The foot has two arches: the longitudinal arch and the transverse arch. The longitudinal arch is higher on the medial side and is supported by the posterior pillar of the calcaneum and the anterior pillar composed of the navicular bone, three cuneiforms, and the medial three metatarsal bones. The transverse arch is located on the anterior part of the tarsus and the posterior part of the metatarsus. The foot has several intertarsal joints, including the sub talar joint, talocalcaneonavicular joint, calcaneocuboid joint, transverse tarsal joint, cuneonavicular joint, intercuneiform joints, and cuneocuboid joint. The foot also has various ligaments, including those of the ankle joint and foot. The foot is innervated by the lateral plantar nerve and medial plantar nerve, and it receives blood supply from the plantar arteries and dorsalis pedis artery. The foot has several muscles, including the abductor hallucis, flexor digitorum brevis, abductor digit minimi, flexor hallucis brevis, adductor hallucis, and extensor digitorum brevis.

Structures Passing Posterior to the Medial Malleolus

The medial malleolus is a bony prominence on the inner side of the ankle joint. Several important structures pass posterior to it, including the tibialis posterior tendon, flexor digitorum longus tendon, posterior tibial artery, tibial nerve, and tendon of flexor hallucis longus.

The tibialis posterior tendon is responsible for plantar flexion and inversion of the foot, while the flexor digitorum longus tendon helps to flex the toes. The posterior tibial artery supplies blood to the foot and ankle, while the tibial nerve provides sensation and motor function to the muscles of the lower leg and foot. Finally, the tendon of flexor hallucis longus helps to flex the big toe.

It is important to be aware of these structures when performing any procedures or surgeries in the area, as damage to them can result in significant complications. Understanding the anatomy of the ankle and foot can also help in the diagnosis and treatment of various conditions affecting these structures.

Compartment syndrome is characterized by the 6 P’s: pain, paresthesia, paresis, pallor, perishingly cold, and pulselessness. Pain is an early symptom that is often not relieved by pain medication and is particularly noticeable during passive stretching. Paresthesia, which includes abnormal sensations like tingling, numbness, and burning, may progress to anesthesia.

Compartment syndrome is a complication that can occur after fractures or vascular injuries. It is characterized by increased pressure within a closed anatomical space, which can lead to tissue death. Supracondylar fractures and tibial shaft injuries are the most common fractures associated with compartment syndrome. Symptoms include pain, numbness, paleness, and possible paralysis of the affected muscle group. Even if a pulse is present, compartment syndrome cannot be ruled out. Diagnosis is made by measuring intracompartmental pressure, with pressures over 20 mmHg being abnormal and over 40 mmHg being diagnostic. X-rays typically do not show any pathology. Treatment involves prompt and extensive fasciotomies, with careful attention to decompressing deep muscles in the lower limb. Patients may experience myoglobinuria and require aggressive IV fluids. In severe cases, debridement and amputation may be necessary, as muscle death can occur within 4-6 hours.

Wharton’s duct is encircled by the lingual nerve, which is responsible for providing sensory innervation to the front two-thirds of the tongue.

Anatomy of the Submandibular Gland

The submandibular gland is located beneath the mandible and is surrounded by the superficial platysma, deep fascia, and mandible. It is also in close proximity to various structures such as the submandibular lymph nodes, facial vein, marginal mandibular nerve, cervical branch of the facial nerve, deep facial artery, mylohyoid muscle, hyoglossus muscle, lingual nerve, submandibular ganglion, and hypoglossal nerve.

The submandibular duct, also known as Wharton’s duct, is responsible for draining saliva from the gland. It opens laterally to the lingual frenulum on the anterior floor of the mouth and is approximately 5 cm in length. The lingual nerve wraps around the duct, and as it passes forward, it crosses medial to the nerve to lie above it before crossing back, lateral to it, to reach a position below the nerve.

