What are the main hip and thigh muscles. How do they function in daily activities. What exercises can strengthen these muscles. How can you prevent common injuries related to hip and thigh muscles.

The Importance of Hip and Thigh Muscles in Human Movement

Hip and thigh muscles play a crucial role in human locomotion, stability, and overall lower body function. These muscle groups work in harmony to facilitate various movements essential for daily activities and athletic performance. Understanding their anatomy, functions, and proper care is vital for maintaining optimal physical health and preventing injuries.

Anatomy of Hip Muscles: Key Players in Lower Body Mechanics

The hip region comprises several muscle groups that work together to provide stability and enable movement. These muscles can be categorized based on their primary functions:

• Hip flexors
• Hip extensors
• Hip abductors
• Hip adductors
• Hip rotators

Each of these muscle groups contributes to specific movements of the hip joint, allowing for a wide range of motion and stability in various positions.

Hip Abductors: Facilitating Lateral Movement

Hip abductors are responsible for moving the leg away from the midline of the body. One of the key muscles in this group is the Tensor Fascia Latae (TFL).

The Tensor Fascia Latae is a small but significant muscle located on the outer side of the hip. It plays a crucial role in hip stabilization and movement. Here are its key characteristics:

• Origin: Anterior iliac crest and ilium
• Insertion: Lateral condyle of the tibia via the iliotibial band (ITB)
• Actions: Hip flexion and abduction
• Innervation: Superior gluteal nerve

In daily activities, the TFL is particularly important for maintaining balance while walking, especially when placing one foot in front of the other. To strengthen this muscle, exercises like standing hip abduction using a resistance band can be effective. Stretching exercises such as outer hip stretches can help maintain flexibility and prevent tightness.

The Hamstring Group: Powerhouses of Hip Extension and Knee Flexion

The hamstring muscle group consists of three major muscles located at the back of the thigh. These muscles are crucial for hip extension and knee flexion, playing a significant role in activities like running, jumping, and maintaining posture.

Semitendinosus: A Key Player in Hip and Knee Movement

The semitendinosus is one of the three muscles that make up the hamstring group. Its characteristics include:

• Origin: Ischial tuberosity
• Insertion: Upper medial surface of the tibia
• Actions: Hip extension, knee flexion, and internal rotation of the hip when the knee is flexed
• Innervation: Tibial part of the sciatic nerve

In everyday activities, the semitendinosus is engaged when bending the knee to step over objects. Strengthening exercises for this muscle include knee curls with resistance bands and Nordic curls. To maintain flexibility, sitting and standing hamstring stretches are recommended.

Semimembranosus: The Medial Hamstring Muscle

The semimembranosus is the most medial of the three hamstring muscles. Its properties include:

• Origin: Ischial tuberosity
• Insertion: Posterior part of the medial condyle of the tibia
• Actions: Hip extension, knee flexion, and internal rotation of the hip when the knee is flexed
• Innervation: Tibial part of the sciatic nerve

Like the semitendinosus, the semimembranosus is active in activities that involve bending the knee. It can be strengthened through exercises such as knee curls with resistance bands and Nordic curls. Stretching is equally important to prevent tightness, which can contribute to lower back and knee pain.

Hip Adductors: The Groin Muscles

Hip adductors, also known as the groin muscles, are responsible for bringing the leg towards the midline of the body. These muscles play a crucial role in stabilizing the hip and pelvis during various activities.

Adductor Magnus: The Largest Groin Muscle

The adductor magnus is the largest of the adductor muscles and is often described as having two distinct parts: the adductor head and the hamstring head. Its characteristics include:

• Origin:
  • Adductor head: Inferior ramus of pubis and ischial ramus
  • Hamstring head: Ischial tuberosity
• Insertion:
  • Adductor head: Gluteal tuberosity, linea aspera, and proximal supracondylar line
  • Hamstring head: Adductor tubercle of the femur
• Actions:
  • Adductor head: Hip adduction, flexion, and medial rotation
  • Hamstring head: Hip extension
• Innervation:
  • Adductor head: Obturator nerve
  • Hamstring head: Sciatic nerve

In daily activities, the adductor magnus is engaged when bringing the second leg into a car. To strengthen this muscle, hip adduction exercises using resistance bands are effective. Long adductor stretches can help maintain flexibility and prevent tightness.

Adductor Longus: The Middle Short Adductor

The adductor longus is the middle of the three short adductor muscles. Its properties include:

• Origin: Superior pubic ramus, just below the crest
• Insertion: Middle third of the linea aspera of the femur
• Actions: Hip adduction and flexion
• Innervation: Obturator nerve

Like the adductor magnus, this muscle is active when bringing the leg towards the midline, such as when entering a vehicle. Strengthening exercises include hip adduction with resistance bands, while long adductor stretches can help maintain flexibility.

