Upper limb

The upper limb, also known as the upper extremity, is a functional unit of the human body that extends from the shoulder to the hand, comprising the arm (brachium), forearm (antebrachium), and hand (manus). It enables essential movements such as grasping, reaching, manipulating objects, and providing sensory feedback for proprioception and touch.^[1] The upper limb consists of 30 bones, including the humerus in the arm, the radius and ulna in the forearm, eight carpals, five metacarpals, and 14 phalanges in the hand. These provide structural support and facilitate joint articulations, anchored to the trunk via the pectoral girdle (scapula and clavicle) for shoulder mobility. For detailed skeletal components, see the Anatomy section.^[1]^[2] Approximately 60 muscles organized into compartments enable precise control and power for these functions. The upper limb is innervated primarily by the brachial plexus (C5–T1) and supplied by branches of the subclavian artery, supporting coordinated motor and sensory activities. Detailed descriptions of muscles and neurovasculature are covered in the Anatomy section.^[3]^[1]

Overview

Definition

The upper limb, also known as the upper extremity, is the region of the human body that extends from the pectoral girdle to the distal phalanges of the hand, forming a key component of the appendicular skeleton.^[4] The pectoral girdle, consisting of the clavicle and scapula, anchors the upper limb to the axial skeleton at the shoulder, while the free portion includes the arm (humerus), forearm (radius and ulna), wrist (carpal bones), and hand (metacarpals and phalanges).^[5] This structure encompasses 32 bones per side—4 in the girdle and 28 in the free limb—enabling a wide range of motion from the shoulder to the fingertips.^[4] In contrast to the lower limb, which is primarily adapted for weight-bearing and locomotion through stable pelvic attachments and robust skeletal elements, the upper limb is specialized for mobility, prehension, and fine manipulation, reflecting evolutionary priorities for tool use and environmental interaction in primates and humans.^[1] Its basic composition integrates bones with synovial joints for articulation, skeletal muscles for movement, peripheral nerves from the brachial plexus for sensory and motor innervation, and a vascular network derived from the subclavian artery and accompanying veins to support dexterity and endurance.^[6] The nomenclature of the upper limb draws from classical Latin and Greek roots, with "brachium" denoting the arm (from the shoulder to elbow) and "manus" referring to the hand, terms established in early anatomical texts like those of Galen and later standardized in Renaissance works by Vesalius.^[7] These etymologies underscore the limb's historical recognition as a versatile appendage, distinct in form and function from the lower extremity.^[5]

Functions

The upper limb plays a pivotal role in human physiology by facilitating manipulation and prehension, which involve grasping, reaching, and executing fine motor tasks through the hand's exceptional dexterity. This capability is enabled by the thumb's opposability and the coordinated action of the fingers, allowing precise object handling essential for daily activities such as writing or tool manipulation.^[1] The structure supports a range of grip types, from power grips for heavy objects to precision grips for delicate tasks, enhancing environmental interaction and productivity.^[1] Sensory functions of the upper limb provide critical tactile feedback through skin receptors and proprioception, enabling spatial awareness and accurate movement control. Tactile sensations detect pressure, texture, and temperature via mechanoreceptors in the skin, while proprioceptors in muscles and joints convey information about limb position and motion to the central nervous system.^[8] This sensory integration allows for seamless adjustment during tasks, preventing errors and supporting adaptive responses.^[8] In supportive roles, the upper limb contributes to weight-bearing in postures like quadrupedal support or push-up positions, distributing body load through the shoulder girdle and elbow for stability.^[9] Additionally, it facilitates communication through gestures, such as pointing or waving, which convey non-verbal information and enhance social interaction.^[10] The upper limb's integration with the central nervous system underscores its significance in tool use and the cultural evolution of human dexterity. This connection has driven evolutionary adaptations, allowing early hominins to manipulate objects and innovate technologies, shaping cognitive and societal development.^[11]

Anatomy

Skeletal components

The skeletal components of the upper limb provide the rigid framework essential for support, mobility, and manipulation, consisting of the pectoral girdle, humerus, radius, ulna, and the bones of the hand. These elements articulate to form a flexible appendage capable of a wide range of movements, with specific features like articular surfaces and fossae facilitating joint stability and motion.^[12] The pectoral girdle anchors the upper limb to the axial skeleton and includes the clavicle and scapula. The clavicle, an S-shaped long bone, articulates medially with the manubrium of the sternum at the sternoclavicular joint and laterally with the acromion process of the scapula at the acromioclavicular joint; its sternal end is triangular and enlarged, while the acromial end is flattened and oval.^[13] The scapula, a flat triangular bone, features the acromion process projecting anteriorly to articulate with the clavicle, the coracoid process serving as an attachment site, and the glenoid cavity—a shallow, pear-shaped articular surface deepened by the glenoid labrum for humeral articulation at the glenohumeral joint.^[13] The humerus forms the skeleton of the arm, extending from the shoulder to the elbow. Proximally, it includes a rounded head that articulates with the glenoid cavity and two tubercles—the larger greater tubercle laterally and the smaller lesser tubercle anteriorly—for rotator cuff attachments. The shaft is cylindrical with a deltoid tuberosity midway. Distally, the humerus features the capitulum (a lateral rounded condyle articulating with the radius), the trochlea (a medial pulley-shaped condyle articulating with the ulna), the medial and lateral epicondyles for ligament attachments, and fossae such as the anterior coronoid and radial fossae (accommodating ulnar and radial processes during flexion) and the posterior olecranon fossa (for the ulna during extension).^[13] The forearm comprises the radius and ulna, parallel long bones connected by the interosseous membrane, a fibrous sheet that binds their shafts and transmits forces between them. The radius, lateral and shorter, has a disc-shaped head proximally that articulates with the capitulum of the humerus and the radial notch of the ulna; distally, it features a styloid process projecting laterally for ligament attachment. The ulna, medial and longer, includes a proximal olecranon process and trochlear notch articulating with the humeral trochlea, a radial notch for the radius, and a distal styloid process medially.^[13] The hand skeleton includes the carpals, metacarpals, and phalanges, enabling precise dexterity. The eight carpal bones, arranged in two rows, are the proximal scaphoid (with a tubercle and waist prone to fracture), lunate, triquetrum, and pisiform (sesamoid-like), and the distal trapezium (saddle-shaped for thumb articulation), trapezoid, capitate, and hamate (with a hook); they form the wrist's concavity for flexor tendon passage. The five metacarpals are elongated bones with bases articulating proximally with the carpals at carpometacarpal joints and heads distally with phalanges at metacarpophalangeal joints; the first (thumb) is the shortest and most mobile. The 14 phalanges consist of proximal, middle (absent in thumb), and distal bones per digit, with bases articulating proximally and heads distally forming interphalangeal joints; the thumb has two (proximal and distal), while fingers have three each.^[13] Ossification of upper limb bones begins in utero via primary centers in diaphyses and secondary centers in epiphyses, with fusion occurring postnatally; timelines vary by bone and sex (earlier in females). The clavicle ossifies first intramembranously at 6 weeks gestation in the diaphysis, with a secondary sternal epiphysis appearing at 18-20 years and full union by 20-25 years.^[14] Scapular ossification starts at 8 weeks gestation for the body, spine, and glenoid (primary center), with coracoid at 1 year and epiphyses for acromion (15-18 years), inferior angle (16-18 years), vertebral border (18-20 years), and coracoid/glenoid (16-18 years), uniting by 18-25 years.^[14] The humerus has a primary diaphyseal center at 6-7 weeks, with epiphyses for head (1-2 years), greater tubercle (2-3 years), lesser tubercle (3-5 years), capitulum (2-3 years), medial epicondyle (5-8 years), and lateral epicondyle/trochlea (11-14 years), fusing by 16-25 years.^[14] Radius and ulna diaphyses appear at 7 weeks; radius epiphyses at carpal end (females 8 months, males 15 months) and humeral end (6-7 years), ulna at carpal end (females 6-7 years, males 7-8 years) and humeral end (10 years), with unions by 17-25 years and 17-24 years, respectively.^[14] Carpal ossification is delayed: capitate (females 3-6 months, males 4-10 months), hamate (females 5-10 months, males 6-12 months), triquetrum (females 2-3 years, males ~3 years), lunate (females 3-4 years, males ~4 years), scaphoid (females 4-5 years, males ~5 years), trapezium/trapezoid (females 4-5 years, males 5-6 years), pisiform (females 9-10 years, males 12-13 years). Metacarpal diaphyses form at 9 weeks, with proximal first metacarpal epiphysis at 3 years and distal others at 2 years, uniting by 15-20 years. Phalangeal diaphyses ossify at 7-12 weeks (distal row first, then proximal and middle), with proximal epiphyses at 1-3 years and unions by 18-20 years.^[14]

