Flexibility (anatomy)

Last updated April 16, 2024

An oversplit by former Olympic gymnast Irina Tchachina Overspagat.jpg — An oversplit by former Olympic gymnast Irina Tchachina

Flexibility is the anatomical range of movement in a joint or series of joints, and length in muscles that cross the joints to induce a bending movement or motion. Flexibility varies between individuals, particularly in terms of differences in muscle length of multi-joint muscles. Flexibility in some joints can be increased to a certain degree by exercise, with stretching a common exercise component to maintain or improve flexibility.

Anatomical elements

Joints

The joints in a human body are surrounded by synovial membranes and articular cartilage which cover, cushion and nourish the joint and surfaces of each.^[1] Increasing muscular elasticity of the joint's range of mobility increases flexibility.

Ligaments

Ligaments are composed of two different tissues: white and yellow. The white fibrous tissues are not stretchy, but are extremely strong so that even if the bone were fractured the tissue would remain in place. The white tissue allows subjective freedom of movement. The yellow elastic tissue can be stretched considerably and return to its original length.

Tendons

Tendons are not elastic and are even less stretchy. Tendons are categorized as a connective tissue. Connective tissue supports, surrounds, and binds the muscle fibres. They contain both elastic and non-elastic tissue.

Areolar tissue

The areolar tissue is permeable and is extensively distributed throughout the body. This tissue acts as a general binder for all other tissues.^[2]

Muscle tissue

Muscle tissue is made of a stretchy material. It is arranged in bundles of parallel fibres.^[3]

Stretch receptors

Stretch receptors have two parts: Spindle cells and Golgi tendons. Spindle cells, located in the center of a muscle, send messages for the muscle to contract.^[4] On the other hand, Golgi tendon receptors are located near the end of a muscle fiber and send messages for the muscle to relax. As these receptors are trained through continual use, stretching becomes easier. When reflexes that inhibit flexibility are released the splits then become easier to perform. The splits use the body's complete range of motion and provide a complete stretch.

Stretching

Flexibility is improved by stretching.^[5] Stretching should only be started when muscles are warm and the body temperature is raised. To be effective while stretching, force applied to the body must be held just beyond a feeling of pain and needs to be held for at least ten seconds. Increasing the range of motion creates good posture and develops proficient performance in everyday activities increasing the length of life and overall health of the individual.^[6]

Dynamic

Dynamic flexibility is classified as the ability to complete a full range of motion of a joint. This is a release of energy with proper timing for the muscles to contract.^[7] It also controls movement as the speed increases while stretching parts of the body. This form of stretching prepares the body for physical exertion and sports performance. In the past it was the practice to undertake static stretching before exercise. Dynamic stretching increases range of movement, blood and oxygen flow to soft tissues prior to exertion. Increasingly, coaches and sports trainers are aware of the role in dynamic stretching in improving performance and reducing the risk of injury.

Static-active

Static-active stretching includes holding an extended position with just the strength of the muscles such as holding the leg in front, side or behind. Static-active flexibility requires a great deal of strength, making it the hardest to develop.

Ballistic

Ballistic stretching is separate from all other forms of stretching. It does not include stretching, but rather a bouncing motion. The actual performance of ballistic movements prevents lengthening of tissues. These movements should only be performed when the body is very warm; otherwise they can lead to injury.

Limits

Each individual is born with a particular range of motion for each joint in their body. In the 1964 book Finding Balance by Gigi Berardi, the author mentions three limiting factors: occupational demands, movement demands, and training oversights.^[8]

Internal factors

Movement demands include strength, endurance and range of motion. Training oversights occurs when the body is overused.^[9] Internally, the joints, muscles, tendons, and ligaments can affect one's flexibility. As previously mentioned, each part of the body has its own limitations and combined, the range of motion can be affected. The mental attitude of the performer during the state of motion can also affect their range.

External factors

Externally, anything from the weather outside to the age of the performer can affect flexibility. General tissues and collagen change with age influencing the individual.^{[ further explanation needed ]}As one ages, performing activities of daily living without pain becomes much harder. By stretching often, one can maintain a level of musculoskeletal fitness that will keep them feeling well.