The submandibular gland receives sympathetic innervation from the superior cervical ganglion and parasympathetic innervation from the submandibular ganglion via the lingual nerve. Its arterial supply comes from a branch of the facial artery, which passes through the gland to groove its deep surface before emerging onto the face by passing between the gland and the mandible. The anterior facial vein provides venous drainage, and the gland’s lymphatic drainage goes to the deep cervical and jugular chains of nodes.

The extensor carpi radialis longus muscle is innervated by the radial nerve. However, in a patient with a radial nerve palsy due to a midshaft humeral fracture, this muscle may be the only forearm extensor directly supplied by the radial nerve. Therefore, it is the most likely correct answer when considering exercises to strengthen the affected muscle.

The extensor carpi radialis brevis muscle, which originates from the lateral epicondyle of the humerus, is also innervated by a branch of the radial nerve. However, its insertion point is different from that described in the MRI, making it an unlikely answer.

The extensor digitorum brevis muscle, which assists in extending the toes, is not relevant to the patient’s wrist condition.

The extensor digitorum longus muscle, which is involved in foot dorsiflexion and toe extension, is also not relevant to the patient’s wrist condition.

Upper limb anatomy is a common topic in examinations, and it is important to know certain facts about the nerves and muscles involved. The musculocutaneous nerve is responsible for elbow flexion and supination, and typically only injured as part of a brachial plexus injury. The axillary nerve controls shoulder abduction and can be damaged in cases of humeral neck fracture or dislocation, resulting in a flattened deltoid. The radial nerve is responsible for extension in the forearm, wrist, fingers, and thumb, and can be damaged in cases of humeral midshaft fracture, resulting in wrist drop. The median nerve controls the LOAF muscles and can be damaged in cases of carpal tunnel syndrome or elbow injury. The ulnar nerve controls wrist flexion and can be damaged in cases of medial epicondyle fracture, resulting in a claw hand. The long thoracic nerve controls the serratus anterior and can be damaged during sports or as a complication of mastectomy, resulting in a winged scapula. The brachial plexus can also be damaged, resulting in Erb-Duchenne palsy or Klumpke injury, which can cause the arm to hang by the side and be internally rotated or associated with Horner’s syndrome, respectively.

The patient has both osteoarthritis and rheumatoid arthritis, with the latter affecting the smaller joints of the hands and feet. Methotrexate is a commonly used immunosuppressive medication for rheumatoid arthritis, but it can cause hepatotoxicity as a significant side effect.

Although fat emboli are a potential risk after orthopaedic surgery, they usually cause neural and respiratory symptoms rather than liver damage. Additionally, the onset of fat emboli occurs within hours to days after the operation, not three months later.

While calcium channel blockers, ACE inhibitors, and opioid medications have their own side effects, they typically do not affect liver function.

Methotrexate is an antimetabolite that hinders the activity of dihydrofolate reductase, an enzyme that is crucial for the synthesis of purines and pyrimidines. It is a significant drug that can effectively control diseases, but its side-effects can be life-threatening. Therefore, careful prescribing and close monitoring are essential. Methotrexate is commonly used to treat inflammatory arthritis, especially rheumatoid arthritis, psoriasis, and acute lymphoblastic leukaemia. However, it can cause adverse effects such as mucositis, myelosuppression, pneumonitis, pulmonary fibrosis, and liver fibrosis.

Women should avoid pregnancy for at least six months after stopping methotrexate treatment, and men using methotrexate should use effective contraception for at least six months after treatment. Prescribing methotrexate requires familiarity with guidelines relating to its use. It is taken weekly, and FBC, U&E, and LFTs need to be regularly monitored. Folic acid 5 mg once weekly should be co-prescribed, taken more than 24 hours after methotrexate dose. The starting dose of methotrexate is 7.5 mg weekly, and only one strength of methotrexate tablet should be prescribed.

