Herbs use full in hair growth

1-BHRINGRAJ

2- AMALA        

3-NEEM           

4- RITHA

5-SHIKAKAI

7-ASHWAGANDHA

8-BRAHAMI

9-JATAMANSI

10-METHI (FENUGREEK)

11-COCONUT

12-ALOE VERA

13-JOJOBA

14-YOGHURT

                       What to eat-

 1-Meat, fish, milk, cheese, eggs, yogurt, soybean

 2-Liver, fish oil, eggs, fortified milk; red, yellow, and orange vegetables are good    sources     of vitamin A, as are some dark green leafy vegetables like spinach.

3-Brown rice, Cauliflower, Mushrooms, Oats, Sunflower seeds, Walnuts, Soya, Peas, lentils, Cooked egg yolk, etc

4-Fresh peppers, citrus fruits, melons berries, potatoes, tomatoes and dark green leafy vegetables

5-Green leafy vegetables, nuts, grains, vegetable oils, and most ready-to-eat cereals, which are fortified with vitamin E.

6-Marmite, Calf's liver, Chickpeas, Endive

7-Green leafy vegetables, kidney beans, and bran

8-Seafood, oysters, oat

9-Good sources of copper are liver again, seafood, nuts, and seeds.

10-Rice, oats, lettuce, parsnips, asparagus, onion, strawberry, cabbage, cucumber, leek, sunflower seeds, celery, rhubarb, cauliflower, and Swiss chard.

Vomiting

1-Vomiting, also known as emesis, puking, barfing, throwing up, among other terms, is the involuntary, forceful expulsion of the contents of one's stomach through the mouth and sometimes the nose.

2-Vomiting can be caused by a wide variety of conditions; it may present as a specific response to ailments like gastritis or poisoning, or as a non-specific sequela of disorders ranging from brain tumors and elevated intracranial pressure to overexposure to ionizing radiation. The feeling that one is about to vomit is called nausea, which often proceeds, but does not always lead to, vomiting. Antiemetics are sometimes necessary to suppress nausea and vomiting. In severe cases, where dehydration develops, intravenousfluid may be required. Self-induced vomiting can be a component of an eating disorder, such as bulimia nervosa, and is itself now an eating disorder on its own, purging disorder.

Complications

1-Aspiration

2-Dehydration and electrolyte imbalance

3-Dentistry

Recurrent vomiting, such as observed in bulimia nervosa, may lead to destruction of the tooth enamel due to the acidity of the vomit. Digestive enzymes can also have a negative effect on oral health, by degrading the tissue of the gums.

4-Receptors on the floor of the fourth ventricle of the brain represent a chemoreceptor trigger zone, known as the area postrema, stimulation of which can lead to vomiting. The area postrema is a circumventricular organ and as such lies outside the blood–brain barrier; it can therefore be stimulated by blood-borne drugs that can stimulate vomiting or inhibit it.

Contents

Gastric secretions and likewise vomit are highly acidic. Recent food intake appears in the gastric vomit. Irrespective of the content, vomit tends to be malodorous.

The content of the vomitus (vomit) may be of medical interest.

1-      Fresh blood in the vomit is termed hematemesis ("blood vomiting"). Altered blood bears resemblance to coffee grounds (as the iron in the blood is oxidized) and, when this matter is identified, the term coffee-ground vomiting is used.

2-      If the vomiting reflex continues for an extended period with no appreciable vomitus, the condition is known as non-productive emesis or "dry heaves", which can be painful and debilitating.

Color of vomit

            1-Bright red      -            bleeding from the esophagus

      2- Dark red vomit with liver-like clots suggests profuse bleeding in the stomach, such as             from a perforated ulcer

     3-   Coffee-ground-like vomit suggests less severe bleeding in the stomach,

            4-Yellow vomit suggests bile, indicating that the pyloric valve is open and bile is flowing into the stomach from the duodenum (this is more common in older people)

Differential diagnosis

Vomiting may be due to a large number of causes, and protracted vomiting has a long differential diagnosis.