Bone	Primary Center (Diaphysis)	Key Secondary Centers (Epiphyses)	Union Timeline
Clavicle	6 weeks gestation	Sternal end: 18-20 years	20-25 years
Scapula	8 weeks gestation (body/glenoid)	Acromion: 15-18 years; Coracoid: 1 year (initial), 16-18 years (final); Inferior angle: 16-18 years	18-25 years
Humerus	6-7 weeks gestation	Head: 1-2 years; Greater tubercle: 2-3 years; Capitulum: 2-3 years; Medial epicondyle: 5-8 years; Trochlea: 11-14 years	16-25 years
Radius	7 weeks gestation	Distal (carpal): Females 8 months, males 15 months; Proximal (humeral): 6-7 years	17-25 years
Ulna	7 weeks gestation	Distal (carpal): Females 6-7 years, males 7-8 years; Proximal (humeral): 10 years	17-24 years
Carpals	Variable, postnatal	Capitate: Females 3-6 months, males 4-10 months; Pisiform: Females 9-10 years, males 12-13 years	N/A (no epiphyses)
Metacarpals	9 weeks gestation	Distal: 2 years; Proximal (1st): 3 years	15-20 years
Phalanges	7-12 weeks gestation	Proximal: 1-3 years	18-20 years

^[14]

Joints and ligaments

The upper limb features a series of synovial joints that provide extensive mobility, from the proximal shoulder to the distal finger articulations, stabilized by ligaments that prevent excessive translation while permitting multi-planar motion. These joints are classified based on their morphology and function, with degrees of freedom ranging from uniaxial to triaxial, enabling precise manipulation and reach.^[15] The glenohumeral joint, also known as the shoulder joint, is a multiaxial ball-and-socket synovial joint formed by the articulation of the humeral head with the glenoid cavity of the scapula. It allows flexion-extension, abduction-adduction, and internal-external rotation across three rotational axes, providing the widest range of motion in the body. The joint is enclosed by a loose fibrous capsule reinforced by glenohumeral ligaments, and the glenoid labrum—a fibrocartilaginous rim—deepens the shallow glenoid socket to enhance stability.^[16]^[17]^[18] The elbow complex comprises the humeroulnar and humeroradial articulations forming a uniaxial hinge joint for flexion-extension, combined with the proximal radioulnar pivot joint enabling pronation-supination. This setup allows two degrees of freedom: one for hinging and one for rotation. Stability is augmented by the annular ligament, which encircles the radial head and binds it to the ulna, preventing subluxation during forearm rotation.^[19]^[20]^[21] The radiocarpal joint, or wrist joint, is a biaxial ellipsoid synovial joint between the distal radius and the proximal carpal row (scaphoid, lunate, and triquetrum), permitting flexion-extension and radial-ulnar deviation. Its stability relies on collateral ligaments, including the radial collateral (from radius to scaphoid and trapezium) and ulnar collateral (from ulna to triquetrum), which resist lateral deviations.^[22]^[23]^[24] In the hand, the carpometacarpal (CMC) joint of the thumb is a unique saddle synovial joint between the trapezium and first metacarpal, allowing opposition and circumduction with three degrees of freedom for enhanced dexterity. The metacarpophalangeal (MCP) joints are condyloid synovial joints between metacarpals and proximal phalanges, supporting flexion-extension, abduction-adduction, and circumduction in two planes. Interphalangeal (IP) joints, including proximal and distal, are uniaxial hinge synovial joints between phalanges, restricted to flexion-extension for precise gripping.^[25]^[26]^[27]^[28] Key ligaments throughout the upper limb include the coracoclavicular ligament, which connects the coracoid process to the clavicle, suspending the scapula and preventing acromioclavicular dislocation under the weight of the arm. The transverse humeral ligament spans the intertubercular groove of the humerus, retaining the long head of the biceps tendon within the groove during shoulder motion. At the wrist, palmar and dorsal radiocarpal ligaments extend from the radius to the carpals, limiting excessive flexion and extension while guiding carpal alignment.^[23]^[29]^[24] All upper limb joints are synovial, featuring a cavity filled with synovial fluid secreted by the synovial membrane, which lubricates articular surfaces to minimize friction and provides nutrients to avascular cartilage. This fluid's viscous properties absorb shock and facilitate smooth gliding, essential for the limb's repetitive, high-mobility demands.^[26]^[24]^[30]