It is important to avoid prescribing trimethoprim or co-trimoxazole concurrently as it increases the risk of marrow aplasia. High-dose aspirin also increases the risk of methotrexate toxicity due to reduced excretion. In case of methotrexate toxicity, the treatment of choice is folinic acid. Overall, methotrexate is a potent drug that requires careful prescribing and monitoring to ensure its effectiveness and safety.

The subscapularis muscle is responsible for internal rotation, while the other muscles in the cuff are responsible for external rotation. During Gerber’s Test, the consultant will ask you to place the dorsum of your hand behind your back, which requires internal rotation of the humerus. This movement is facilitated by the subscapularis muscle.

Understanding the Rotator Cuff Muscles

The rotator cuff muscles are a group of four muscles that are responsible for the movement and stability of the shoulder joint. These muscles are known as the SItS muscles, which stands for Supraspinatus, Infraspinatus, teres minor, and Subscapularis. Each of these muscles has a specific function in the movement of the shoulder joint.

The Supraspinatus muscle is responsible for abducting the arm before the deltoid muscle. It is the most commonly injured muscle in the rotator cuff. The Infraspinatus muscle rotates the arm laterally, while the teres minor muscle adducts and rotates the arm laterally. Lastly, the Subscapularis muscle adducts and rotates the arm medially.

Understanding the functions of each of these muscles is important in diagnosing and treating rotator cuff injuries. By identifying which muscle is injured, healthcare professionals can develop a treatment plan that targets the specific muscle and promotes healing. Overall, the rotator cuff muscles play a crucial role in the movement and stability of the shoulder joint.

The Gell and Coombs classification divides hypersensitivity reactions into four types. Type 1 is immediate and IgE mediated, type 2 is mediated by IgG and IgM causing cell death, type 3 is mediated by immune complexes, and type 4 is delayed and mediated by T lymphocytes causing contact dermatitis. Examples of each type include allergic rhinitis, Goodpasture syndrome, and rheumatoid arthritis. Nickel is a common cause of contact dermatitis.

Understanding Contact Dermatitis

Contact dermatitis is a skin condition that can be caused by two main types of reactions. The first type is irritant contact dermatitis, which is a non-allergic reaction that occurs due to exposure to weak acids or alkalis, such as detergents. This type of dermatitis is commonly seen on the hands and is characterized by erythema, but crusting and vesicles are rare.

The second type of contact dermatitis is allergic contact dermatitis, which is a type IV hypersensitivity reaction. This type of dermatitis is uncommon and is often seen on the head following hair dyes. It presents as an acute weeping eczema that predominantly affects the margins of the hairline rather than the hairy scalp itself. Topical treatment with a potent steroid is indicated for this type of dermatitis.

Cement is a frequent cause of contact dermatitis. The alkaline nature of cement may cause an irritant contact dermatitis, while the dichromates in cement can also cause an allergic contact dermatitis. It is important to understand the different types of contact dermatitis and their causes to effectively manage and treat this condition.

The correct nerve that runs in its groove between the two heads is the radial nerve. The ulnar nerve is positioned anterior to the medial head, while the axillary nerve passes through the quadrangular space located above the lateral head of the triceps muscle. As a result, the lateral border of the quadrangular space is the humerus.

Anatomy of the Triceps Muscle

The triceps muscle is a large muscle located on the back of the upper arm. It is composed of three heads: the long head, lateral head, and medial head. The long head originates from the infraglenoid tubercle of the scapula, while the lateral head originates from the dorsal surface of the humerus, lateral and proximal to the groove of the radial nerve. The medial head originates from the posterior surface of the humerus on the inferomedial side of the radial groove and both of the intermuscular septae.

All three heads of the triceps muscle insert into the olecranon process of the ulna, with some fibers inserting into the deep fascia of the forearm and the posterior capsule of the elbow. The triceps muscle is innervated by the radial nerve and supplied with blood by the profunda brachii artery.