Digestive tract

•           Gastritis (inflammation of the gastric wall)

•           Gastroenteritis

•           Gastroesophageal reflux disease

•           Celiac disease

•           Non-celiac gluten sensitivity

•           Pyloric stenosis (in babies, this typically causes a very forceful "projectile vomiting" and is an indication for urgent surgery)

•           Bowel obstruction

•           Overeating

•           Acute abdomen and/or peritonitis

•           Ileus

•           Food allergies (often in conjunction with hives or swelling)

•           Cholecystitis, pancreatitis, appendicitis, hepatitis

•           Food poisoning

•           In children, it can be caused by an allergic reaction to cow's milk proteins (Milk allergy or lactose intolerance)

Causes in the sensory system:

•           Movement: motion sickness (which is caused by overstimulation of the labyrinthine canals of the ear)

•           Ménière's disease

Causes in the brain:

•           Concussion

•           Cerebral hemorrhage

•           Migraine

•           Brain tumors, which can cause the chemoreceptors to malfunction

•           Benign intracranial hypertension and hydrocephalus

Metabolic disturbances (these may irritate both the stomach and the parts of the brain that coordinate vomiting)

•           Hypercalcemia (high calcium levels)

•           Uremia (urea accumulation, usually due to renal failure)

•           Adrenal insufficiency

•           Hypoglycemia

•           Hyperglycemia

Pregnancy:

•           Hyperemesis, morning sickness

Drug reaction

•           Alcohol

•           opioids

•           selective serotonin reuptake inhibitors

•           many chemotherapy drugs

•           some entheogens (such as peyote or ayahuasca)

•           Norovirus (formerly Norwalk virus or Norwalk agent)

•           Swine influenza

•           Bulimia Nervosa

•           Purge disorder

Emetics

An emetic, such as syrup of ipecac, is a substance that induces vomiting when administered orally or by injection.

·         Salt water and mustard water have been used since ancient times as emetics.Care must be taken with salt, as excessive intake can potentially be harmful.

·         Copper sulfate was also used in the past as an emetic. It is now considered too toxic for this use.

·         Hydrogen peroxide is used as an emetic in veterinary practice.

Other types

            Projectile vomiting refers to vomiting that ejects the gastric contents with great force. It is a classic symptom of infantile hypertrophic pyloric stenosis, in which it typically follows feeding and can be so forceful that some material exits through the nose.

 Treatment

An antiemetic is a drug that is effective against vomiting and nausea. Antiemetics are typically used to treat motion sickness and the side effects of medications such as opioids and chemotherapy.

Antiemetics act by inhibiting the receptor sites associated with emesis. Hence,

 1-anticholinergics,

2-antihistamines,

3-dopamine antagonists,

4-serotonin antagonists, and cannabinoids

Epidemiology

Nausea and/or vomiting are the main complaints in 1.6% of visits to family physicians in Australia.

               1. SANDHIMUKTA (DISLOCATION OF BONY JOINTS )

Urpista , vislista, vivartita, avaksipta, atiksipta, and tiryak ksipta –are its six kinds.

SAMANYA LAKSANA – (general signs and symptoms )

Inability to perform actions such as extension, contraction, rotation and vigorous (quick ) movements, severe pain and inability to withstand touch (guarding) – are the general symptoms of dislocations.

Visesa laksana-specific symptoms of each kind-

1-In Utpista – Specific symptoms are – appearance of swelling on both the sides of the joint and pain , different kinds fo pain appearing especially at nights.

2-In Vislista- swelling is slight, pain is continuous (at both day and night ) and improper functioning of the joint.

3-In Vivartita- joint is shifted to any one di resulting in distortion of the part and pain.

4-In Avaksipta- drooping down (ptosis) of the joint and pain

5-In Atipksipta- both the (two) bones forming the joints are moved apart (making a gap in between) and pain.

6-In Tiryak ksipta- any one bone of the joint only is displaced to a side and produces pain.

joints of upper limb

INDEX

1.     INTRODUCTION

2.     STERNOCLAVICULAR  JOINT

3.     ACROMIOCLAVICULAR  JOINT

4.     CORACOCLAVICULAR  JOINT

5.     GLENOHUMERAL  JOINT

6.     ELBOW  JOINT

7.     PROXIMAL  RADIOULNAR  JOINT

8.     DISTAL  RADIOULNAR  JOINT

9.     RADIOCARPAL  JOINT

10.                        INTERCARPAL  JOINTS

11.                        CARPOMETACARPAL  AND  INTERMETACARPAL  JOINTS

12.                        FIRST  CARPOMETACARPAL  JOINT

13.                        METACARPOPHALANGEAL  AND  INTERPHALANGEAL  JOINTS

 

 

          INTRODUCTION

     Joints are  sites where two or more bones or cartilages articulate. Free movements occur at synovial joints. The shoulder girdle connects the upper limb to the axial skeleton . Shoulder joint is the most freely mobile joint. The carrying angle in relation to elbow joint is to facilitate carrying objects like buckets without hitting pelvis.