Muscles

The muscles of the upper limb enable a wide range of movements, from gross shoulder motions to fine hand manipulations, and are organized into functional groups based on their anatomical regions and actions. These muscles vary in architecture, with fusiform types like the biceps brachii featuring parallel fibers for greater excursion and speed, while pennate types, such as the unipennate flexor pollicis longus or multipennate subscapularis, have oblique fibers attaching to tendons for enhanced force production through larger physiological cross-sectional areas.^[31]^[32] Shoulder muscles primarily stabilize and move the glenohumeral joint, with the rotator cuff providing dynamic stability and others effecting abduction, adduction, and rotation. The supraspinatus originates from the supraspinous fossa of the scapula and inserts on the greater tubercle of the humerus; it is innervated by the suprascapular nerve (C5-C6) and primarily abducts the arm. The infraspinatus arises from the infraspinous fossa and inserts on the greater tubercle; innervated by the suprascapular nerve (C5-C6), it laterally rotates the arm. The teres minor originates from the upper two-thirds of the lateral border of the scapula and inserts on the greater tubercle; supplied by the axillary nerve (C5-C6), it laterally rotates the arm and assists in adduction. The subscapularis originates from the subscapular fossa and inserts on the lesser tubercle; innervated by the upper and lower subscapular nerves (C5-C7), it medially rotates the arm. The deltoid originates from the clavicle, acromion, and spine of the scapula, inserting on the deltoid tuberosity of the humerus; innervated by the axillary nerve (C5-C6), it abducts the arm and assists in flexion, extension, and rotation depending on the fiber portion. The pectoralis major originates from the clavicle, sternum, and costal cartilages of ribs 2-6, inserting on the intertubercular groove of the humerus; supplied by the lateral and medial pectoral nerves (C5-T1), it flexes, adducts, and medially rotates the arm.^[31]^[33]

Muscle	Origin	Insertion	Innervation	Primary Action
Supraspinatus	Supraspinous fossa	Greater tubercle of humerus	Suprascapular nerve	Abducts arm
Infraspinatus	Infraspinous fossa	Greater tubercle of humerus	Suprascapular nerve	Laterally rotates arm
Teres minor	Lateral border of scapula	Greater tubercle of humerus	Axillary nerve	Laterally rotates arm
Subscapularis	Subscapular fossa	Lesser tubercle of humerus	Subscapular nerves	Medially rotates arm
Deltoid	Clavicle, acromion, scapular spine	Deltoid tuberosity	Axillary nerve	Abducts arm
Pectoralis major	Clavicle, sternum, ribs 2-6	Intertubercular groove of humerus	Pectoral nerves	Flexes, adducts, medially rotates arm

Arm muscles act mainly at the elbow joint for flexion and extension. The biceps brachii has two heads: the long head originates from the supraglenoid tubercle of the scapula, and the short head from the coracoid process; both insert on the radial tuberosity and bicipital aponeurosis; innervated by the musculocutaneous nerve (C5-C6), it flexes the forearm and supinates the hand. The triceps brachii has three heads originating from the infraglenoid tubercle (long head), posterior humerus (lateral and medial heads), inserting on the olecranon process of the ulna; supplied by the radial nerve (C6-C8), it extends the forearm. The brachialis originates from the anterior distal humerus and inserts on the coronoid process and tuberosity of the ulna; innervated by the musculocutaneous nerve (C5-C6), with a minor contribution from the radial nerve, it flexes the forearm. Regional innervation for arm muscles centers on the musculocutaneous nerve for flexors and the radial nerve for the extensor.^[31]

Muscle	Origin	Insertion	Innervation	Primary Action
Biceps brachii (long/short heads)	Supraglenoid tubercle/coracoid process	Radial tuberosity	Musculocutaneous nerve	Flexes forearm, supinates hand
Triceps brachii	Infraglenoid tubercle, posterior humerus	Olecranon process	Radial nerve	Extends forearm
Brachialis	Anterior distal humerus	Coronoid process of ulna	Musculocutaneous nerve	Flexes forearm

Forearm muscles are divided into anterior (flexor-pronator) and posterior (extensor-supinator) compartments, facilitating wrist, hand, and digit movements; many feature long tendons passing through synovial sheaths to reduce friction. Flexors like the flexor carpi radialis originate from the medial epicondyle of the humerus and insert on the bases of the second and third metacarpals; innervated by the median nerve (C6-C7), it flexes and abducts the wrist. Extensors such as the extensor digitorum arise from the lateral epicondyle via the common extensor tendon and insert on the extensor expansions of digits 2-5; supplied by the posterior interosseous nerve (C7-C8), a radial nerve branch, it extends the wrist and digits. Pronators and supinators include the pronator teres, originating from the medial epicondyle and coronoid process of the ulna, inserting on the mid-lateral radius; innervated by the median nerve (C6-C7), it pronates the forearm. The supinator originates from the lateral epicondyle, radial collateral ligament, and ulna, inserting on the proximal radius; supplied by the deep branch of the radial nerve (C5-C6), it supinates the forearm. In the forearm, flexor tendons travel within a common synovial sheath (ulnar bursa) under the flexor retinaculum, extending proximally into the forearm and distally for the little finger, while the flexor pollicis longus has a separate radial bursa; extensor tendons pass under the extensor retinaculum with individual synovial sheaths for each, minimizing friction during wrist extension. Innervation for flexors is primarily median nerve, with ulnar for some medial muscles, while extensors rely on radial nerve branches.^[31]^[34]^[35]

Muscle Example	Compartment	Origin	Insertion	Innervation	Primary Action
Flexor carpi radialis	Anterior	Medial epicondyle	Bases of metacarpals 2-3	Median nerve	Flexes, abducts wrist
Extensor digitorum	Posterior	Lateral epicondyle	Extensor expansions digits 2-5	Posterior interosseous nerve	Extends wrist, digits
Pronator teres	Anterior	Medial epicondyle, coronoid process	Mid-radius	Median nerve	Pronates forearm
Supinator	Posterior	Lateral epicondyle, ulna	Proximal radius	Deep radial nerve	Supinates forearm