Common Injuries and Prevention Strategies for Hip and Thigh Muscles

Understanding common injuries associated with hip and thigh muscles is crucial for prevention and proper care. Some of the most frequent issues include:

• Hamstring strains
• Groin strains
• Hip flexor strains
• Iliotibial band syndrome

These injuries often occur due to factors such as inadequate warm-up, muscle imbalances, or overuse. How can you prevent these common hip and thigh muscle injuries? Here are some effective strategies:

1. Proper warm-up: Always perform a thorough warm-up before engaging in physical activities to increase blood flow and prepare muscles for exertion.
2. Balanced strength training: Incorporate exercises that target all major hip and thigh muscle groups to prevent imbalances.
3. Flexibility maintenance: Regular stretching routines can help maintain muscle flexibility and reduce the risk of strains.
4. Gradual progression: Increase the intensity and duration of your workouts gradually to allow your muscles to adapt.
5. Proper form: Ensure correct technique during exercises and sports activities to minimize undue stress on muscles and joints.

Effective Exercises for Strengthening Hip and Thigh Muscles

Incorporating targeted exercises into your fitness routine can significantly improve the strength and functionality of your hip and thigh muscles. Here are some effective exercises for different muscle groups:

Exercises for Hip Abductors

• Standing hip abduction with resistance bands
• Side-lying leg raises
• Clamshells

Exercises for Hamstrings

• Nordic curls
• Romanian deadlifts
• Glute-ham raises

Exercises for Hip Adductors

• Standing adductor exercises with resistance bands
• Sumo squats
• Copenhagen plank

When performing these exercises, it’s essential to start with lighter weights or resistance and focus on proper form before progressing to more challenging variations.

The Role of Hip and Thigh Muscles in Athletic Performance

Hip and thigh muscles play a crucial role in various sports and athletic activities. Understanding their function can help athletes optimize their training and performance. How do these muscles contribute to different sports?

• Running: Hip flexors and extensors provide the power for forward propulsion, while abductors and adductors stabilize the pelvis.
• Jumping: The powerful contraction of hip extensors, particularly the gluteus maximus and hamstrings, is essential for vertical leap.
• Kicking: In sports like soccer or martial arts, the coordinated action of hip flexors, extensors, and rotators enables powerful and precise kicks.
• Swimming: Hip and thigh muscles contribute to the leg movements in various swimming strokes, providing propulsion and stability.

Athletes can enhance their performance by incorporating sport-specific exercises that target these muscle groups, improving strength, power, and endurance.

Rehabilitation and Recovery of Hip and Thigh Muscle Injuries

When injuries to hip and thigh muscles occur, proper rehabilitation is crucial for a full recovery and prevention of future issues. What are the key components of an effective rehabilitation program?

1. Rest and protection: Initially, allow the injured area to heal by avoiding activities that cause pain.
2. Gradual mobilization: As pain subsides, begin with gentle range-of-motion exercises to prevent stiffness.
3. Progressive strengthening: Implement a structured program of exercises that gradually increase in intensity and complexity.
4. Functional training: Incorporate exercises that mimic the movements and demands of your daily activities or sport.
5. Return to activity: Follow a carefully planned return-to-play protocol to ensure safe reintegration into full activity.

It’s important to work with a qualified healthcare professional, such as a physical therapist or sports medicine physician, to develop an appropriate rehabilitation plan tailored to your specific injury and needs.

The Importance of Proper Diagnosis

Accurate diagnosis is crucial for effective treatment of hip and thigh muscle injuries. Healthcare providers may use various diagnostic tools and techniques, including:

• Physical examination
• Imaging studies (X-rays, MRI, ultrasound)
• Functional movement assessments
• Strength and flexibility tests

These diagnostic methods help determine the exact nature and severity of the injury, guiding the development of an appropriate treatment and rehabilitation plan.

Maintaining Long-term Hip and Thigh Muscle Health

Maintaining the health of your hip and thigh muscles is essential for long-term mobility, function, and quality of life. What strategies can you employ to ensure the ongoing health of these important muscle groups?

