Functional Anatomy of the Hip-Muscles and Fascia


Original Editor - Ewa Jaraczewska based on course by Rina Pandya

Top Contributors - Ewa Jaraczewska, Jess Bell, Kim Jackson and Lucinda hampton

Introduction[edit | edit source]

One theory on human functional anatomy assumes that the body has two muscular systems: local and global (also known as stabiliser and global movers, see core muscles).

  1. The local muscular system acts close to the joint axis, provides joint compression, and is responsible for joint stability. Large forces produced by muscles and small changes in their length create joint compression, thus producing active stabilisation of the joint.[1]
  2. The global system contains superficial muscles generating greater torque and a larger moment arm.[1] However, it is the muscle architecture and the line of action that determines the muscles' primary role.

Daily activities require the hip joint to withstand high forces. This is made possible by the contribution of the individual muscles surrounding the joint.[2] Active stability provided by the hip muscles can increase passive stability in both the normal hip, as well as the hip with structural abnormality.[1]

Muscles[edit | edit source]

"There are 22 muscles that provide stability around the hip joint to give it that 360-degree mobility. It's a huge responsibility to maintain that stability of the ball and socket." Rina Pandya

External Rotators[edit | edit source]

External Rotators of the Hip
Attachments:[edit | edit source]

Quadratus femoris: ischial tuberosity to the intertrochanteric crest of the femur.

Obturator internus and externus: obturator membrane and ischiopubic ramus to the greater trochanter (internus) or intertrochanteric fossa of the femur (externus).

Gemelli (superior and inferior): ischial spine (superior) or ischial tuberosity (inferior) to the greater trochanter and obturator internus tendon.

Piriformis: anterior surface of the sacrum and sacrotuberous ligament to the greater trochanter.

Function:[edit | edit source]
  • Active stabilisers of the hip joint. A primary role of these muscles is to stabilise the femoral head in the acetabulum. When deep external rotators are resected during hip arthroplasty with a posterior surgical approach, there is an increased rate of prosthetic dislocation and functional deficits. With capsular repairs, the dislocation rate is lower.
  • Resisted external rotation of the hip with extension activates piriformis, but its line of force is not conducive to enhance joint compression.
  • If the hip joint is tight with external rotation, and the patient is not able to bring their leg up and put their sock on, it could indicate tightness of the piriformis. In addition, the patient may complain of shooting pain in the buttock region.[3]

Internal Rotators[edit | edit source]

Attachments:[edit | edit source]
Tensor Fascia Latae

Tensor fascia latae (TFL): the anterior superior iliac spine to iliotibial tract, between the deep and superficial layers of the iliotibial band.

Gluteus medius: the outer surface of the ilium, between the iliac crest, and the anterior and posterior gluteal lines to the greater trochanter. The muscle has three segments; anterior, posterior, middle or superficial, each with a specific orientation of muscle fibres.

Gluteus minimus: the outer surface of the ilium, between the anterior and posterior gluteal lines to the greater trochanter.

Function:[edit | edit source]
  • TFL works in different movement planes: it assists with hip abduction in the frontal plane, performs hip flexion in the sagittal plane, completes internal rotation in the transverse plane together with anterior gluteus medius and gluteus minimus.[4]
  • TFL has limited elasticity, which limits the bulging of the thigh muscles and, thus, helps keep them contained so they can contract efficiently.[3]
  • Gluteus medius and gluteus minimus are primary abductors and assist with internal rotation.

Abductors[edit | edit source]

Gluteus minimus

Gluteus medius

Tensor Fascia Latae

Piriformis

See above for attachments.

Function:[edit | edit source]
Hip Abductor

The functions of gluteus minimus include:

  • Stabilisation of the hip and pelvis through modulation of the joint capsule.
  • Stabilisation of the femoral head in the acetabulum.
  • Rotation and flexion of the hip.
  • Prevention of anterior dislocation and migration of the femoral head in a superior and medial direction.
  • Proprioceptive role.

Gluteus medius:

  • Is a primary abductor of the hip.
  • Stabilises the pelvis and hip.
  • Prevents the pelvis from adduction in a single-leg stance.
  • Is an important stabiliser of the pelvis on the hip as it contracts prior to and after foot contact regardless of the walking speed.[1]

Piriformis:

  • Externally (laterally) rotates the femur during the hip extension and abducts the femur during hip flexion.[5]
  • Acts as an auxiliary muscle and shows coactivation during pelvic floor muscles contracture.[6]

Adductors[edit | edit source]

Hip Adductors
Attachments:[edit | edit source]

Adductor longus: pubic bone between the crest and symphysis to linea aspera of the femur.

Adductor brevis: body and inferior ramus of the pubis to linea aspera of the femur.

Adductor magnus: ischial tuberosity and inferior ramus of the pubis to linea aspera and the adductor tubercle.