Intrinsic hand muscles control precise finger and thumb motions, located in the thenar, hypothenar, and central compartments, often with short tendons or direct insertions. The thenar group includes the abductor pollicis brevis, originating from the flexor retinaculum and tubercle of the scaphoid, inserting on the proximal phalanx of the thumb; innervated by the recurrent branch of the median nerve (C8-T1), it abducts the thumb. Hypothenar muscles like the abductor digiti minimi originate from the pisiform bone and flexor retinaculum, inserting on the proximal phalanx of the little finger; supplied by the deep branch of the ulnar nerve (C8-T1), it abducts the little finger. The palmar interossei (unipennate) originate from the medial sides of metacarpals 2, 4, and 5, inserting on the extensor expansions and proximal phalanges; innervated by the ulnar nerve (C8-T1), they adduct the fingers toward the midline. Dorsal interossei (bipennate) originate from adjacent sides of metacarpals, inserting similarly; also ulnar-innervated (C8-T1), they abduct the fingers. Lumbricals originate from the tendons of flexor digitorum profundus, inserting on the extensor expansions of digits 2-5; the first two are median-innervated (C8-T1), the latter two ulnar (C8-T1), flexing metacarpophalangeal joints while extending interphalangeal joints. In the hand, digital fibrous and synovial sheaths enclose flexor tendons of digits 2-5, extending from metacarpal heads to the distal phalanges, with a 1-3 cm gap from the common flexor sheath; extensor tendons lack extensive sheaths beyond the wrist but form expansions over the digits. Hand muscle innervation is dominated by the median nerve for thenar and lateral lumbricals, and ulnar for hypothenar, interossei, and medial lumbricals.^[31]^[35]^[32]

Muscle Group/Example	Origin	Insertion	Innervation	Primary Action
Thenar (abductor pollicis brevis)	Flexor retinaculum, scaphoid	Proximal phalanx of thumb	Median nerve	Abducts thumb
Hypothenar (abductor digiti minimi)	Pisiform, flexor retinaculum	Proximal phalanx of digit 5	Ulnar nerve	Abducts little finger
Palmar interossei	Medial metacarpals 2,4,5	Extensor expansions	Ulnar nerve	Adduct fingers
Dorsal interossei	Adjacent metacarpals	Extensor expansions	Ulnar nerve	Abduct fingers
Lumbricals	Flexor digitorum profundus tendons	Extensor expansions digits 2-5	Median/ulnar nerves	Flex MCP, extend IP joints

Neurovasculature

The neurovasculature of the upper limb encompasses the intricate network of nerves and blood vessels that provide sensory and motor innervation as well as arterial supply and venous drainage to the region. The primary neural structure is the brachial plexus, which originates from the anterior rami of spinal nerves C5 through T1. These roots emerge from the intervertebral foramina and unite to form three trunks in the posterior triangle of the neck: the superior trunk from C5-C6, the middle trunk from C7, and the inferior trunk from C8-T1.^[36]^[37] Each trunk subsequently divides into anterior and posterior divisions behind the middle scalene muscle, yielding six divisions that rearrange into three cords around the axillary artery: the lateral cord (from anterior divisions of superior and middle trunks), the posterior cord (from posterior divisions of all trunks), and the medial cord (from the anterior division of the inferior trunk).^[36]^[37] The cords give rise to the major terminal branches, including the musculocutaneous nerve (from the lateral cord), median nerve (from lateral and medial cords), ulnar nerve (from the medial cord), radial nerve (from the posterior cord), and axillary nerve (from the posterior cord).^[36]^[37] The nerves of the brachial plexus mediate sensory, motor, and autonomic functions essential for upper limb operation. Sensory innervation follows dermatomal patterns, with C5 covering the lateral shoulder, C6 the lateral forearm and thumb, C7 the middle fingers, C8 the medial forearm and little finger, and T1 the medial upper arm.^[38] Motor innervation corresponds to myotomes, where C5 supplies shoulder abductors, C6 elbow flexors, C7 elbow extensors, C8 finger flexors, and T1 intrinsic hand muscles.^[38] Autonomic components, primarily sympathetic fibers from the T1 root via gray rami communicantes, reach the upper limb through the major nerves to regulate vasomotor tone and sweat glands.^[38] Arterial supply to the upper limb begins with the subclavian artery, which continues as the axillary artery from the lateral border of the first rib to the inferior border of the teres major muscle. The axillary artery then becomes the brachial artery in the arm, descending medial to the humerus and bifurcating at the cubital fossa into the radial and ulnar arteries.^[39] The radial artery courses laterally along the radius to the wrist, while the ulnar artery travels medially along the ulna; both contribute to the hand's circulation via the superficial palmar arch (primarily ulnar) and deep palmar arch (primarily radial), which anastomose to supply the palmar and digital vessels.^[40]^[41] Venous drainage parallels the arterial system, divided into superficial and deep components that ultimately converge into the axillary vein. Superficial veins include the cephalic vein, which drains the lateral hand and forearm along the radial side and ascends laterally to join the axillary vein, and the basilic vein, which drains the medial hand and forearm along the ulnar side and pierces the deep fascia midway up the arm to form the axillary vein with the brachial veins.^[42] Deep veins, such as the paired brachial veins accompanying the brachial artery and the radial and ulnar veins in the forearm, provide the primary return flow.^[43] Lymphatic pathways follow venous routes, with superficial lymphatics from the hand draining laterally via the cephalic vein to infraclavicular nodes or medially via the basilic vein to supratrochlear nodes, while deep lymphatics accompany arteries to axillary nodes before entering the subclavian lymphatic duct.^[42] Anastomotic networks ensure collateral circulation throughout the upper limb. Around the scapula, the scapular anastomosis connects branches of the subclavian (e.g., suprascapular and transverse cervical arteries) with the axillary artery's subscapular and circumflex scapular branches, forming a robust collateral pathway. At the elbow, anastomoses between the brachial artery's profunda brachii, superior ulnar collateral, and inferior ulnar collateral arteries link with radial and ulnar recurrent branches for alternative flow.^[44] In the palm, the superficial and deep palmar arches interconnect the radial and ulnar arteries, supplemented by dorsal carpal and metacarpal anastomoses, to maintain perfusion despite occlusions.^[41] Clinically, key pulse points for assessing arterial patency are the brachial artery, palpated in the medial bicipital groove of the arm for blood pressure measurement, and the radial artery, located at the wrist's radial styloid process for routine pulse evaluation.^[45]^[46]