^[7] Performers should be aware of over-stretching. Even basic things such as clothing and equipment can affect a performance. Dance surfaces and lack of proper shoes can also affect a performer's ability to perform at their best.^[10]

Signs of injury

Stretching for too long or too much can give way to an injury.^[11] For most activities, the normal range of motion is more than adequate. Any sudden movements or going too fast can cause a muscle to tighten. This leads to extreme pain and the performer should let the muscle relax by resting.

Risk of injury

Some people get injuries while doing yoga^[12] and aerobics ^{[ citation needed ]} so one needs to be careful while doing it. While most stretching does not cause injury, it is said that quick, ballistic stretching can if it is done incorrectly.^[7] If a bone, muscle or any other part is stretched more than its capacity it may lead to dislocation or muscle pulls.

Related Research Articles

A ligament is the fibrous connective tissue that connects bones to other bones. It is also known as articular ligament, articular larua, fibrous ligament, or true ligament. Other ligaments in the body include the:

<span class="mw-page-title-main">Human leg</span> Lower extremity or limb of the human body (foot, lower leg, thigh and hip)

The leg is the entire lower limb of the human body, including the foot, thigh or sometimes even the hip or buttock region. The major bones of the leg are the femur, tibia, and adjacent fibula. The thigh is between the hip and knee, while the calf (rear) and shin (front) are between the knee and foot.

A tendon or sinew is a tough band of dense fibrous connective tissue that connects muscle to bone. It sends the mechanical forces of muscle contraction to the skeletal system, while withstanding tension.

The rotator cuff is a group of muscles and their tendons that act to stabilize the human shoulder and allow for its extensive range of motion. Of the seven scapulohumeral muscles, four make up the rotator cuff. The four muscles are:

Shoulder problems including pain, are one of the more common reasons for physician visits for musculoskeletal symptoms. The shoulder is the most movable joint in the body. However, it is an unstable joint because of the range of motion allowed. This instability increases the likelihood of joint injury, often leading to a degenerative process in which tissues break down and no longer function well.

A sprain is a soft tissue injury of the ligaments within a joint, often caused by a sudden movement abruptly forcing the joint to exceed its functional range of motion. Ligaments are tough, inelastic fibers made of collagen that connect two or more bones to form a joint and are important for joint stability and proprioception, which is the body's sense of limb position and movement. Sprains may be mild, moderate, or severe, with the latter two classes involving some degree of tearing of the ligament. Sprains can occur at any joint but most commonly occur in the ankle, knee, or wrist. An equivalent injury to a muscle or tendon is known as a strain.

The human musculoskeletal system is an organ system that gives humans the ability to move using their muscular and skeletal systems. The musculoskeletal system provides form, support, stability, and movement to the body.

Stretching is a form of physical exercise in which a specific muscle or tendon is deliberately expanded and flexed in order to improve the muscle's felt elasticity and achieve comfortable muscle tone. The result is a feeling of increased muscle control, flexibility, and range of motion. Stretching is also used therapeutically to alleviate cramps and to improve function in daily activities by increasing range of motion.

Manual therapy, or manipulative therapy, is a physical treatment primarily used by physical therapists, occupational therapists to treat musculoskeletal pain and disability; it mostly includes kneading and manipulation of muscles, joint mobilization and joint manipulation. It is also used by Rolfers, massage therapists, athletic trainers, osteopaths, and physicians.

Achilles tendon rupture is when the Achilles tendon, at the back of the ankle, breaks. Symptoms include the sudden onset of sharp pain in the heel. A snapping sound may be heard as the tendon breaks and walking becomes difficult.

<span class="mw-page-title-main">Fibular collateral ligament</span> Collateral fibular ligament

The lateral collateral ligament is an extrinsic ligament of the knee located on the lateral side of the knee. Its superior attachment is at the lateral epicondyle of the femur ; its inferior attachment is at the lateral aspect of the head of fibula. The LCL is not fused with the joint capsule. Inferiorly, the LCL splits the tendon of insertion of the biceps femoris muscle.

<span class="mw-page-title-main">Golfer's elbow</span> Tendon inflammation disease of the elbow

Golfer's elbow, or medial epicondylitis, is tendinosis of the medial common flexor tendon on the inside of the elbow. It is similar to tennis elbow, which affects the outside of the elbow at the lateral epicondyle. The tendinopathy results from overload or repetitive use of the arm, causing an injury similar to ulnar collateral ligament injury of the elbow in "pitcher's elbow".

