, and joint loading <ref>Judex, S., & Carlson, K. J. (2009). Is Bone’s Response to Mechanical Signals Dominated by Gravitational Loading? Medicine & Science in Sports & Exercise, 41(11), 2037-2043. <nowiki>https://doi.org/10.1249/MSS.0b013e3181a8c931</nowiki></ref> | |||
* Understanding gravitational forces is essential for designing [[Elderly Mobility Scale|interventions to prevent falls]] in older adults and individuals with [[Balance|balance impairments]], as minimizing the effects of gravity on postural stability can reduce fall risk <ref>Rubenstein, L. Z. (2006). Falls in older people: epidemiology, risk factors and strategies for prevention. Age and ageing, 35(Supplement_2), ii37-ii41.</ref> | |||
== Resources == | == Resources == | ||
[[Category:Biomechanics]] | [[Category:Biomechanics]] | ||
Revision as of 17:56, 22 April 2024
Original Editor - Alicia Fernandes Top Contributors - Alicia Fernandes, Vidya Acharya, Olajumoke Ogunleye, Carina Therese Magtibay and Kim Jackson
Introduction[edit | edit source]
A force is a push or pull acting upon an object as a result of its interaction with another object.
Types of Force[edit | edit source]
- Internal Force: This type of force originates from actions occurring within the object itself. Examples include the contraction and relaxation of muscles, such as those involved in walking, and the pulling of muscles at their attachments to the human body.[1]
- External Force:External force is exerted on an object by an external agent. Examples include kicking a football, throwing a javelin, or pushing a rug. External force can be further classified into two categories:
- Contact Forces: These forces involve direct contact with the object and are required to change its position. Examples include pushing, pulling, tension, compression, hitting a tennis ball, or trapping a soccer ball.
- Non-contact Forces: Non-contact forces do not require physical contact with the object. Examples include magnetic forces, which attract metallic materials to a magnet, and gravitational forces, which attract objects to the Earth's surface or to each other. These forces, also known as force fields or attraction forces, influence human movement.[1]
It's important to note that not all forces induce or alter motion. For a change in position to occur, the applied force must exceed both the weight of the object and any frictional forces acting upon it.
Forces in Human Movement Analysis[edit | edit source]
how forces are analyzed and measured during human movement assessments in rehabilitation, including techniques such as
- motion capture and
- force plates
Applications of Forces in Therapeutic Interventions[edit | edit source]
how forces are utilized in different rehabilitation therapies and interventions, such as
- resistance training,
- manual therapy, and
- therapeutic exercises.
Impact of Forces on Tissue Healing and Injury Prevention[edit | edit source]
Wound healing is a complex biological process crucial for tissue repair and regeneration. However, excessive scarring poses a significant clinical challenge, impacting both patient outcomes and healthcare costs. Recent advancements in our understanding of mechanical forces in the wound environment have illuminated the intricate interplay between biomechanics and tissue healing. This article delves into the pivotal role of mechanical forces in cutaneous wound healing and explores emerging therapeutic strategies aimed at minimizing scar formation.
Understanding the Impact of Mechanical Forces:[2]
Studies comparing fetal and adult wound healing reveal profound differences in the response to mechanical forces. Fetal wounds, characterized by lower resting stress levels, exhibit scarless healing, whereas adult wounds are prone to excessive scarring due to increased mechanical stresses in the wound environment. Mechanotransduction pathways play a central role in this process, with mechanical stimulation activating signaling cascades that promote fibrosis and scar formation.
Targeting Mechanical Forces to Minimize Scarring:[2]
Therapeutic interventions focusing on modulating mechanical forces offer promising avenues for scar minimization. By reducing mechanical stresses in the wound environment, these strategies aim to mitigate the activation of mechanotransduction pathways associated with hypertrophic and keloid scar formation. Novel mechanotherapies, such as mechanical offloading and mechanomodulation, have emerged as potential interventions to achieve scar reduction and promote more favorable wound healing outcomes.
Types of forces on the body[edit | edit source]
Compression Force[edit | edit source]
- Forces are moving primarily in an approximating direction
- Compression stimulates bone, cartilage, discogenic tissue, and often neurological tissue.[3]
- When these tissues are overloaded, this leads to fractures, in some cases disc damage, or even nerve compression[4].