Biomechanics and Movement

Kinematics

The kinematics of the upper limb describes the geometric aspects of its motion without considering forces, focusing on the spatial configurations and trajectories achievable through joint articulations. The upper limb functions as a serial kinematic chain, comprising the shoulder complex, elbow, forearm, wrist, and hand, which collectively enable a wide range of positions for the hand in three-dimensional space. Motion occurs primarily through synovial joints that permit rotation and, in some cases, translation, allowing for precise manipulation and reach. These movements are constrained by joint morphology and ligamentous structures, which the joints and ligaments section details further.^[16] Key joint ranges of motion define the limits of upper limb mobility. At the shoulder (glenohumeral joint), flexion reaches up to 180° in the sagittal plane, while extension is approximately 60°; these values align with normative standards established by the American Academy of Orthopaedic Surgeons (AAOS). The elbow joint, a hinge, allows flexion up to 150°, facilitating folding of the forearm toward the upper arm. Wrist deviation includes radial deviation of about 20° and ulnar deviation of 30° in the frontal plane, enabling side-to-side tilting essential for grasping. These ranges vary slightly by individual factors such as age and sex but represent typical healthy adult capabilities.^[47]^[48]^[49] Upper limb motions are organized around three primary anatomical axes corresponding to the cardinal planes of the body. Flexion and extension occur about the frontal (coronal) axis in the sagittal plane, abduction and adduction about the sagittal axis in the frontal plane, and internal/external rotation about the longitudinal (vertical) axis in the transverse plane. The shoulder complex exhibits the broadest mobility, with rotations in all three planes, while the elbow primarily flexes/extends and the forearm pronates/supinates around its long axis. The hand and fingers add further complexity through multi-planar motions at the carpometacarpal and interphalangeal joints. Degrees of freedom (DOF) quantify the independent parameters needed to specify the limb's configuration. The glenohumeral joint possesses 6 DOF, comprising three rotational (flexion/extension, abduction/adduction, internal/external rotation) and three translational components along the x, y, and z axes, owing to its ball-and-socket design that permits both pivoting and sliding. The elbow contributes 2 DOF: one for flexion/extension at the humeroulnar joint and one for pronation/supination at the proximal radioulnar joint. The wrist adds 2-3 DOF for flexion/extension and deviation, while the hand provides multiple DOF—approximately 20 in total across the thumb (for opposition) and fingers—enabling fine dexterity through combinations of flexion, extension, abduction, and adduction. Overall, the upper limb chain offers 27-30 DOF, far exceeding the 6 needed for full spatial positioning, which introduces redundancy for versatile task execution.^[50]^[51]^[52] To model multi-joint upper limb motions, coordinate systems employ Euler angles, which decompose complex three-dimensional rotations into sequential rotations about fixed or body axes (e.g., Z-X-Y sequence for shoulder girdle). This approach facilitates kinematic analysis of the arm as a chain, where each segment's orientation relative to the previous is calculated using rotation matrices; for instance, shoulder elevation combines humeral elevation and scapular rotation via Euler angles to track end-effector position. Such representations are standard in biomechanics for simulating reaching or manipulating tasks.^[53] Advanced kinematic descriptions incorporate instant centers of rotation (ICR) and screw theory to capture non-spherical joint behaviors. The ICR is the instantaneous point about which a joint segment rotates at any given moment, migrating during motion—for example, in the shoulder, the ICR shifts proximally (11-16 cm from the humeral head) during abduction, reflecting coupled glenohumeral and scapulothoracic translations. Screw theory models joint motion as a "twist" combining rotation about an axis with translation along the same axis (a screw displacement), providing a unified framework for analyzing helical paths in upper limb joints like the elbow, where flexion involves both pivoting and minor sliding. This theory underpins precise simulations of limb trajectories, emphasizing the upper limb's capacity for infinite end positions within its workspace.^[54]^[55]^[56]

Muscle actions and coordination

The upper limb's muscles generate forces through coordinated actions that enable precise movements, with prime movers providing the primary torque for specific joint actions. For instance, the biceps brachii serves as the prime mover for elbow flexion, exerting torque via its moment arm, which measures approximately 4-5 cm at 90° elbow flexion and varies with joint angle to optimize force production during tasks like lifting.^[57] This torque generation relies on the muscle's insertion on the radial tuberosity, allowing efficient force transmission across the elbow joint.^[58] Synergist muscles assist prime movers to refine actions and stabilize joints, while antagonists provide opposition to control deceleration and prevent unwanted motion. The supinator muscle acts as a synergist with the biceps brachii during rapid elbow flexion combined with forearm supination, enhancing overall torque efficiency in pronated starting positions.^[59] In contrast, the triceps brachii functions as the primary antagonist to the biceps, co-activating at levels up to 45% during preparatory phases of dynamic movements to maintain joint stability before and after peak flexion.^[60] Muscle force output in the upper limb follows the force-velocity relationship, described by Hill's hyperbolic equation, which quantifies how contractile force decreases with increasing shortening velocity:

F = F_{\max} \cdot \frac{V_{\max} - V}{k \cdot V + V_{\max}}

Here, F is the force, F_{\max} the maximum isometric force, V the velocity, V_{\max} the maximum unloaded velocity, and k a constant reflecting muscle properties. In reaching tasks, this relationship limits elbow flexor force during fast extensions, reducing torque by up to 50% at velocities near V_{\max}, thereby influencing reach speed and accuracy.^[61]^[62] Neural coordination patterns ensure smooth upper limb motion through mechanisms like reciprocal inhibition and co-activation. Reciprocal inhibition suppresses antagonist activity via spinal interneurons during agonist contraction, facilitating efficient elbow flexion by reducing triceps interference and promoting unidirectional torque.^[63] Co-activation, conversely, simultaneously recruits agonists and antagonists to enhance joint stiffness, as seen in shoulder stabilization during pointing, where it increases stability without sacrificing mobility.^[64] In load-bearing activities such as arm elevation, the deltoid and trapezius exhibit synergy to distribute forces across the shoulder girdle. The middle deltoid initiates glenohumeral abduction, while the upper trapezius upwardly rotates the scapula, together generating coordinated torque to elevate the arm against gravity, with peak co-activation around 60-90° to counter compressive loads up to 1.5 times body weight.^[65] This interplay prevents scapular winging and optimizes force transmission for sustained overhead tasks.