<span class="mw-page-title-main">Acetabular labrum</span> Ring of cartilage that surrounds the acetabulum of the hip

The acetabular labrum is a fibrocartilaginous ring which surrounds the circumference of the acetabulum of the hip, deepening the acetabulum. The labrum is attached onto the bony rim and transverse acetabular ligament. It is triangular in cross-section.

Running economy (RE) a complex, multifactorial concept that represents the sum of metabolic, cardiorespiratory, biomechanical and neuromuscular efficiency during running. Oxygen consumption (VO₂) is the most commonly used method for measuring running economy, as the exchange of gases in the body, specifically oxygen and carbon dioxide, closely reflects energy metabolism. Those who are able to consume less oxygen while running at a given velocity are said to have a better running economy. However, straightforward oxygen usage does not account for whether the body is metabolising lipids or carbohydrates, which produce different amounts of energy per unit of oxygen; as such, accurate measurements of running economy must use O₂ and CO₂ data to estimate the calorific content of the substrate that the oxygen is being used to respire.

<span class="mw-page-title-main">Musculoskeletal injury</span> Medical condition

Musculoskeletal injury refers to damage of muscular or skeletal systems, which is usually due to a strenuous activity and includes damage to skeletal muscles, bones, tendons, joints, ligaments, and other affected soft tissues. In one study, roughly 25% of approximately 6300 adults received a musculoskeletal injury of some sort within 12 months—of which 83% were activity-related. Musculoskeletal injury spans into a large variety of medical specialties including orthopedic surgery, sports medicine, emergency medicine and rheumatology.

<span class="mw-page-title-main">Elastic therapeutic tape</span> Pseudo-medicine product; elastic cotton strip with an acrylic adhesive

Elastic therapeutic tape, also called kinesiology tape or kinesiology therapeutic tape, Kinesio tape, k-tape, or KT is an elastic cotton strip with an acrylic adhesive that is purported to ease pain and disability from athletic injuries and a variety of other physical disorders. In individuals with chronic musculoskeletal pain, research suggests that elastic taping may help relieve pain, but not more than other treatment approaches, and no evidence indicates that it can reduce disability in chronic pain cases.

Eccentric training is a type of strength training that involves using the target muscles to control weight as it moves in a downward motion. This type of training can help build muscle, improve athletic performance, and reduce the risk of injury. An eccentric contraction is the motion of an active muscle while it is lengthening under load. Eccentric training is repetitively doing eccentric muscle contractions. For example, in a biceps curl the action of lowering the dumbbell back down from the lift is the eccentric phase of that exercise – as long as the dumbbell is lowered slowly rather than letting it drop.

Elastic mechanisms in animals are very important in the movement of vertebrate animals. The muscles that control vertebrate locomotion are affiliated with tissues that are springy, such as tendons, which lie within the muscles and connective tissue. A spring can be a mechanism for different actions involved in hopping, running, walking, and serve in other diverse functions such as metabolic energy conservation, attenuation of muscle power production, and amplification of muscle power production.

The limbs of the horse are structures made of dozens of bones, joints, muscles, tendons, and ligaments that support the weight of the equine body. They include two apparatuses: the suspensory apparatus, which carries much of the weight, prevents overextension of the joint and absorbs shock, and the stay apparatus, which locks major joints in the limbs, allowing horses to remain standing while relaxed or asleep. The limbs play a major part in the movement of the horse, with the legs performing the functions of absorbing impact, bearing weight, and providing thrust. In general, the majority of the weight is borne by the front legs, while the rear legs provide propulsion. The hooves are also important structures, providing support, traction and shock absorption, and containing structures that provide blood flow through the lower leg. As the horse developed as a cursorial animal, with a primary defense mechanism of running over hard ground, its legs evolved to the long, sturdy, light-weight, one-toed form seen today.

Anatomical terminology is used to uniquely describe aspects of skeletal muscle, cardiac muscle, and smooth muscle such as their actions, structure, size, and location.