1. Regular exercise: Engage in a balanced exercise routine that includes strength training, flexibility work, and cardiovascular activities.
2. Proper nutrition: Consume a balanced diet rich in protein, vitamins, and minerals to support muscle health and recovery.
3. Adequate hydration: Maintain proper hydration to support muscle function and prevent cramping.
4. Rest and recovery: Allow sufficient time for rest between workouts to prevent overuse injuries and promote muscle repair.
5. Posture awareness: Maintain good posture throughout the day to reduce unnecessary strain on hip and thigh muscles.
6. Regular stretching: Incorporate a regular stretching routine to maintain flexibility and prevent muscle imbalances.
7. Ergonomic considerations: Ensure your work and living environments are set up ergonomically to minimize strain on your muscles.

By implementing these strategies, you can help maintain the health and function of your hip and thigh muscles throughout your life, supporting overall physical well-being and reducing the risk of injuries.

The Role of Core Strength in Hip and Thigh Muscle Function

Core strength plays a significant role in supporting hip and thigh muscle function. A strong core provides a stable foundation for lower body movements, improving overall efficiency and reducing the risk of injury. How does core strength benefit hip and thigh muscles?

• Improved posture: A strong core helps maintain proper alignment of the spine and pelvis, reducing strain on hip and thigh muscles.
• Enhanced stability: Core muscles work in tandem with hip muscles to stabilize the pelvis during movement.
• Increased power transfer: A strong core allows for more efficient transfer of force between the upper and lower body, improving overall athletic performance.
• Reduced risk of lower back pain: By supporting proper spine alignment, a strong core can alleviate stress on the hip flexors and reduce the risk of lower back pain.

Incorporating core strengthening exercises into your fitness routine can significantly benefit the function and health of your hip and thigh muscles.

The Impact of Age on Hip and Thigh Muscle Function

As we age, changes in muscle mass, strength, and flexibility can affect the function of hip and thigh muscles. Understanding these changes is crucial for maintaining mobility and independence throughout life. How does aging affect hip and thigh muscles?

• Muscle mass reduction: Age-related muscle loss, known as sarcopenia, can lead to decreased strength and function.
• Reduced flexibility: Connective tissues may become less elastic, leading to decreased range of motion.
• Slower recovery: Aging muscles may take longer to recover from exertion or injury.
• Increased risk of falls: Weakened hip and thigh muscles can contribute to balance issues and an increased risk of falls.

To mitigate these age-related changes, it’s important to maintain an active lifestyle that includes regular strength training, flexibility exercises, and balance work. Consulting with a healthcare professional or certified fitness instructor can help develop an age-appropriate exercise program that addresses these concerns.

The Role of Nutrition in Supporting Aging Muscles

Proper nutrition plays a crucial role in maintaining muscle health as we age. What dietary considerations are important for supporting aging hip and thigh muscles?

• Adequate protein intake: Consuming sufficient high-quality protein helps maintain muscle mass and strength.
• Vitamin D and calcium: These nutrients support bone health, which is closely tied to muscle function.
• Antioxidants: A diet rich in fruits and vegetables provides antioxidants that may help reduce inflammation and support muscle health.
• Hydration: Proper hydration is essential for muscle function and recovery at any age.

Combining a balanced diet with regular exercise can help maintain hip and thigh muscle function well into later life, supporting overall health and independence.

Hip Muscles – Origin, Insertion, Action and Exercises

April 19, 2023

The hip muscles include pelvic and groin muscles. They are important for stabilising the body and for moving the legs. Here we explain the hip and groin muscles, their actions and exercises.

Each of the hip muscles will have a main function, to produce a specific movement. However, often they will do more than one movement, assisting another muscle.

Movements of the hip

The movements available at the hip are:

Flexion

This is when you move your leg forwards and upwards.

Extension

This is the reverse of flexion, moving the leg down and backward.

Abduction

This is moving the leg out to the side.

Adduction

This is moving the leg inwards from the side and across the front of the body.

Hip abductors

These muscles abduct the hip. Abduction is the movement when you lift your leg up sideways, away from the midline of the joint.

Tensor Fascia Latae

The Tensor Fasciae Latae (TFL) is a small muscle on the outside of the hip. It attaches inferiorly (underneath/below) to the long thick strip of fascia, known as the iliotibial band (ITB).

• Origin: Anterior Iliac crest and ilium.
• Insertion: Lateral condyle of the tibia via the Iliotibial band.
• Actions: Flexion of the hip. Hip abduction.
• Innervation: Superior gluteal nerve.
• Daily uses: Keeping one foot in front of the other when walking.
• Example strengthening exercise: Standing hip abduction using a resistance band.
• Example stretches: Outer hip stretch. Standing outer hip stretch.

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Hip muscles which make the hamstring group

Semitendinosus

When running the hamstrings act eccentrically to slow down the knee extension motion. Hamstring strains are common in individuals with chronically tight hamstrings or who do not warm up thoroughly.