Development and Embryology

Embryonic origins

The upper limb develops from paired limb buds that emerge during the fourth week of embryonic gestation, arising from the lateral plate mesoderm and overlying ectoderm. These buds form through the proliferation of mesenchymal cells in the somatic layer of the mesoderm, initiated by signals from the body axis, including fibroblast growth factor 8 (FGF8) and retinoic acid. The limb buds are characterized by two critical signaling centers: the apical ectodermal ridge (AER), a thickened ectodermal structure at the distal tip that promotes outgrowth, and the zone of polarizing activity (ZPA), a mesenchymal region at the posterior margin that establishes asymmetry.^[66]^[67] Patterning along the three axes occurs concurrently with outgrowth. Proximal-distal patterning is regulated by fibroblast growth factor (FGF) signaling from the AER, which maintains the progress zone of undifferentiated mesenchyme, while Hox genes (such as HoxA and HoxD clusters) specify segment identity along this axis. Anteroposterior patterning is controlled by Sonic hedgehog (Shh) secreted from the ZPA, creating a gradient that determines digit identity and posterior structures. Dorsoventral axis formation involves Wnt signaling from the dorsal ectoderm, which promotes dorsal characteristics like extensor muscles, in opposition to ventral signals from engrailed-1 (En1) expressing cells.^[68]^[69] Skeletal elements arise through chondrogenesis, beginning around week 5, where mesenchymal cells condense into precartilaginous models under the influence of transforming growth factor-beta (TGF-β) and bone morphogenetic proteins (BMPs). These condensations form the humerus proximally, followed by the radius and ulna, and then the carpals, metacarpals, and phalanges distally. Ossification initiates in week 8 via endochondral mechanisms, with primary centers appearing in the diaphyses of long bones like the humerus and radius/ulna, while digits ossify later.^[70]^[71] Disruptions in these processes lead to congenital anomalies; for instance, early truncation or failure of the AER, often due to ischemia or teratogens, results in amelia, the complete absence of the upper limb. Similarly, ZPA defects involving reduced Shh signaling can cause polydactyly or syndactyly by altering anteroposterior patterning.^[72]^[73]

Postnatal changes

The postnatal development of the upper limb involves significant growth spurts during childhood and adolescence, characterized by the elongation of long bones through endochondral ossification at epiphyseal plates. These growth plates remain active until fusion occurs, marking skeletal maturity. For instance, the distal epiphysis of the humerus fuses around 12-17 years (earlier in females), while the proximal epiphysis unites between 14 and 21 years (later in males).^[14] In a radiographic study of young athletes, the distal epiphysis of the radius fused at a mean age of 16.85 years in males and 16.71 years in females, and the distal ulna at 16.83 years in males and 16.25 years in females.^[74] The clavicle, unique in its intramembranous ossification, completes its growth later, with the medial epiphysis fusing around 21-25 years.^[75] These fusion timelines vary slightly by sex and population, but generally, upper limb bones achieve full length by late adolescence, supporting increased load-bearing and mobility demands. Bone remodeling in the upper limb continues throughout life, adapting to mechanical stresses in accordance with Wolff's law, which posits that bone architecture and density adjust to the prevailing forces applied to it.^[76] In active individuals, repetitive loading from activities like throwing or weightlifting enhances cortical bone density in the humerus and radius, particularly on the dominant side, as seen in athletes where the playing arm exhibits up to 30-40% greater bone mineral density compared to the non-dominant arm.^[77] This adaptive response involves osteoblast and osteoclast activity balancing to thicken trabeculae along stress lines, preventing fractures under asymmetric loads typical of upper limb use. In sedentary lifestyles, however, reduced activity leads to decreased bone density, increasing porosity in the proximal humerus and distal forearm by up to 1-2% per decade after age 30. Muscles of the upper limb undergo hypertrophy in response to resistance exercise, increasing cross-sectional area through myofibrillar protein synthesis and satellite cell activation.^[78] This adaptation is evident in the deltoid and biceps brachii, where 8-12 weeks of progressive overload training can yield 10-20% gains in muscle volume, primarily via enlargement of type II fast-twitch fibers.^[79] Fiber type adaptations also occur, with endurance training shifting hybrid fibers toward type I slow-twitch profiles for improved fatigue resistance in forearm flexors, while high-intensity strength work promotes type II hypertrophy for power output in shoulder rotators.^[80] These changes enhance grip strength and reaching precision, but require consistent loading to maintain. Age-related degeneration profoundly affects upper limb function, beginning subtly in mid-adulthood and accelerating after age 60. Sarcopenia, the progressive loss of muscle mass and strength, reduces upper extremity lean mass by 25-45% from peak levels, with annual declines of 1-2% in hand and shoulder muscles, leading to diminished force generation.^[81] Osteoarthritis commonly develops in weight-bearing joints like the shoulder and elbow, eroding cartilage and causing subchondral bone remodeling that stiffens the glenohumeral joint by 20-30% in range of motion by age 70.^[82] Concurrently, reduced dexterity arises from slower nerve conduction and joint laxity, with fine motor tasks like pinching declining by 15-25% per decade, as grip strength correlates inversely with age (r = -0.45).^[83] These alterations collectively impair activities of daily living, such as buttoning or lifting. Sexual dimorphism in the upper limb emerges prominently during puberty, driven by hormonal influences on growth and muscle distribution. Males typically develop broader shoulders with a 10-15% larger glenoid fossa and deltoid mass, enhancing throwing velocity and upper body strength, which averages 40-50% greater than in females by adulthood.^[84] In contrast, females exhibit relatively longer forearms and finer hand control, with superior dexterity in precision tasks due to proportionally smaller but more coordinated intrinsic hand muscles, supporting activities like sewing or typing.^[85] These differences, while adaptive, also influence injury susceptibility, with males more prone to shoulder dislocations from expansive leverage.^[86]