References

↑ Blakey (1994), p. 9.
↑ Blakey (1994), p. 26.
↑ Blakey (1994), p. 30.
↑ Blakey (1994), p. 33.
↑ Ashley (2004), p. 14.
↑ Barratt (1964), p. 27.
1 2 3 Holt, Laurence E. (2008). Flexibility : a concise guide to conditioning, performance enhancement, injury prevention, and rehabilitation. Pelham, Thomas W., Holt, Jason. Totowa, N.J.: Humana Press. ISBN 9781603271059. OCLC 501802731.
↑ Berardi (1964), p. 35.
↑ Berardi (1964), p. 37.
↑ Berardi (1964), p. 34.
↑ Blakey (1994), p. 20.
↑ Broad, William J. (2012). The Science of Yoga: The Risks and the Rewards . Simon and Schuster. ISBN 978-1-4516-4142-4.

Bibliography

Arnheim, Daniel D. Dance Injuries: Their Prevention And Care. 3rd ed. Princeton, NJ: Princeton Book Company, 1991. Print.
Ashley, Linda. Essential Guide to Dance. 2nd ed. London: Hodder & Stoughton, 2004. Print. ISBN 978-0340803202.
Barratt, Marcia, et al. Foundations For Movement. Dubuque, IA: Wm. C. Brown Co., 1964. Print.
Berardi, Gigi. Finding Balance. 2nd ed. Routledge, NY: Routledge, 2005. Print. ISBN 978-0415943390.
Blakey, W P. Stretching Without Pain. Canada: Twin Eagles Educational & Healing Institute, 1994. Print. ISBN 978-1873017050.
Como, William. Raoul Gelabert's anatomy for the dancer with exercises to improve technique and prevent injuries. New York: Danad, 1964; 51-57. ASIN B000XYUX4Q.
Dilmen, Nevit. Stretching. 2009. Own Work. Wikimedia Commons. Web. 4 Dec. 2010.
Franklin, Eric N. Conditioning for Dance. Champaign, IL: Human Kinetics, 2004. Print.
FvS. Split, gymnastics. 2005. Own Work. Wikimedia Commons. Web. 4 Dec. 2010.
Liedarback, "General considerations," p. 59.
McCharles, Rick. Gymnast jumping on beam. 2008. https://www.flickr.com/photos/71035721@N00/2972933329. Wikimedia Commons. Web. 4 Dec. 2010.
Pare, Caroline. Caroline Zhang in 2008 Skate Canada International. 2008. https://web.archive.org/web/20120724082853/http://everythingskating.com/. Wikimedia Commons. Web. 4 Dec. 2010.
Reinking, Ann, and Linda Szmyd. The Dancer's Workout. London: Bantam Books, 1984. Print.
Ryan, Allan J., and Robert E. Stephens, eds. The Healthy Dancer: Dance Medicine for Dancers. Princeton, NJ: Princeton Book Company, 1987. Print.
Stuart Wright, Dancer's Guide to Injuries of the Lower Extremity (New York: Cornwall Books, 1985), p. 14.
Swischuk, Leornard E. "Doing the Splits: Heard A Pop--Cannot Walk." Pediatric Emergency Care 23.11 (2007): 842-3. Web. 8 Sep. 2010. <http://ovidsp.tx.ovid.com>.

External links

NYU on Hip injuries
Mayo Clinic on Stretching
How to stretch
About.com on Front Splits Archived 2010-03-02 at the Wayback Machine

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[1] Blakey (1994), p. 9.

[2] Blakey (1994), p. 26.

[3] Blakey (1994), p. 30.

[4] Blakey (1994), p. 33.

[5] Ashley (2004), p. 14.

[6] Barratt (1964), p. 27.

[Holt-7] 1 2 3 Holt, Laurence E. (2008). Flexibility : a concise guide to conditioning, performance enhancement, injury prevention, and rehabilitation. Pelham, Thomas W., Holt, Jason. Totowa, N.J.: Humana Press. ISBN 9781603271059. OCLC 501802731.

[8] Berardi (1964), p. 35.

[9] Berardi (1964), p. 37.

[Finding_Balance-10] Berardi (1964), p. 34.

[11] Blakey (1994), p. 20.

[12] Broad, William J. (2012). The Science of Yoga: The Risks and the Rewards . Simon and Schuster. ISBN 978-1-4516-4142-4.

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v t e Stretching
Concepts	Flexibility Range of motion Warming up Cooling down
Source	Active stretching Passive stretching
Motion	Static stretching Dynamic stretching