The primary action of the triceps muscle is elbow extension. The long head can also adduct the humerus and extend it from a flexed position. The radial nerve and profunda brachii vessels lie between the lateral and medial heads of the triceps muscle. Understanding the anatomy of the triceps muscle is important for proper diagnosis and treatment of injuries or conditions affecting this muscle.

Winged scapula is caused by paralysis of serratus anterior, which affects arm abduction. Triceps brachii is responsible for extension, biceps brachii for flexion, and latissimus dorsi for adduction.

Upper limb anatomy is a common topic in examinations, and it is important to know certain facts about the nerves and muscles involved. The musculocutaneous nerve is responsible for elbow flexion and supination, and typically only injured as part of a brachial plexus injury. The axillary nerve controls shoulder abduction and can be damaged in cases of humeral neck fracture or dislocation, resulting in a flattened deltoid. The radial nerve is responsible for extension in the forearm, wrist, fingers, and thumb, and can be damaged in cases of humeral midshaft fracture, resulting in wrist drop. The median nerve controls the LOAF muscles and can be damaged in cases of carpal tunnel syndrome or elbow injury. The ulnar nerve controls wrist flexion and can be damaged in cases of medial epicondyle fracture, resulting in a claw hand. The long thoracic nerve controls the serratus anterior and can be damaged during sports or as a complication of mastectomy, resulting in a winged scapula. The brachial plexus can also be damaged, resulting in Erb-Duchenne palsy or Klumpke injury, which can cause the arm to hang by the side and be internally rotated or associated with Horner’s syndrome, respectively.

There are three categories of muscle: skeletal, cardiac, and smooth.

The Process of Muscle Contraction

Muscle contraction is a complex process that involves several steps. It begins with an action potential reaching the neuromuscular junction, which causes a calcium ion influx through voltage-gated calcium channels. This influx leads to the release of acetylcholine into the extracellular space, which activates nicotinic acetylcholine receptors, triggering an action potential. The action potential then spreads through the T-tubules, activating L-type voltage-dependent calcium channels in the T-tubule membrane, which are close to calcium-release channels in the adjacent sarcoplasmic reticulum. This causes the sarcoplasmic reticulum to release calcium, which binds to troponin C, causing a conformational change that allows tropomyosin to move, unblocking the binding sites. Myosin then binds to the newly released binding site, releasing ADP and pulling the Z bands towards each other. ATP binds to myosin, releasing actin.

The components involved in muscle contraction include the sarcomere, which is the basic unit of muscles that gives skeletal and cardiac muscles their striated appearance. The I-band is the zone of thin filaments that is not superimposed by thick filaments, while the A-band contains the entire length of a single thick filament. The H-zone is the zone of the thick filaments that is not superimposed by the thin filaments, and the M-line is in the middle of the sarcomere, cross-linking myosin. The sarcoplasmic reticulum releases calcium ion in response to depolarization, while actin is the thin filaments that transmit the forces generated by myosin to the ends of the muscle. Myosin is the thick filaments that bind to the thin filament, while titin connects the Z-line to the thick filament, altering the structure of tropomyosin. Tropomyosin covers the myosin-binding sites on actin, while troponin-C binds with calcium ions. The T-tubule is an invagination of the sarcoplasmic reticulum that helps co-ordinate muscular contraction.

There are two types of skeletal muscle fibres: type I and type II. Type I fibres have a slow contraction time, are red in colour due to the presence of myoglobin, and are used for sustained force. They have a high mitochondrial density and use triglycerides as

When a hip fracture occurs within the joint capsule, there is a higher chance of the femoral head experiencing avascular necrosis. This type of fracture is considered displaced and requires treatment with hemiarthroplasty or total hip replacement, especially for older patients. However, younger patients may opt for hip fixation instead of replacement as prosthetic joints have a limited lifespan.