• Origin: Ischial tuberosity.
• Insertion: Upper medial surface of the tibia.
• Actions: Hip extension. Knee flexion. Internal rotation of the hip when the knee is flexed.
• Innervation: Tibial part of the sciatic nerve.
• Daily uses: Bending the knee to step over something.
• Example strengthening exercises: Knee curl with a resistance band.
  Nordic curl.
• Example stretches: Sitting hamstring stretch. Standing hamstring stretch.

Semimembranosus

Semimembranosus is the most medial of the three hamstring muscles. Chronically tight hamstrings are often a contributory factor to lower back pain and knee pain.

• Origin: Ischial tuberosity.
• Insertion: Posterior part of the medial condyle of the tibia.
• Actions: Hip extension. Knee flexion. Internal rotation of the hip when the knee is flexed.
• Innervation: Tibial part of the sciatic nerve.
• Daily uses: Bending the knee to step over something.
• Example strengthening exercises: Knee curl with a resistance band. Nordic curl eccentric exercise
• Example stretches: Sitting hamstring stretch. Standing hamstring stretch.

Biceps Femoris

Biceps Femoris is one of the three muscles which form the hamstring group forming the back of the thigh. The muscle is often described as having a long head (the attachment from the ischium) and a short head (attached to the femur).

Adductor hip muscles

Adductor Magnus

Adductor Magnus is the largest groin muscle and is one of the two long adductor muscles (gracilis is the other). It is usually described as having two parts, hamstring, and adductor parts.

• Origin: Adductor head: Inferior ramus of pubis and ischial ramus.
  Adductor head: Inferior ramus of pubis and ischial ramus.
• Insertion: Adductor head: Gluteal tuberosity, linea aspera, and proximal supracondylar line.
  Hamstring head: Adductor tubercle of the femur.
• Actions: Adductor head: Adducts, flexes and medially rotates the hip. Hamstring head: Extends hip.
• Innervation: Adductor head: Obturator nerve.
  Hamstring head: Sciatic nerve.
• Daily uses: Bringing your second leg into the car.
• Example strengthening exercises: Hip adduction using a resistance band.
• Example stretches: Long adductor stretch.

Adductor Longus

Adductor Longus is the middle of the three short adductor muscles. Groin strains are common injuries to the adductor muscles, which occur without a thorough warm-up or in individuals with chronically tight or weak adductor muscles.

• Origin: Superior pubic ramus, just below the crest.
• Insertion: Middle third of the linea aspera of the femur.
• Actions: Hip adduction. Hip flexion.
• Innervation: Obturator nerve.
• Daily uses: Bringing your second leg into the car.
• Example Strengthening Exercises: Hip adduction using a resistance band.
• Example Stretches: Long adductor stretch.

Adductor Brevis

Adductor Brevis is the smallest and shortest (hence the name brevis, meaning short in latin) of the three short adductor muscles. Groin strains are common injuries to the adductor muscles, which occur without a thorough warm-up or in individuals with chronically tight or weak adductor muscles.

• Origin: Inferior ramus of the pubic bone Insertion.
  Upper part of the linea aspera of the femur.
• Actions: Hip adduction. Hip flexion.
• Innervation: Obturator nerve.
• Daily uses: Bringing your second leg into the car.
• Example Strengthening Exercises: Isometric hip adduction. Hip adduction using a resistance band.
• Example Stretches: Short adductor stretch.

Pectineus

Pectineus is positioned between the Iliopsoas and Adductor Longus muscles and is part of the short adductor group with adductors brevis and longus.

• Origin: Upper front of the pubic bone.
• Insertion: Upper medial shaft of the femur, inferior to the lesser trochanter.
• Actions: Hip adduction. Hip flexion. Medial hip rotation.
• Innervation: Femoral nerve.
• Daily uses: Kicking a football.
• Example strengthening exercises: Isometric groin contraction. Hip adduction using a resistance band.
• Example stretches: Short adductor stretch.

Gracilis

Gracilis is another muscle that works in conjunction with the groin muscles or adductors.

External rotator hip muscles

These muscles primarily rotate the hip externally (outwards).

Piriformis Muscle

The Piriformis muscle is an important muscle. The sciatic nerve passes underneath this muscle on its route down to the posterior thigh. In some individuals, the nerve can actually pass right through the muscle. This can lead to sciatica symptoms due to a condition known as piriformis syndrome.