     Supination and pronation are basic movement for the survival of human being. During pronation , food is picked and by supination , it is put at the mouth.

     The first carpometacarpal joint allows movement of opposition of thumb with the fingers for picking up or   holding  things.

Joints of the Upper Limb

                1.Sternoclavicular  Joint

Ø     Type of joint  

•      Saddle type synovial joint; but it functions like a ball-and-socket joint

•      ATYPICAL: fibrocartilage cover articular surfaces

Ø     Articulating surfaces

•             Sternal facet of clavicle, clavicular facet of manubrium

•             There is also an ARTICULAR DISC

Ø     Articular capsule

•            Surrounds the joint, including the clavicular epiphysis

•            Attached to the articular disc

•            Lined with synovial membrane, contains synovial fluid

Ø    Ligaments

•           Anterior and posterior sternoclavicular ligaments

•           Interclavcular ligament

•            Costoclavicular ligament

Ø Stability factors

•      Not many muscles around, and the surfaces are incongruous, so the joint relies on the ligaments for stability.

•      Anterior and posterior sternoclavicular ligaments reinforce it anteriorly and posteriorly

•      Interclavicular ligament reinforces it superiorly

•      Costoclavicular ligament reinforces it inferiorly

•      Articular disc limits medial displacement

Ø Movements

•      Flexion, extension, rotation, anterior and posterior

•      movement, circumduction

Ø Blood supply

•      Internal thoracic and subscapular arteries

Ø Nerve supply

•      Nerve to subclavius

•      Medial supraclavicular nerve

                                     2. Acromioclavicular joint

Ø Type of joint

•      Plane type synovial joint

Ø Articulating surfaces

•      Acromial end of the clavicle, and the acromion process of the scapula

Ø Articular capsule

•      Attached to the margins of the articular surfaces Lined with synovial membrane Contai ns synovial fluid Strengthened superiorly by fibers from the trapezius

Ø Ligaments

•      Acromioclavicular ligament

•      Conoid ligament

•      Trapezoid ligament

Ø Stability factors

•      Coracoacromial ligament

•      Stability is maintained by extrinsic ligaments, far from the joint itself

•      Acromioclavicular ligament

•      Conoid and trapezoid ligaments anchor the clavicle to the coracoid process, suspending the free limb and scapula from the clavicle

Ø Movements

•      The acromian rotates on the clavicle

Ø Blood supply

•      Suprascapular and thoracoaromial arteries

Ø Nerve supply

•      Lateral pectoral and axillary nerve

•      Subcutaneous lateral supraclavicular nerve

3. Coracoclavicular joint

Ø Type of joint

•      Not really much of a joint, as the two bones don’t really articulate. There is a rare anatomical abnormality when they actually come into contact, but normally the coracoid process attaches indirectly to the clavicle by means of the strong coracoclavicular ligaments, the conoid and the trapezoid.

Ø Articulating surfaces

•      Normally, none.

•      The superior surface of the coracoid process attaches to the conoid and the trapezoid line of the clavicle by the ligaments abovementioned

Ø Articular capsule

•      No capsule

Ø Ligaments

•      Conoid ligament

•      Trapezoid ligament

Ø Stability factors

•      Conoid and trapezoid ligaments anchor the clavicle to the coracoid process, suspending the free limb and scapula from the clavicle

Ø Movements

•      There is limited movement at this joint; the clavicle rotates on the acromion.

Ø Blood supply

•      Suprascapular and thoracoaromial arteries

Ø Nerve supply

•      Lateral pectoral and axillary nerve

•      Subcutaneous lateral supraclavicular nerve

4. Glenohumeral joint

Ø Type of joint

•      Ball and socket synovial joint

Ø Articulating surfaces

•      Humeral head articulates with the glenoid cavity.

•      The cavity is deepened by the glenoid labrum.

•      About 1/3rd of the head actually sits in the cavity.

Ø Articular capsule

•      Attaches proximally to the margins of the glenoid cavity, and distally to the anatomical neck of the humerus.

•      IT HAS HOLES IN IT.

•      One hole admits the tendon of the long head of biceps brachii, and the other communicates with the subscapular bursa.