Hip fractures are a common occurrence, particularly in elderly women with osteoporosis. The femoral head’s blood supply runs up the neck, making avascular necrosis a risk in displaced fractures. Symptoms include pain and a shortened and externally rotated leg. Patients with non-displaced or incomplete neck of femur fractures may still be able to bear weight. Hip fractures are classified based on their location, either intracapsular or extracapsular. The Garden system is a commonly used classification system that categorizes fractures into four types based on stability and displacement. Blood supply disruption is most common in Types III and IV.

Undisplaced intracapsular fractures can be treated with internal fixation or hemiarthroplasty if the patient is unfit. Displaced fractures require replacement arthroplasty, with total hip replacement being preferred over hemiarthroplasty if the patient was able to walk independently outdoors with no more than a stick, is not cognitively impaired, and is medically fit for anesthesia and the procedure. Extracapsular fractures are managed with a dynamic hip screw for stable intertrochanteric fractures and an intramedullary device for reverse oblique, transverse, or subtrochanteric fractures.

Azathioprine is an immunosuppressant that is commonly used to maintain remission in Crohn’s disease. It is metabolized into mercaptopurine, which inhibits purine synthesis and helps to control inflammation.

Infliximab is a monoclonal antibody that is sometimes used to induce remission in refractory or fistulating Crohn’s disease. It works by binding to and neutralizing tumor necrosis factor, a key mediator of inflammation.

Mesalazine is a second-line drug that is used to induce remission in Crohn’s disease after glucocorticoids. It belongs to the 5-aminosalicylate class of drugs and works by inhibiting prostaglandin secretion. It is also considered for use in maintaining remission in post-surgical Crohn’s patients.

Methotrexate is another immunosuppressant that is used as a second-line treatment for Crohn’s disease. It works by disrupting folic acid metabolism and accumulating the anti-inflammatory molecule adenosine.

Metronidazole is an antibiotic that is used to treat isolated peri-anal Crohn’s disease. It works by forming radicals that disrupt the DNA of anaerobic bacteria.

Azathioprine is a medication that is converted into mercaptopurine, which is an active compound that inhibits the production of purine. To determine if someone is at risk for azathioprine toxicity, a test for thiopurine methyltransferase (TPMT) may be necessary. Adverse effects of this medication include bone marrow depression, nausea and vomiting, pancreatitis, and an increased risk of non-melanoma skin cancer. If infection or bleeding occurs, a full blood count should be considered. It is important to note that there may be a significant interaction between azathioprine and allopurinol, so lower doses of azathioprine should be used. However, azathioprine is generally considered safe to use during pregnancy.

Anatomy of the Lateral Malleolus

The lateral malleolus is a bony prominence on the outer side of the ankle joint. Posterior to the lateral malleolus and superficial to the superior peroneal retinaculum are the sural nerve and short saphenous vein. These structures are important for sensation and blood flow to the lower leg and foot.

On the other hand, posterior to the lateral malleolus and deep to the superior peroneal retinaculum are the peroneus longus and peroneus brevis tendons. These tendons are responsible for ankle stability and movement.

Additionally, the calcaneofibular ligament is attached at the lateral malleolus. This ligament is important for maintaining the stability of the ankle joint and preventing excessive lateral movement.

Understanding the anatomy of the lateral malleolus is crucial for diagnosing and treating ankle injuries and conditions. Proper care and management of these structures can help prevent long-term complications and improve overall ankle function.

If there is a disc herniation at the L3-L4 level, it can impact the L4 spinal nerve and lead to issues with the femoral nerve’s function. A herniation at the L2-L3 level can cause L3 radiculopathy and result in weakness in hip adduction. On the other hand, a herniation at the L3-L4 level can cause L4 radiculopathy and lead to weakness in knee extension, with a greater contribution from L4 than L3, as well as a decrease in the patellar reflex.