• Origin: Anterior surface of the lateral sacrum
• Insertion: Greater trochanter of the femur
• Actions: External rotation of the hip. Hip abduction.
• Innervation: Branch of the sacral plexus
• Daily uses: Taking the first leg out of the car
• Example strengthening exercises: Hip extension with external rotation
• Example stretches: Piriformis stretch
• Related injuries: Piriformis syndrome
• Related muscles: Gluteus minimus, gluteus medius, gluteus maximus

Hip flexor muscles

These muscle flex the hip. Hip flexion is moving the leg forwards and upwards. The rectus femoris is also a hip muscle as well as being one of the quadriceps.

Iliopsoas

Iliopsoas is sometimes classified as two muscles, Iliacus and Psoas major, with Iliacus arising from the Ilium and Psoas from the vertebrae.

• Origin: Inner surface of the Ilium. Base of the sacrum.
  Sides of the bodies of T12-L5.
• Insertion: Lesser trochanter of the femur.
• Actions: Flexion of the hip. Lateral rotation of the hip. Flexing torso when the legs are fixed (e.g. lying to sitting).
• Innervation: Femoral nerve and branches of the lumbar plexus.
• Daily uses: Climbing a step.
• Example stretches: Hip flexor stretch.
• Example strengthening exercises: Isometric hip flexion. Standing hip flexion with a resistance band.

Gracilis

• Origin: Lower pubic body, near the pubic symphysis
• Insertion: Upper medial surface of the tibia (pes anserine insertion).
• Actions: Adducts hip.
  Flexes knee.
  Internally rotates the hip when the knee is flexed.
• Innervation: Obturator nerve.
• Daily uses: Sitting with the knees pressed together.
• Example strengthening exercises: Hip adduction using a resistance band.
• Example stretches: Long adductor stretch.

Rectus femoris

The Rectus Femoris muscle is part of the Quadriceps muscle group. It is the only muscle of the group which crosses the hip joint and is a powerful knee extensor when the hip is extended but is weak when the hip is flexed.

• Origin: Anterior Inferior Iliac Spine (AIIS).
• Insertion: Top of the patella and the patella tendon to the tibial tuberosity.
• Actions: Flexion of the hip. Extension of the knee.
• Innervation: Femoral nerve.
• Daily uses: Kicking a football.
• Example strengthening exercises: Standing hip flexion using resistance band. Sitting hip flexion – isometric.
• Example stretches: Hip flexor stretch. Laying quadricep stretch. Standing quadricep stretch.

Sartorius Muscle

The Sartorius is a two-joint muscle and so is weak when the knee is flexed and the hip is flexed at the same time. It works better during single movements.

• Origin: Area between the ASIS (Anterior Superior Iliac Spine) and AIIS (Anterior Inferior Iliac Spine).
• Insertion: Anterior part of the medial condyle of the tibia.
• Actions: Flexion of the hip. Flexion of the knee. External rotation of the hip as it flexes the hip and knee.
• Innervation: Femoral nerve. 
• Daily uses: Sitting in a cross-legged position. 
• Example strengthening exercises: Standing hip flexion using resistance band. Isometric hip flexion.  
• Example stretches: Hip flexor stretch. Laying quadricep stretch. Standing quadriceps stretch.

Gluteal muscles

Gluteus minimus

This is the smallest of the three gluteal muscles and sits underneath the gluteus medius.

• Origin: Outer surface of the ilium, below the origin of Gluteus medius.
• Insertion: Greater trochanter of the femur.
• Actions: Hip abduction. Internal rotation of the hip.
• Innervation: Superior gluteal nerve.
• Daily uses: Getting out of a car.
• Example strengthening exercises: Standing abduction using a resistance band.
• Example stretches: Outer hip stretch. Gluteal stretch.

Gluteus medius

Gluteus Medius is an important muscle in controlling the level of the hips. Weaknesses in gluteus medius often result in a Trendelenburg sign, an abnormal gait cycle where the hip of the swinging leg drops down, rather than raises up. This results in increased degrees of knee flexion in order to clear the ground.

• Origin: Outer surface of the ilium, just below the crest.
• Insertion: Greater trochanter of the femur.
• Actions: Hip abduction. Posterior fibres externally rotate the hip. Anterior fibres internally rotate the hip.
• Innervation: Superior gluteal nerve
• Daily uses: Stepping sideways out of the bath.
• Example strengthening exercises: Standing abduction using a resistance band.
• Example stretches: Outer hip stretch. Gluteal stretch.

Gluteus maximus

Gluteus Maximus is the largest and most superficial of the three gluteal muscles which forms the rounded shape of the buttocks.