•      THE WEAKEST PART is the inferior part which is not reinforced by the rotator cuff muscles

Ø Ligaments

•      Glenohumeral ligaments: intrinsic ligaments, three fibrous thickenings of the capsule, anteriorly

•      Coracohumeral ligament – from the base of coracoid to the anterior aspect of the greater tubercle

•      Transverse humeral ligament- acts as the roof over the bicipital groove

•      Coracoacromial ligament- forms the roof over the glenohumeral joint

Ø Stability factors

•      The joint is too shallow to be stable; stability is sacrificed to mobility

•      The socket is deepened by the glenoid labrum

•      The joint is stabilized mainly by muscles:

§   supraspinatus

§   infraspinatus

§   teres minor

§   subscapularis

•      they hold the ball in the socket

•      the coracoacromial arch and supraspinatus tendon limit superior displacement

•      supraspinatus and teres minor limit posterior

Ø Movements

•      Greatest freedom of movement of any joint in the body

•      Flexion/extension, abduction/adduction, medial and lateral rotation, circumduction

•      Assisted by the movement of the pectoral girdle (the scapula and the clavicle)

Ø Blood supply

•      Anterior and posterior circumflex humeral arteries

•      Branches of the suprascapular artery

Ø Nerve supply

•      Suprascapular, axillary and lateral pectoral nerves.

Ø Clinical anatomy

•      FROZEN SHOULDER – Synovial membrane become adherent to each other.

•      SHOULDER TIP PAIN – Irritation of peritoneum underlying diaphragm due to surrounding pathology causes referred pain in shoulder.

Factors Influencing the Stability of the Glenohumeral Joint

•      MAINLY, THE ROTATOR CUFF: supraspinatus, infraspinatus, subscapularis and teres minor

•      They hold the head of humerus in the glenoid fossa

•      SOMEWHAT, THE LIGAMENTS:

•      Glenohumeral

•      Coracohumeral

•      Coracoacromial arch

•      SLIGHTLY, THE GLENOID LABRUM

5. Elbow Joint

Ø Type of joint

•      typical synovial hinge joint

Ø Articulating surfaces

•      Trochlea of humerus articulates with the trochlear notch of the ulna.

•      Capitulum of the humerus articulates with the head of radius the surfaces are most congruent when the arm is halfway pronated, and the elbow is flexed to a right angle.

Ø Articular capsule

•      laterally and medially, just attaches to the margins of the articular surfaces.

•      Anteriorly and posteriorly, the capsule comes up more proximally, to enclose the coronoid fossa and the olecranon fossa. Distally, it blends with the capsule of the proximal radioulnar joint .

Ø Ligaments

•      all are intrinsic- thickened parts of the joint capsule the lateral one is the Radial Collateral ligament - blends distally with the annular ligament of the radius; attaches to radial notch margins the medial one is the Ulnar Collateral ligament

•      - triangular, fan-like

•      - the ANTERIOR band is the STRONGEST

•      - the POSTERIOR band is the weakest

•      - the slender and feeble OBLIQUE band

•      merely serves to deepens the socket for the

•      trochlea of the humerus

Ø Stability factors

•      Major stability factor: bony alignment; The bones articulate well, the olecranon fossa limits hyperextension, and the coronoid fossa limits hyperflexion. The medial and lateral collateral ligaments serve to limit abduction and adduction- a minorstability factor

Ø Movements

•      It is PERMANENTLY ABDUCTED to 17 degrees:

•       The “carrying angle” = this angle is 10 degrees greater in women

•       it DISAPPEARS when the arm is PRONATED

•      but the elbow only allows flexion and extension

•      FLEXORS: biceps brachii, brachialis, brachioradialis

•      EXTENSORS: Triceps Brachii, Anconeus

•       when the forearm is supinated, the biceps brachii helps flex it

•       when the forearm is pronated, the pronator teres helps flex it.

•       major flexor is the brachialis; minor flexor is brachioradialis

Ø Blood supply

•      Derived from the anastomosis around the elbow joint

Ø Nerve supply

•      Musculocutaneous, ulnar and median nerve

Ø BURSAE: under every muscle attachment… the most important are:

•      - Intratendinous olecranon bursa sometimes inside the tendon of the triceps

•      - Subtendinous olecranon bursa between the olecranon and the triceps tendon

•      - Subcutaneous olecranon bursa in the subcutaneous tissue over the olecranon

Ø Clinical anatomy

•      Tennis elbow – Tenderness over lateral epicondyle of humerus.

•      Golfer’s elbow – Microtrauma of medial epicondyle of humerus.

•      Student’s (Miner’s)elbow - Effusion into bursa over subcutaneous posterior surface of the olecranon process .