Understanding Prolapsed Disc and its Features

A prolapsed disc in the lumbar region can cause leg pain and neurological deficits. The pain is usually more severe in the leg than in the back and worsens when sitting. The features of the prolapsed disc depend on the site of compression. For instance, compression of the L3 nerve root can cause sensory loss over the anterior thigh, weak quadriceps, reduced knee reflex, and a positive femoral stretch test. On the other hand, compression of the L4 nerve root can cause sensory loss in the anterior aspect of the knee, weak quadriceps, reduced knee reflex, and a positive femoral stretch test.

Similarly, compression of the L5 nerve root can cause sensory loss in the dorsum of the foot, weakness in foot and big toe dorsiflexion, intact reflexes, and a positive sciatic nerve stretch test. Lastly, compression of the S1 nerve root can cause sensory loss in the posterolateral aspect of the leg and lateral aspect of the foot, weakness in plantar flexion of the foot, reduced ankle reflex, and a positive sciatic nerve stretch test.

The management of prolapsed disc is similar to that of other musculoskeletal lower back pain, which includes analgesia, physiotherapy, and exercises. However, if the symptoms persist even after 4-6 weeks, referral for an MRI is appropriate. Understanding the features of prolapsed disc can help in early diagnosis and prompt management.

Understanding Prolapsed Disc and its Features

A prolapsed disc in the lumbar region can cause leg pain and neurological deficits. The pain is usually more severe in the leg than in the back and worsens when sitting. The features of the prolapsed disc depend on the site of compression. For instance, compression of the L3 nerve root can cause sensory loss over the anterior thigh, weak quadriceps, reduced knee reflex, and a positive femoral stretch test. On the other hand, compression of the L4 nerve root can cause sensory loss in the anterior aspect of the knee, weak quadriceps, reduced knee reflex, and a positive femoral stretch test.

Similarly, compression of the L5 nerve root can cause sensory loss in the dorsum of the foot, weakness in foot and big toe dorsiflexion, intact reflexes, and a positive sciatic nerve stretch test. Lastly, compression of the S1 nerve root can cause sensory loss in the posterolateral aspect of the leg and lateral aspect of the foot, weakness in plantar flexion of the foot, reduced ankle reflex, and a positive sciatic nerve stretch test.

The management of prolapsed disc is similar to that of other musculoskeletal lower back pain, which includes analgesia, physiotherapy, and exercises. However, if the symptoms persist even after 4-6 weeks, referral for an MRI is appropriate. Understanding the features of prolapsed disc can help in early diagnosis and prompt management.

The attachment point of the anterior cruciate ligament is the anterior intercondylar area of the tibia. From there, it extends in a posterolateral direction and inserts into the posteromedial aspect of the lateral femoral condyle.

The knee joint is the largest and most complex synovial joint in the body, consisting of two condylar joints between the femur and tibia and a sellar joint between the patella and femur. The degree of congruence between the tibiofemoral articular surfaces is improved by the presence of the menisci, which compensate for the incongruence of the femoral and tibial condyles. The knee joint is divided into two compartments: the tibiofemoral and patellofemoral compartments. The fibrous capsule of the knee joint is a composite structure with contributions from adjacent tendons, and it contains several bursae and ligaments that provide stability to the joint. The knee joint is supplied by the femoral, tibial, and common peroneal divisions of the sciatic nerve and by a branch from the obturator nerve, while its blood supply comes from the genicular branches of the femoral artery, popliteal, and anterior tibial arteries.

The correct diagnosis for this patient is osteomalacia, which is characterized by low serum calcium, low serum phosphate, raised ALP, and raised PTH. It is important to identify the risk factors for osteomalacia, such as decreased sunlight exposure, which can lead to vitamin D deficiency and subsequent hypocalcaemia. In response to hypocalcaemia, PTH levels increase, as seen in this case.