• Origin: Posterior crest of the ilium.
  Posterior surface of the sacrum.  
• Insertion: Gluteal tuberosity of the femur Iliotibial band (ITB).  
• Actions: Hip extension.
  External rotation of the hip.
• Innervation: Inferior gluteal nerve.  
• Daily uses: Extension phase of walking upstairs.
• Example strengthening exercises: Hip extension using a resistance band.  
• Example stretches: Gluteus maximus stretch.  
• Related injuries: Myofascial pain in the buttock muscles.
• Related muscles: Gluteus medius. Gluteus minimus.

Normal Hip Joint Anatomy & Total Hip Replacement 3D Videos, Houston Texas

The hip joint is the largest weight-bearing joint in the human body. It is also referred to as a ball and socket joint and is surrounded by muscles, ligaments and tendons. The thighbone or femur and the pelvis join to form the hip joint.

Any injury or disease of the hip will adversely affect the joint’s range of motion and ability to bear weight.

The hip joint is made up of the following:

• Bones and joints
• Ligaments of the joint capsule
• Muscles and tendons
• Nerves and blood vessels that supply the bones and muscles of the hip

The hip joint is the junction where the hip joins the leg to the trunk of the body. It is comprised of two bones: the thighbone or femur, and the pelvis, which is made up of three bones called ilium, ischium and pubis.

The ball of the hip joint is made by the femoral head while the socket is formed by the acetabulum. The acetabulum is a deep, circular socket formed on the outer edge of the pelvis by the union of three bones: ilium, ischium and pubis. The lower part of the ilium is attached by the pubis while the ischium is considerably behind the pubis. The stability of the hip is provided by the joint capsule or acetabulum and the muscles and ligaments that surround and support the hip joint.

The head of the femur rotates and glides within the acetabulum. A fibrocartilaginous lining called the labrum is attached to the acetabulum and further increases the depth of the socket.

The femur is one of the longest bones in the human body. The upper part of the thighbone consists of the femoral head, femoral neck, and greater and lesser trochanters. The head of the femur joins the pelvis (acetabulum) to form the hip joint. Next to the femoral neck, there are two protrusions known as greater and lesser trochanters which serve as sites of muscle attachment.

Articular cartilage is the thin, tough, flexible and slippery surface lubricated by synovial fluid that covers the weight-bearing bones of the body. It enables smooth movements of the bones and reduces friction.

Ligaments of the Hip Joint

Ligaments are fibrous structures that connect bones to other bones. The hip joint is encircled with ligaments to provide stability to the hip by forming a dense and fibrous structure around the joint capsule. The ligaments adjoining the hip joint include:

• Iliofemoral ligament: This is a Y-shaped ligament that connects the pelvis to the femoral head at the front of the joint. It helps in limiting over-extension of the hip.
• Pubofemoral ligament: This is a triangular shaped ligament that extends between the upper portion of the pubis and the iliofemoral ligament. It attaches the pubis to the femoral head.
• Ischiofemoral ligament: This is a group of strong fibers that arise from the ischium behind the acetabulum and merge with the fibers of the joint capsule.
• Ligamentum teres: This is a small ligament that extends from the tip of the femoral head to the acetabulum. Although it has no role in hip movement, it does have a small artery within that supplies blood to a part of the femoral head.
• Acetabular labrum: The labrum is a fibrous cartilage ring which lines the acetabular socket. It deepens the cavity increasing the stability and strength of the hip joint.

Muscles and Tendons of the Hip Joint

A long tendon called the iliotibial band runs along the femur from the hip to the knee and serves as an attachment site for several hip muscles including the following:

• Gluteal: These are the muscles that form the buttocks. There are three muscles (gluteus minimus, gluteus maximus, and gluteus medius) that attach to the back of the pelvis and insert into the greater trochanter of the femur.
• Adductors: These muscles are in the thighs which help in adduction, the action of pulling the leg back towards the midline.
• Iliopsoas: This muscle is in front of the hip joint and provides flexion. It is a deep muscle that originates from the lower back and pelvis, and extends up to the inside surface of the upper part of the femur.
• Rectus femoris: This is the largest band of muscles located in front of the thigh. They are also called hip flexors.
• Hamstring muscles: These begin at the bottom of the pelvis and run down the back of the thigh. Because they cross the back of the hip joint, they help in extension of the hip by pulling it backwards.

Nerves and Arteries of the Hip Joint

Nerves of the hip transfer signals from the brain to the muscles to aid in hip movement. They also carry the sensory signals such as touch, pain, and temperature back to the brain.

The main nerves in the hip region include the femoral nerve in the front of the femur and the sciatic nerve at the back. The hip is also supplied by a smaller nerve known as the obturator nerve.