- Examples: stress fracture of vertebrae, disc herniation, cervical radiculopathy, and compartment syndrome. Insufficient loading may lead to osteoporosis for example.[5]
Shear Force[edit | edit source]
- Forces are NOT moving in opposite or approximating directions exclusively. This is a COMBINATION of tension and compression.
- When shear is the primary motion occuring, the body often lacks sufficient ways to attenuate this stress and may lead to degenerative changes over time or perhaps even acute tissue rupture.
- EXAMPLES: This is seen in ACL ruptures and spondylolisthesis.
Tension Force[edit | edit source]
- Forces are oriented primarily in opposite directions[6]
- Tension stimulates muscle, tendon, ligament and in some cases neurological tissue.
- Overload with “tension” leads to sprains, strains and in some cases peripheral nerve injury.
- Examples: hamstring tear, patellar tendonopathy, brachial plexopathy, MCL tear. Insufficient loading leads to muscle atrophy, and weak ligaments and tendons for example.
Gravitational force[edit | edit source]
- Gravitational forces exerted on the human body influence biomechanical responses during various activities, such as standing, walking, and jumping
- it play a significant role in postural control, as the body continuously adjusts its orientation and center of mass to maintain stability against the pull of gravity [7]
- it affect gait patterns by influencing the distribution of forces and moments across joints during locomotion, impacting walking efficiency and stability [8]
- also contributes to musculoskeletal loading during weight-bearing activities, influencing bone density, muscle activation patterns, and joint loading [9]
- Understanding gravitational forces is essential for designing interventions to prevent falls in older adults and individuals with balance impairments, as minimizing the effects of gravity on postural stability can reduce fall risk [10]
Resources[edit | edit source]
- ↑ 1.0 1.1 Federal University of Technology, Owerri, & Tropical Publishers Nigeria. (2016). Human biomechanics: Basic and applied. Federal University of Technology, Owerri and Tropical Publishers Nigeria.
- ↑ 2.0 2.1 Barnes, L. A., Marshall, C. D., Leavitt, T., Hu, M. S., Moore, A. L., Gonzalez, J. G., Longaker, M. T., & Gurtner, G. C. (2018). Mechanical Forces in Cutaneous Wound Healing: Emerging Therapies to Minimize Scar Formation. Advances in Wound Care, 7(2). https://doi.org/10.1089/wound.2016.0709
- ↑ Owan I, Burr DB, Turner CH, Qiu J, Tu Y, Onyia JE, Duncan RL. Mechanotransduction in bone: osteoblasts are more responsive to fluid forces than mechanical strain. American Journal of Physiology-Cell Physiology. 1997 Sep 1;273(3):C810-5. doi: 10.1152/ajpcell.1997.273.3.C810.
- ↑ Adams MA. Mechanical influences in disc degeneration and prolapse: medico-legal relevance. Bone & Joint360. 2014;3(2):1-4.
- ↑ Claes L, Recknagel S, Ignatius A. Mechanobiology of Skeletal Regeneration. Langenbeck's Archives of Surgery. 2012.
- ↑ Matsumoto T, Nagayama K. Tensile properties of vascular smooth muscle cells: Bridging vascular and cellular biomechanics. Journal of Biomechanics. 2012 Mar 15;45(5):745-55. doi: 10.1016/j.jbiomech.2011.11.014.
- ↑ Winter, D. A. (1995). Human balance and posture control during standing and walking. Gait & posture, 3(4), 193-214.
- ↑ Mills, P. M., & Barrett, R. S. (2017). Methodological factors affecting joint moments estimation in clinical gait analysis: a systematic review. BioMedical Engineering OnLine, 16(106). https://doi.org/10.1186/s12938-017-0375-5
- ↑ Judex, S., & Carlson, K. J. (2009). Is Bone’s Response to Mechanical Signals Dominated by Gravitational Loading? Medicine & Science in Sports & Exercise, 41(11), 2037-2043. https://doi.org/10.1249/MSS.0b013e3181a8c931
- ↑ Rubenstein, L. Z. (2006). Falls in older people: epidemiology, risk factors and strategies for prevention. Age and ageing, 35(Supplement_2), ii37-ii41.