Clinical Aspects

Common injuries and conditions

Upper extremity injuries and conditions are among the most frequent presentations in clinical settings, often resulting from trauma, overuse, or degenerative processes. In the United States, upper extremity injuries accounted for 28.8% of all emergency department visits between 2012 and 2021, with fractures being the leading cause of hospital admissions among these cases.^[87] Incidence rates are elevated in athletes due to repetitive stress and in the elderly owing to reduced bone density and balance issues.^[88] These pathologies commonly affect mobility and quality of life, with mechanisms involving falls, direct impacts, or chronic strain. Fractures represent a major category of upper limb trauma, particularly those of the distal radius, humeral shaft, and scaphoid bone. Colles' fracture, a distal radius fracture, typically occurs via a fall on an outstretched hand (FOOSH) mechanism, leading to dorsal displacement and angulation of the distal fragment. Symptoms include immediate wrist pain, swelling, bruising, and a characteristic "dinner fork" deformity, with tenderness over the distal radius. It is the most common forearm fracture, comprising up to 20% of all skeletal injuries and disproportionately affecting postmenopausal women due to osteoporosis.^[89]^[90] Humeral shaft fractures arise from high-energy direct blows, twisting forces, or low-energy falls, resulting in mid-arm pain, swelling, crepitus, and potential radial nerve palsy causing wrist drop. These fractures account for 1-5% of all fractures, with an annual incidence of 13-20 per 100,000, more frequent in young males from trauma and older adults from falls.^[91]^[92] Scaphoid fractures, the most prevalent carpal bone injury, stem from FOOSH with axial loading and hyperextension, presenting as snuffbox tenderness, wrist pain exacerbated by radial deviation, and swelling without obvious deformity. They constitute 2-7% of all fractures and 60-70% of carpal fractures, predominantly in young active males aged 20-30, with delayed union risk due to precarious blood supply.^[93]^[94] Soft tissue injuries encompass tendon and nerve pathologies from repetitive microtrauma or acute overload. Rotator cuff tears involve partial or complete detachment of the supraspinatus or other cuff tendons, often from degenerative attrition in older individuals or acute trauma in younger ones via forceful abduction. Symptoms feature shoulder pain, particularly at night or with overhead motion, weakness in arm elevation, and limited active range of motion. Prevalence reaches 20-30% in asymptomatic adults over 60, rising to 64% in symptomatic cases, with higher rates in overhead athletes.^[95]^[96] Lateral epicondylitis, known as tennis elbow, results from eccentric overload of the extensor carpi radialis brevis during repetitive wrist extension and grip, causing microtears at the lateral epicondyle. Key symptoms are aching pain over the lateral elbow, worsened by gripping or wrist extension, with possible radiation to the forearm. It affects 1-3% of the general population, peaking in ages 40-50, and up to 50% of recreational tennis players with frequent play.^[97]^[98] Carpal tunnel syndrome arises from median nerve compression within the carpal tunnel due to repetitive hand motions, inflammation, or anatomical narrowing, leading to nocturnal paresthesia in the thumb, index, and middle fingers, hand weakness, and thenar atrophy in advanced cases. It has an annual incidence of 1-2 per 1,000, higher in women and manual workers, comprising a significant portion of occupational upper limb disorders.^[99] Dislocations disrupt joint stability through traumatic forces, commonly affecting the shoulder and finger joints. Anterior shoulder dislocation, accounting for 95-97% of glenohumeral dislocations, occurs via a levering mechanism of abduction, extension, and external rotation, often in contact sports. It presents with severe shoulder pain, inability to adduct the arm, a squared-off shoulder appearance, and possible axillary nerve injury causing deltoid numbness. The incidence is approximately 0.2 per 1,000 person-years in the general population, with higher rates (up to 2.5 per 1,000) in young males under 25 and athletes.^[100]^[101] Finger joint dislocations, typically dorsal at the proximal interphalangeal (PIP) or metacarpophalangeal (MCP) joints, result from hyperextension or axial loading in falls or sports impacts. Symptoms include acute pain, swelling, visible deformity, and restricted motion, with potential ligament or tendon entrapment. These injuries represent about 9% of sports-related hand traumas, frequent in ball-handling athletes.^[102]^[103] Inflammatory conditions involve autoimmune or idiopathic processes leading to joint capsule and synovial changes. Rheumatoid arthritis profoundly impacts the hand through symmetric synovitis of metacarpophalangeal (MCP) and proximal interphalangeal (PIP) joints, driven by autoimmune-mediated cytokine release and pannus formation eroding cartilage and bone. Symptoms encompass morning stiffness lasting over 30 minutes, warmth, fusiform swelling of fingers, and progressive deformities like ulnar deviation and swan-necking, often with systemic fatigue. It affects 0.5-1% of the population, with hand involvement in 70-90% of cases, more common in women aged 30-50.^[104]^[105] Adhesive capsulitis, or frozen shoulder, features idiopathic synovial inflammation and capsular fibrosis, possibly linked to immobility or endocrine factors, progressing through freezing (pain-dominant), frozen (stiffness-dominant), and thawing phases. Primary symptoms are diffuse shoulder aching, night pain disrupting sleep, and global restriction of active and passive motion, with external rotation most limited. Prevalence is 2-5%, higher in women aged 40-60 and diabetics.^[106]^[107]

Diagnostic and therapeutic approaches

Diagnostic approaches for upper limb disorders typically begin with clinical evaluation, followed by imaging and specialized tests to assess bone, soft tissue, and nerve integrity. X-rays are the primary modality for detecting fractures and bony abnormalities in the upper limb, providing quick visualization of bone alignment and joint spaces.^[108] Magnetic resonance imaging (MRI) excels in evaluating soft tissue structures such as tendons, ligaments, and muscles, making it essential for diagnosing rotator cuff tears or labral injuries.^[108] Electromyography (EMG) is used to assess nerve function and detect abnormalities in muscle electrical activity, particularly for peripheral neuropathies or brachial plexus injuries.^[109] Arthroscopy serves as both a diagnostic and therapeutic tool, allowing direct visualization of intra-articular structures in joints like the shoulder and wrist to confirm pathologies such as cartilage damage or synovitis.^[109] Non-surgical therapies form the cornerstone of initial management for many upper limb conditions, aiming to reduce pain, inflammation, and promote healing without invasive procedures. Immobilization using casts, splints, or slings stabilizes fractures or injured joints, preventing further displacement while allowing soft tissue recovery; for instance, a coaptation splint supports humeral shaft fractures by accommodating swelling.^[110] Physical therapy protocols emphasize controlled exercises to restore function, including passive and active-assisted movements to regain joint mobility.^[111] Pharmacotherapy, such as non-steroidal anti-inflammatory drugs (NSAIDs) or intra-articular corticosteroids, alleviates pain and swelling in conditions like adhesive capsulitis or tendinopathies.^[107] Surgical interventions are indicated when conservative measures fail or for severe structural damage, focusing on restoring anatomy and function through precise techniques. Rotator cuff repair involves reattaching torn tendons to the humeral head using arthroscopic sutures or anchors, often improving shoulder stability and range of motion.^[112] Fracture fixation employs internal hardware like plates and screws to align and stabilize broken bones, such as in distal humerus or clavicle fractures, promoting union while minimizing displacement.^[113] Tendon transfers, such as latissimus dorsi to the rotator cuff, address irreparable tears by rerouting functional tendons to restore motion in chronic cases.^[114] Rehabilitation following diagnosis or surgery is critical for optimizing recovery and preventing complications, tailored to the specific injury. Range-of-motion exercises, starting with gentle passive stretches, gradually progress to active movements to restore joint flexibility and reduce stiffness.^[115] Strengthening protocols incorporate resistance training for muscles like the rotator cuff or forearm extensors, enhancing endurance and load-bearing capacity post-injury.^[115] As of 2025, advances in upper limb care include regenerative medicine and enhanced surgical precision. Platelet-rich plasma (PRP) injections promote tendon healing in conditions like lateral epicondylitis by delivering growth factors to stimulate tissue repair, showing improved pain relief and function in clinical studies.^[116] Robotic-assisted surgery, particularly in arthroscopy and microsurgery, offers superior precision for procedures like tendon transfers or flap reconstructions, reducing operative time and complications in upper extremity cases.^[117]