In addition to these nerves, there are blood vessels that supply blood to the lower limbs. The femoral artery, one of the largest arteries in the body, arises deep in the pelvis and can be felt in front of the upper thigh.

Hip Movements

All the anatomical parts of the hip work together to enable various movements.Hip movements include flexion, extension, abduction, adduction, circumduction, and hip rotation.

Quadriceps femoris – KinesioPro

The quadriceps femoris (quadriceps) is the largest muscle in the human body. It is made up of four separate muscles: three broad muscles (medial, lateral, and intermediate) and the rectus femoris. They form the bulk of the thigh and together are one of the most powerful muscles in the human body.

Clinically Relevant Anatomy

Origin and Insertion

The quadriceps muscles are attached to the patella by the quadriceps tendon. In turn, the patella is attached to the tibia by the patella ligament.

Vascularis lateralis muscle (LSM) of the thigh

• Origin: the muscle originates from the greater trochanter and lateral lip of the rough line of the femur.
• Function: extends the knee joint and stabilizes the patella.

Intermediate vastus muscle (VSM) of the thigh

• Origin: anterior and lateral surfaces of the body of the femur.
• Function: extends the knee and stabilizes the patella.

Vascular medial muscle (MSM) of the thigh

• Origin: intertrochanteric line and medial lip of the rough line of the femur.
• Function: extends the knee joint and stabilizes the patella, especially due to the horizontal fibers of the distal part of the muscle.

Read also the article: Angle Q.

Rectus femoris muscle (MP)

• Beginning: the muscle originates from the lower anterior iliac spine, just above the acetabulum, runs straight along the body of the femur (Latin word ” straight” – rectus) and is attached to the patella by the tendon of the quadriceps femoris muscle.
• Function: Flexes the hip and extends the knee (the only quadriceps muscle that crosses the hip and knee joints).

These muscles are innervated by the femoral nerve (L2, L3, L4).

Blood supply: femoral artery, deep femoral artery.

Function

Knee extension

All quadriceps muscles extend the knee. The hip PM also flexes the hip at the hip joint. The LSM of the thigh adducts the thigh, and also participates in its extension and external rotation.

• The quadriceps are mainly used during kicking, jumping (basketball), cycling and running.
• In daily life, these muscles help you get up from a chair, walk, climb stairs and squat.
• In the walking cycle, the muscles are most active during the swing phase; they are also active during the descent downhill.

Clinical Significance

From an athletic point of view, this is an extremely important muscle, but due to the stress it is under, it is often injured. Strains, tears and bruises of the quadriceps are common in various sports such as athletics, rugby, football, etc., and lead to a change in training regimen and the inability to participate in competitions. A quadriceps injury, not to mention a deterioration in athletic performance, can be quite painful and debilitating.

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Myositis ossificans is a complication that can occur in connection with severe contusions of the quadriceps muscle. This is a neoplastic proliferation of bones and cartilage in the area of ​​injury. With bruises, the incidence ranges from 9% to 17%. The condition should be suspected if symptoms worsen after 2–3 weeks, with impaired knee flexion and persistent edema.

Adaptation of the quadriceps muscle in the presence of disease

Skeletal muscles change in the presence of chronic disease. This means that the functions of the muscle may be impaired due to changes in metabolism and its own structure.

• Chronic obstructive pulmonary disease (COPD) and chronic heart failure

The presence of chronic respiratory diseases, such as COPD, determines the decrease in quadriceps mass, as well as an increase in connective tissue and fibrosis phenomena. This results in decreased contractility, decreased strength, and reduced balance when walking or standing. Anaerobic fibers increase due to oxidative fibers; muscles get tired more easily. There is also an increase in intramuscular fat with local and systemic metabolic changes (increased cardiovascular risk). Women suffer more from functional muscle changes than men.

• Multiple sclerosis

In multiple sclerosis, the quadriceps muscle loses its mass and strength, which is accompanied by a decrease in oxidative fibers and an increase in anaerobic fibers. Although there is an increase in the number of white fibers, the latter are characterized by greater atrophy. Increased intramuscular fat and fibrous processes.

• Aging

Age adaptation of the quadriceps muscle is accompanied by changes in its morphology and function. The muscle loses mass and volume (sarcopenia), strength and coordination decrease. Motor units are lost (denervation processes increase), while the percentage of red fibers increases. The processes of fibrosis and accumulation of intramuscular fat also increase.

Evaluation

After taking the history, a thorough examination should be performed, including examination, palpation, assessment of strength and movement. Injuries to the quadriceps muscle may be accompanied by obvious deformity, such as a bulge or defect in the belly of the muscle.