•      Cubitus valgus – When carrying angle is more,ulnar nerve get stretched.

•      Cubitus varus   -  When carrying angle is less.

6. Proximal Radioulnar Joint

Ø Type of joint

•      Pivot type synovial joint

Ø Articulating surfaces

•      The head of radius articulates with the radial notch of  the ulna

Ø Articular capsule

•      The fibrous part blends into the elbow joint

•      The synovial part is continuous with the elbow joint

•      There is also a SACCIFORM RECESS of the joint, a distal extension of it down the radius which allows the radius to rotate without tearing the synovium

Ø Ligaments

•      The ANULAR ligament encircles the head of the radius

Ø Stability factors

•      The bones articulate well

•      The ANULAR ligament is the main stability factor, preventing dislocation of the radial head.

•      The INTEROSSEOUS MEMBRANE also prevents distraction of the radius

•      The joint is surrounded by muscles eg. brachioradialis and brachialis, which contribute to its stability in a minor way

Ø Movements

•      Pronation and supination

•      Supination is the palm turning up, as if to receive alms

•      The axis of rotation passes through the head of radius  and through the site of attachment of of radius and ulna  distally

•      THE RADIUS IS THE ONE THAT ROTATES the ulna stays stationary

Ø Blood supply

•      Supplied by the radial portion of the periarticular arterial anastomosis of the elbow, which is the anastomosis of radial and middle collateral arteries with the radial and recurrent inteosseous arteries

Ø Nerve supply

•      Supplied by the musculocutaneous, median and radial nerves, where  pronation is work of the median supination is the work of the radial and musculocutaneous nerves

7.Distal Radioulnar Joint

Ø Type of joint

•      Pivot type of synovial joint

Ø Articulating surfaces

•      The head of ulna articulates with the ulnar notch of the medial distal radius which separates the the cavity of the distal radioulnar joint from the cavity of the wrist joint

Ø Articular capsule

•      The synovial membrane extends supeiorly between the radius and the ulna to form a SACCIFORM RECESS, which accommodates for the twistng of the capsule.

Ø Ligaments

•      Intrinsic ANTERIOR and POSTERIOR ligaments strengthen the joint capsule

•      These are weak transverse bands

Ø Stability factors

•      The ARTICULAR DISC is the main uniting structure of the joint, because it bings the ends of the radius and the ulna together

Ø Movements

•      During pronation, the radius crosses the ulna

•      During supination, the radius is parallel with the ulna

•      Supination is produced by Supinator

•      Pronation is produced by the Pronator Quadratus as well as Pronator Teres FCR, PL and brachioradialis also help when the forearm is mid-pronated

Ø Blood supply

•      Anterior and posterior interosseous arteries

Ø Nerve supply

•      Anterior and posterior interosseous nerves

8. Radiocarpal joint

Ø Type of joint

•      Condyloid (ellipsoid) type of synovial joint

Ø Articulating surfaces

•      Three of the carpal bones (scaphoid, triquetrum and lunate) articulate with the radius

•      The pisiform and the ulna don’t participate

Ø Articular capsule

•      Stretches from the distal ends of the radius and ulna, to the proximal row of carpal bones (but not the pisiform)

Ø Ligaments

•      The PALMAR radiocarpal ligaments stretch from the radius to both of the two rows of carpal bones;

•      The DORSAL radiocarpal ligament does the same

•      these ligaments make sure the hand follows the radius in its rotation

•      the ULNAR COLLATERAL LIGAMENT passes from the ulnar styloid to the triquetrum

•      the RADIAL COLLATERAL LIGAMENT passes from the radial styloid to the triquetrum

Ø Clinical anatomy

•      RHEUMATOID ARTHRITIS

•      GANGLION – It is a cystic swelling resulting from mucoid degeneration of synovial sheaths around tendon.

9. Intercarpal joints

Ø Type of joint

•      Plane synocial joints

Ø Articulating surfaces

•      Joints between carpal bones of the middle row

•      Joints between carpal bones of the distal row

•      MIDCARPAL JOINT: between the proximal and distal rows of the joints

•      PISOTRIQUETRAL JOINT: articulation between the pisiform and the palmar surface of the triquetrum

Ø Articular capsule

•      The articular cavity is common to all intercarpal and carpometacarpal joints – EXCEPT the thumb, which has its own carpometacarpal capsule.