Acute pancreatitis is an incorrect diagnosis as it does not fit the patient’s clinical picture. Osteoarthritis is also an incorrect diagnosis as it would not cause changes in serum calcium, ALP, or PTH levels. Primary hyperparathyroidism is also an incorrect diagnosis as it is associated with high levels of PTH and calcium, which is not seen in this patient.

Lab Values for Bone Disorders

When it comes to bone disorders, certain lab values can provide important information about the condition. In cases of osteoporosis, calcium, phosphate, alkaline phosphatase (ALP), and parathyroid hormone (PTH) levels are typically normal. However, in osteomalacia, calcium and phosphate levels are decreased while ALP and PTH levels are increased. Primary hyperparathyroidism, which can lead to osteitis fibrosa cystica, is characterized by increased calcium and PTH levels but decreased phosphate levels. Chronic kidney disease can result in secondary hyperparathyroidism, which is marked by decreased calcium levels and increased phosphate and PTH levels. Paget’s disease, on the other hand, typically shows normal calcium and phosphate levels but increased ALP levels. Finally, osteopetrosis is associated with normal levels of calcium, phosphate, ALP, and PTH. By analyzing these lab values, healthcare professionals can better diagnose and treat bone disorders.

Osteogenesis imperfecta is caused by a defect in type 1 collagen, which is found in the skin, tendons, vasculature, and bones. This abnormality results in fragile bones, leading to multiple fractures, as seen in a child with deafness, blue sclera, and fractures. Type 2 collagen is present in cartilage and is not typically affected in osteogenesis imperfecta. Type 3 collagen is the primary component of reticular fibers, which are also not typically affected in this condition. Type 4 collagen makes up basement membranes, which are also not typically affected in osteogenesis imperfecta.

Understanding Osteogenesis Imperfecta

Osteogenesis imperfecta, also known as brittle bone disease, is a group of disorders that affect collagen metabolism, leading to bone fragility and fractures. The most common type of osteogenesis imperfecta is type 1, which is inherited in an autosomal dominant manner and is caused by decreased synthesis of pro-alpha 1 or pro-alpha 2 collagen polypeptides.

This condition typically presents in childhood, with individuals experiencing fractures following minor trauma. Other common features include blue sclera, deafness secondary to otosclerosis, and dental imperfections. Despite these symptoms, adjusted calcium, phosphate, parathyroid hormone, and ALP results are usually normal in individuals with osteogenesis imperfecta.

Overall, understanding the symptoms and underlying causes of osteogenesis imperfecta is crucial for proper diagnosis and management of this condition.

P-GO-GO-Q is a mnemonic for remembering the lateral hip rotators in order from top to bottom: Piriformis, Gemellus superior, Obturator internus, Gemellus inferior, Obturator externus, and Quadratus femoris.

Anatomy of the Hip Joint

The hip joint is formed by the articulation of the head of the femur with the acetabulum of the pelvis. Both of these structures are covered by articular hyaline cartilage. The acetabulum is formed at the junction of the ilium, pubis, and ischium, and is separated by the triradiate cartilage, which is a Y-shaped growth plate. The femoral head is held in place by the acetabular labrum. The normal angle between the femoral head and shaft is 130 degrees.

There are several ligaments that support the hip joint. The transverse ligament connects the anterior and posterior ends of the articular cartilage, while the head of femur ligament (ligamentum teres) connects the acetabular notch to the fovea. In children, this ligament contains the arterial supply to the head of the femur. There are also extracapsular ligaments, including the iliofemoral ligament, which runs from the anterior iliac spine to the trochanteric line, the pubofemoral ligament, which connects the acetabulum to the lesser trochanter, and the ischiofemoral ligament, which provides posterior support from the ischium to the greater trochanter.

The blood supply to the hip joint comes from the medial circumflex femoral and lateral circumflex femoral arteries, which are branches of the profunda femoris. The inferior gluteal artery also contributes to the blood supply. These arteries form an anastomosis and travel up the femoral neck to supply the head of the femur.