• Palpation of the anterior thigh should include assessment of the size of the injured muscle, localization of the area of ​​maximum tenderness, and search for any defect in the muscle.
• The quadriceps strength test should include assessment of resistance to knee extension and hip flexion. Adequate testing of the hip PM should include assessment of resistance to knee extension during hip flexion and extension. This is best done by assessing the patient both in the sitting and lying position. The person is asked to extend the leg at the knee against external resistance. If the femoral nerve is damaged, there will be no quadriceps contraction. The prone position also allows you to optimally assess the mobility and elasticity of the quadriceps muscle.
• Pain is usually felt by the patient with resistance to muscle activation, passive stretching, and direct palpation of the injury site.
• Identification of soreness, any palpable defect and strength at the onset of the disease allows you to determine the severity of the injury and clarify the direction for further examination and treatment.
• Evaluation of the quadriceps for imbalance suggests problems with the patella. It is also necessary to examine the patient in order to identify an imbalance between quadriceps and hamstrings.
• The quadriceps muscle can be used to test the femoral nerve.
• Functional tests include the Get Up and Walk Test and Stair Climbing Test.

Functional coordination between the vastus muscles of the thigh

Myoelectrical balance of the quadriceps muscle is essential for proper movement of the patella.

Proprioceptive muscle afferents help maintain adequate posture. Recent studies suggest that activation of these afferents allows the contralateral quadriceps muscle to improve its coordination and thus postural balance.

The thigh PM can activate its fibers in the longitudinal mode. It can also activate proximal fibers in the absence of distal fiber contraction. If quadriceps activity persists, then the most distal fibers are activated, while the most proximal fibers are not active (which is probably due to a mechanism that slows down the onset of fatigue).

Femoral LSM contributes little to the patellar tendon, so it is not able to generate enough force to medially stabilize the patella during knee extension. In fact, during its contraction, it pulls on the aponeurosis of the FSM of the thigh, counteracting the lateral forces on the patella generated by the LSM of the thigh. The LSM of the femur acts as an indirect stabilizer of the patella, concentrating its force along the median axis of the femur.

The force generated by the LBM of the thigh increases with increasing knee flexion angle. This mechanism is due to the length of the fibers compared to the connective tissue structure of the muscle. Longer fibers are characterized by greater strength and better elasticity or resistance of the connective tissue. When the knee is extended, the LBM of the thigh generates a small force that allows the position to be maintained with minimal effort.

Source: Physiopedia – Quadriceps Muscle.

FUNCTIONAL ANATOMY OF THE MUSCULAR SYSTEM | Thigh abductors

November 24, 2020

Nikita Yushchenko (author)

MUSCLES OF THE LOWER LIMB – abductors of the hip

The muscles of hip abduction cross the hip joint and are located on its lateral side. They are attached mainly to the greater trochanter.

Hip abductor muscles include :

1. gluteus medius;
2. gluteus minimus;
3. pear-shaped;
4. obturator internal;
5. twin;
6. tensor fascia lata (see hip flexors).

1. Gluteus medius is partially covered by the gluteus maximus. It starts from the outer surface of the ilium and the broad fascia of the thigh, and is attached to the greater trochanter.

Gluteus medius :

• Abducts the thigh.
• Also, due to the fact that the anterior fibers of the muscle go from top to bottom and back, and the posterior ones – from top to bottom and forward, it takes part in both pronation and supination of the thigh.

2. Gluteus minimus is located under the gluteus medius. It starts from the ilium and is attached to the greater trochanter.

Gluteus minor :

• Abducts the hip.

3. The piriformis muscle originates on the anterior surface of the sacrum, passes through the foramen magnum into the gluteal region, and inserts at the apex of the greater trochanter.

Piriformis :

• Abducts the thigh.
• Supinates the thigh.

4. The obturator internus muscle is located inside the small pelvis. It starts from the obturator membrane, goes to the lateral side, bends through the lesser sciatic notch, enters the gluteal region and attaches to the trochanteric fossa.

5. Upon its exit from the small pelvis, the upper and lower twin muscles are attached to the tendon of the obturator internus muscle , lying above and below it. These two small muscles originate from the ischial spine (upper muscle) and the ischial tuberosity (lower muscle).

• The function of the obturator internus and gemellius muscles is to abduct the hip if the pelvis is fixed, and in a standing position on one leg, to keep the pelvis from tilting towards the opposite leg.
• In addition, these muscles are also involved in the supination of the thigh.

The main role in hip abduction is played by the gluteus medius, and its anterior and middle sections perform abduction to a greater extent than the posterior one.