Comparative Anatomy

Variations in mammals

The upper limb in mammals exhibits remarkable structural diversity, all derived from a conserved pentadactyl (five-digit) blueprint that has been modified to suit varied locomotor and manipulative demands, such as running, climbing, swimming, or digging.^[118] These variations maintain homologous bones—like the humerus, radius, ulna, carpals, metacarpals, and phalanges—while altering their proportions, fusions, and articulations to optimize function.^[119] In quadrupedal mammals like dogs, the forelimb is adapted for weight-bearing and high-speed locomotion, featuring an elongated scapula that enhances stride length and shoulder mobility. The scapula is broad and massive to support the serratus anterior muscle, which anchors the limb to the axial skeleton, while the clavicle is often rudimentary or absent, allowing greater freedom of movement for galloping.^[120] These features distribute body weight across the forelimbs and facilitate rapid propulsion, with the humerus and forearm bones oriented more vertically for stability under load.^[121] Primates display upper limb modifications emphasizing manipulation and arboreal navigation, with apes possessing opposable thumbs formed by a rotatable first metacarpal that enables precise grasping of objects and branches.^[122] In gibbons, specialized for brachiation (suspensory swinging), the arms are disproportionately elongated relative to the legs, with flexible shoulder joints, elongated forearms, and hook-like hands featuring reduced thenar muscles for secure suspension from above.^[123] These adaptations prioritize reach and hook-grip strength over ground-based propulsion. Aquatic mammals such as whales have transformed their forelimbs into rigid flippers for hydrodynamic control, with carpals often fused into a single bony plate to stiffen the structure and prevent collapse under water pressure. Phalanges are reduced in distinct digit identity but elongated and numerous (hyperphalangy) within each of the five digits, encased in blubber for streamlined steering and stability during swimming.^[124] The humerus is shortened and paddle-like, with the radius and ulna tightly apposed to minimize flexibility.^[125] Burrowing species like moles exhibit robust forelimbs optimized for excavating soil, including strong, well-developed clavicles that articulate directly with the humerus to transmit powerful digging forces from the shoulders. The digits are short and spade-like, with enlarged claws on the third and fourth for scratching and displacing earth, while the humerus features massive deltopectoral crests for enhanced muscle leverage.^[126] Overall, the forelimb is compact and muscular, oriented laterally for perpendicular soil penetration.^[127] Bone homologues across mammals underscore the pentadactyl foundation, as seen in the horse where embryonic limbs initially form five digit condensations that fuse postnatally: digits I–II and IV–V merge into splint bones, leaving a single enlarged central digit (III) for weight support and speed. This monodactyl condition, with the hoof encasing the fused terminal phalanx, exemplifies extreme reduction while retaining traces of the ancestral pattern in vestigial metacarpals.^[128]

Evolutionary adaptations

The evolutionary history of the upper limb traces back to the Devonian period, when sarcopterygian fish fins began transitioning into tetrapod limbs around 385 to 360 million years ago, enabling the shift from aquatic to terrestrial locomotion.^[129] This transformation involved the development of a robust pectoral girdle, which decoupled from the skull and strengthened to support weight-bearing on land, with endochondral bones enlarging to form the primitive scapula.^[130]^[131] Fossils like those of Acanthostega illustrate early polydactylous limbs with fin-like features, marking the initial stages of this adaptation for weight support and rudimentary propulsion on substrates.^[129] In the synapsid lineage leading to mammals, the pectoral girdle underwent further modifications around 270 million years ago, evolving into a smaller, more flexible structure that facilitated sprawling to parasagittal postures suited for burrowing and scurrying behaviors in early therapsids.^[132]^[133] This increased shoulder mobility, evident in fossils like those of Dimetrodon and later cynodonts, allowed for greater range of motion and efficiency in terrestrial navigation, setting the stage for mammalian forelimb versatility.^[134] Primate evolution, beginning in the Eocene, emphasized arboreal adaptations, with forelimbs developing elongated phalanges and an opposable thumb for precise grasping of branches during locomotion in fine-branch environments.^[135]^[136] This prehensile configuration, seen in early primates like Adapis, enhanced stability and maneuverability in trees, diverging from the more generalized mammalian forelimb.^[137] By the Miocene, around 23 to 5 million years ago, the advent of bipedalism in early hominins freed the forelimbs from locomotor duties, allowing specialization for manipulation as evidenced in fossils of apes like Proconsul.^[138]^[139] In human evolution, the precision grip emerged around 2 million years ago in species like Homo erectus, enabling fine motor control for tool-making and use, as indicated by hand bone morphology supporting pad-to-pad opposition of thumb and fingers.^[140] This adaptation coincided with brain enlargement, where increased neocortical volume correlated with enhanced manual dexterity across primates, facilitating complex behaviors like crafting Acheulean tools.^[141] Fossil evidence from Australopithecus species, such as the scapulae of A. afarensis (e.g., from the "Lucy" skeleton), reveals shoulder blades with ape-like craniocaudal elongation but hints of human-like glenoid positioning, suggesting a transitional role in climbing and emerging prehensility around 3.9 to 2.9 million years ago.^[142] Similarly, Neanderthal hand bones from sites like El Sidrón display robust phalanges and carpals adapted for powerful grips, underscoring convergent evolution in dexterity for tool manipulation despite broader upper limb robusticity.^[143]^[144]