Ø Ligaments   -  All the carpals are united with anterior, posterior and interosseous ligaments

Ø Stability factors

•      The ligaments above contribute most;

•      The fibrous articular capsule wraps the carpal bones up, and keeps them together

Ø Movements

•      Slight movemens which extent the range of motion available at the radiocarpal joint

Ø Blood supply

•      Dorsal and palmar carpal arches

Ø Nerve supply

•      Anterior interosseous branch of the median nerve

•      Dorsal and deep branches of the ulnar nerve

10. Carpometacarpal and Intermetacarpal joints

Ø Type of joint

•      Plane type synovial joints- EXCEPT the carpometacarpal joint of the thumb, which is a saddle type joint

Ø Articulating surfaces

•      Distal surfaces of the carpal bones articulate with the bases of the metacarpals

•      The important thumb joint is the articulation between the trapezium and the bease of the first metacarpal

•      The INTERMETACARPAL joints ar adjacent metacarpals articulating with each other’s bases

Ø Articular capsule

•      The medial four carpometacarpal joints, and the three intermetacarpal joints, are all enclosed by the same articular capsule.

•      The thumb CMC joint has its own capsule

Ø Ligaments

•      All thse bones are united by the palmar and dorsal carpometacarpal ligaments, and by the intermetacarpal ligaments.

•      The DEEP TRANSVERSE METACARPAL LIGAMENT and the SUPERFICIAL TRANSVERSE METACARPAL LIGAMENT (which is part of the palmar aponeurosis) both work to prevent separation of the metacarpal bases

Ø Stability factors

•      The above ligaments are he major stability factors

Ø Movements

•      Almost no movement at the CMCs of the 2nd and 3rd fingers,

•      Slight movement at the 4th CMC

•      Moderate movement of the 5th CMC (flexion, extension and rotation)

Ø Blood supply

•      Periarticular arterial anasomoses of the wrist and hand (basically, the arterial arches)

Ø Nerve supply

•      Anterior interosseous branch of the median nerve, posterior interossous branch of the radial nerve, and dorsal and deep branches of the ulnar nerve

Ø Clinical anatomy

•      De Quervains tenosynovitis – Synovial lining of tendons of extensor pollicis brevis and abductor pollicis longus can get inflamed due to repetitive strain and causes painful condition.

11. First carpometacarpal joint

Ø Type of joint

•      Saddle-type synovial joint

Ø Articulating surfaces

•      Trapezium and the base of the 1st metacarpal

Ø Articular capsule

•      Coveres the articulating surfaces

Ø Ligaments

•      anterior oblique (volar) ligament (AOL)

•      dorsoradial ligament,

•      posterior oblique ligament

•      intermetacarpal ligament.

Ø Stability factors  -  Ligaments, mainly

Ø Movements

•      Angular movements in any plane:

•      Flexion- extension

•      Adduction-abduction

•      (thus, circumduction)

•      opposition

Ø Blood supply

•      Periarticular arterial anasomoses of the wrist and hand (basically, the arterial arches)

Ø Nerve supply

•      Anterior interosseous branch of the median nerve, posterior interossous branch of the radial nerve, and dorsal and deep branches of the ulnar nerve

Ø Clinical anatomy

•      The joint can undergo degenerative changes with age which causes a painful condition of base of the thumb.

12. Metacarpophalangeal and interphalangeal joints

Ø Type of joint

•      Metacarpophalangeal joints are condyloid synovial joints

•      Interphalangeal joints are hinge joints

Ø Articulating surfaces

•      Bases and heads

Ø Articular capsule

•      Joint capsules surround each joint, attaching to the margins

Ø Stability factor

•      ligaments

Ø Movements

•      MCPS: flexion, extension, adduction, abduction

Ø Ligaments

•      Each MCP ad ICP joint is reinforced by a medial and lateral collateral ligaments

•      Each of these ligaments has two parts:

•      The dense cord-like part passes from one head to the next base; the thin fan-like part passes anteriorly to fuse with the anterior (palmar) part of the joint capsule

•      The cord-like parts are slack dring extension and taught during flexion- this means you usually cannot spread (abduct) the fingers when the fingers are fully flexed

•      The fan-like parts move like a visor over the underlying heads

•      The palmar ligament (thick part of the capsule) blend with the digital sheaths and provide grooves for the flexor tendons to glide in.

•      At the MCPs, THE PALMAR LIGAMENTS ARE UNITED by the deep transverse metacarpal ligament  

Ø Blood supply

•      Digital arteries

Ø Nerve supply

•      Digital nerves from the median and ulnar nerves