Gracilis: inferior pubic ramus to medial side of the tibial tuberosity.

Pectineus: pectineal line of the pubis and pubic tubercle to pectineal line of the femur.

Function:[edit | edit source]
  • The hip adductors contribute to static balance performance.[7]
  • Adductor longus provides some medial rotation.
  • Adductor magnus extends the hip through its attachment on the ischial tuberosity.
  • In open chain activation, the hip adductors' primary function is hip adduction.
  • In closed chain activation, the hip adductors help to stabilise the pelvis and lower extremity during the stance phase of gait.
  • Secondary roles of the hip adductors include hip flexion and rotation.[8]
  • Gracilis and semitendinosus create the conjoined tendons known as the pes anserinus.[9]

Flexors[edit | edit source]

Attachments[edit | edit source]
Hip Flexors

Iliopsoas has three portions:[3]

  • Iliacus: lateral edge of the sacrum and iliac fossa to the lesser trochanter of the femur.
  • Psoas major: transverse processes of vertebrae T12–L5 to the lesser trochanter of the femur.
  • Psoas minor: vertebral bodies of T12–L1 to iliopubic ramus.

Rectus femoris: anterior-inferior iliac spine, superior rim of the femoral acetabulum to the base of the patella.

Hip Flexors

Sartorius: anterior superior iliac spine to the upper medial side of the tibia.

Tensor fascia latae: see above.

Function:[edit | edit source]
  • Psoas major and iliacus are separately innervated. They are active throughout hip flexion.
  • Iliacus and both psoas muscles have a role similar to that of the rotator cuff muscles at the shoulder. They impact hip joint stability by creating tension in musculotendinous units as they pass over the anterior aspect of the hip joint.[1]
  • Sartorius serves as both a hip and knee flexor and hip external rotator.
  • The Thomas test assesses the length of the hip flexors. The contralateral limb is held in flexion. As flexion of this limb increases, the testing side (if tight) will lift off the bed. This lifting is caused by the posterior tilting of the lumbar spine. Extension of the knee on the testing side indicates rectus femoris or sartorius tightness.

Extensors[edit | edit source]

Hip Extensors
Attachments:[edit | edit source]

Gluteus maximus: ilium, sacrum, coccyx, and the sacrotuberous ligament to gluteal tuberosity of the femur and iliotibial band.

Biceps femoris:

  • Long head: ischial tuberosity to lateral tibial condyle and head of the fibula.
  • Short head: upper supra-condylar line and linea aspera to lateral tibial condyle and head of the fibula.

Semimembranosus: ischial tuberosity to superior and medial surface of the tibia.

Semitendinosus: ischial tuberosity to the medial condyle of the tibia.

Function:[edit | edit source]
  • Gluteus maximus is one of the primary hip extensors, it assists with hip external rotation and is the strongest and the largest muscle in the body.
  • Upper and lower fibres of the gluteus maximus contribute to abduction and adduction, so it is considered an accessory muscle for these movements.
  • Gluteus maximus is prone to weakness and inhibition.[10]
  • Gluteus maximus originates partially from the thoracolumbar fascia. This explains why issues in the lumbar spine or even the thoracolumbar junction can produce an anomaly or tightness / weakness of the gluteus maximus.
  • The biceps femoris long head is most often affected in a hamstring strain injury.[11]

Inversion of muscular action[edit | edit source]

The muscles of the hip joint can contribute to movement in several different planes depending on the position of the hip. This is caused by a change in the relationship between a muscle’s line of action and the hip’s axis of rotation, meaning that hip muscles can have secondary functions. For example, the gluteus medius and minimus act as abductors when the hip is extended and as internal rotators when the hip is flexed. The adductor longus acts as a flexor at 50° of hip flexion, but as an extensor at 70°.[12]

Fascia[edit | edit source]

The concept of fascial lines further explains the connection (i.e. myofascial continuity) between adjacent structures: muscles, tendons, ligaments. This concept helps to explain specific strains and connections that can occur following injury, adhesions, and postural changes.[13]

The fascial lines and the hip joint muscles connected with these lines are:[14]

  • Front functional line: adductor longus
  • Back functional line: contralateral gluteus maximus
  • Superficial front line: rectus femoris
  • Superficial back line: hamstrings
  • Lateral line: gluteus maximus, tensor fascia latae, iliotibial tract/ hip abductors
  • Spiral line: iliotibial tract, tensor fascia latae
  • Deep front line: iliacus, psoas, adductor brevis and longus, adductor magnus and minimus

This video further explains the concept of fascia lines:

[15]

Examples of fascia connections in the hip joint:[16]

  • The fascia of the hip adductors continues to the pelvis and influences the urogenital and pelvic diaphragms.
  • The iliacus fascia is continuous with the deep pelvic fascia.
  • The fascia of the gluteus medius is continuous with the fascia of the abdominal obliques at the iliac crest.
  • There is fascial continuity between the obturator internus and the iliacus which further extends into internal obliques and the diaphragm.

Clinical relevance[edit | edit source]

  1. Piriformis syndrome is described as irritation of the sciatic nerve at the level of the piriformis muscle. It has a number of symptoms involving the hip, buttock, and upper thigh. Possible causes include trauma, haematoma, excessive sitting, and anatomic variations of the muscle and nerve.[17]
  2. Gluteus medius and gluteus minimus muscles weakness can present as a Trendelenburg gait.[3]
  3. One study found that an external myofascial mobilisation approach based on fascial connectivity including the ipsilateral latissimus dorsi, ipsilateral thoracolumbar fascia and contralateral gluteus maximus posteriorly, ipsilateral external oblique and contralateral internal oblique, and hip adductor complex anteriorly led to significant symptom improvement for the chronic pelvic pain syndrome (muscle spastic type).[18]
  4. Psoas tightness can contribute to low back pain.[3]

Resources[edit | edit source]

  1. 1.0 1.1 1.2 1.3 1.4 Retchford TH, Crossley KM, Grimaldi A, Kemp JL, Cowan SM. Can local muscles augment stability in the hip? A narrative literature review. J Musculoskelet Neuronal Interact. 2013 Mar 1;13(1):1-2.
  2. Correa TA, Crossley KM, Kim HJ, Pandy MG. Contributions of individual muscles to hip joint contact force in normal walking. Journal of biomechanics. 2010 May 28;43(8):1618-22.
  3. 3.0 3.1 3.2 3.3 3.4 Pandya R. Anatomy of the Hip Course. Plus. 2022.
  4. Besomi Molina M. Towards the investigation of the tensor fascia lata muscle and iliotibial band function in runners: the relevance of the why and the how. The University of Queensland, Australia. A thesis submitted for the degree of Doctor of Philosophy at The University of Queensland in 2020.
  5. Chang C, Jeno SH, Varacallo M. Anatomy, bony pelvis and lower limb, piriformis muscle. StatPearls [Internet]. 2020 Nov 12.
  6. Wang Z, Zhu Y, Han D, Huang Q, Maruyama H, Onoda K. Effect of hip external rotator muscle contraction on pelvic floor muscle function and the piriformis. International Urogynecology Journal. 2021 Nov 29:1-7.
  7. Porto JM, Freire Junior RC, Bocarde L, Fernandes JA, Marques NR, Rodrigues NC, de Abreu DC. Contribution of hip abductor–adductor muscles on the static and dynamic balance of community-dwelling older adults. Ageing clinical and experimental research. 2019 May;31(5):621-7.
  8. Kiel J, Kaiser K. Adductor strain. Available at https://europepmc.org/article/nbk/nbk493166 (last access 23.02.2022)
  9. Walters BB, Varacallo M. Anatomy, Bony Pelvis and Lower Limb, Thigh Sartorius Muscle. In: StatPearls. StatPearls Publishing, Treasure Island (FL); 2021
  10. Buckthorpe M, Stride M, Della Villa F. Assessing and treating gluteus maximus weakness–a clinical commentary. International journal of sports physical therapy. 2019 Jul;14(4):655.
  11. Llurda-Almuzara L, Labata-Lezaun N, López-de-Celis C, Aiguadé-Aiguadé R, Romaní-Sánchez S, Rodríguez-Sanz J, Fernández-de-Las-Peñas C, Pérez-Bellmunt A. Biceps femoris activation during hamstring strength exercises: a systematic review. International Journal of Environmental Research and Public Health. 2021 Jan;18(16):8733.
  12. Byrne DP, Mulhall KJ, Baker JF. Anatomy & Biomechanics of the Hip. The Open Sports Medicine Journal, 2010, 4: 51-57
  13. Myers TW. Anatomy Trains. Second edition. London: Churchill Livingstone, Elsevier; 2011.
  14. Ward P. SFMA and Anatomy Trains: Concepts For Assessment and Treatment [Internet]. Sports Rehab Expert [accessed 29 November 2021]. Available from: https://www.sportsrehabexpert.com/public/472.cfm
  15. CatFitGlobal.Myofascial Lines. 2012. Available from: https://www.youtube.com/watch?v=LTt1DN3ozAs&t=64s [last accessed 24/02/2022]
  16. Schultz RL, Feitis R. The endless web. Fascial anatomy and physical reality. USA, CA: North Atlantic Books;1996
  17. Physiopedia. Piriformis syndrome. Available from: physio-pedia.com/Piriformis_Syndrome (accessed 6 March 2022)
  18. Ajimsha MS, Ismail LA, Al-Mudahka N, Majzoub A. Effectiveness of external myofascial mobilisation in the management of male chronic pelvic pain of muscle spastic type: A retrospective study. Arab J Urol. 2021 Jul 26;19(3):394-400.