Humeroradial joint
The humeroradial joint, also referred to as the radiohumeral joint, is a synovial articulation within the elbow joint complex, formed by the capitulum of the distal humerus and the fovea of the proximal radial head.[1] This joint contributes to the overall stability and mobility of the elbow, enabling essential upper limb movements while integrating with the adjacent humeroulnar and proximal radioulnar joints.[2] Anatomically, the humeroradial joint is classified as an atypical biaxial ball-and-socket synovial joint, characterized by the rounded capitulum of the humerus articulating with the concave fovea of the radial head.[3] It is enclosed within a common fibrous capsule shared with the rest of the elbow joint, lined by synovium that produces lubricating fluid to reduce friction during motion.[1] The joint's blood supply derives from periarticular anastomoses involving branches of the brachial artery, such as the radial collateral and recurrent radial arteries, ensuring adequate nourishment to the surrounding structures.[4] Innervation is primarily provided by branches of the radial nerve, which supplies sensory fibers to the joint capsule and motor innervation to nearby muscles like the brachioradialis and supinator.[1] Functionally, the humeroradial joint plays a key role in elbow flexion and extension, with its convex-concave geometry allowing smooth gliding motions that complement the hinge-like action of the humeroulnar joint.[2] It also facilitates forearm supination and pronation by permitting rotation of the radial head against the capitulum, essential for activities like turning a doorknob or using tools.[3] The joint's close-packed position occurs at 90 degrees of flexion with slight supination, maximizing stability, while its open-packed position is full extension with supination, allowing greater freedom of movement.[3] Stability of the humeroradial joint is maintained by the lateral collateral ligament complex, including the radial collateral ligament, which originates from the lateral epicondyle of the humerus and inserts into the annular ligament and proximal ulna to resist varus stresses.[3] The annular ligament, a strong fibro-osseous band, encircles the radial head and attaches to the radial notch of the ulna, forming about four-fifths of a ring that prevents radial displacement while permitting rotation.[4] Clinically, injuries to this joint, such as radial head subluxation (nursemaid's elbow) in young children or fractures associated with Monteggia dislocations, can impair forearm rotation and require prompt reduction or surgical intervention to restore function.[4]Anatomy
Bony Articulations
The humeroradial joint forms through the articulation between the capitulum of the distal humerus and the fovea of the proximal radius. The capitulum is a smooth, rounded eminence projecting laterally from the trochlea of the humerus, while the fovea constitutes the shallow, concave superior surface of the radial head, enabling a close congruency that supports load transmission during forearm movements.[1][5] This joint is classified as an atypical biaxial ball-and-socket synovial joint, contributing to the compound elbow joint complex that encompasses the humeroulnar and proximal radioulnar articulations within a shared articular capsule. It facilitates flexion and extension alongside rotational movements of the radius relative to the humerus and ulna.[1][6] The superior aspect of the radial head is covered by hyaline articular cartilage over approximately 240 degrees of its circumference, with the remaining anterolateral 120 degrees lacking cartilage to allow unimpeded passage of soft tissues during forearm pronation and supination. This partial cartilaginous coverage ensures smooth gliding against the capitulum while preventing compression of adjacent structures. Osseous stability arises from the intimate, close-packed fit between the convex capitulum and concave fovea, which inherently limits anteroposterior and mediolateral translation of the radial head.[6][5][7]Ligaments and Capsule
The humeroradial joint is reinforced by several key ligaments that form part of the lateral collateral ligament (LCL) complex, providing essential stability against varus forces and rotational stresses. The radial collateral ligament (RCL), a fan-shaped structure, originates from the inferior aspect of the lateral epicondyle of the humerus and extends distally to blend with the annular ligament and the extensor carpi radialis brevis tendon, thereby anchoring the lateral aspect of the radial head.[1][8] This ligament serves as a primary static stabilizer for the humeroradial articulation, resisting varus deviation and contributing to overall lateral elbow integrity.[9] The annular ligament is a critical component encircling the head and neck of the radius, attaching proximally and distally to the anterior and posterior margins of the radial notch on the ulna.[4] It forms a fibro-osseous ring that maintains the radial head in position relative to the capitulum of the humerus and the ulna, preventing superior displacement during forearm pronation and supination while allowing smooth pivot motion.[4] As part of the LCL complex, the annular ligament integrates with the RCL and lateral ulnar collateral ligament (LUCL) to enhance posterolateral rotatory stability, with the LUCL extending from the lateral epicondyle to the supinator crest of the ulna.[1][6] The LCL complex collectively acts as the main restraint against varus stress at the elbow, particularly in extension where osseous contacts provide additional support.[10] The joint capsule surrounding the humeroradial joint consists of thin anterior and posterior extensions that are continuous with the overall elbow joint capsule, forming a loose fibrous envelope that permits flexion-extension and radioulnar rotation.[1] Lined by a synovial membrane, the capsule produces synovial fluid that lubricates the articular surfaces, reducing friction between the capitulum and radial head during movement.[8] These soft tissue structures, including the ligaments and capsule, collectively ensure joint integrity by distributing loads and maintaining alignment, with the LCL complex providing secondary varus stability in flexed positions where bony articulations are primary.[10]Vascular and Neural Supply
The arterial supply to the humeroradial joint is derived from an extensive anastomotic network surrounding the elbow, ensuring robust nourishment to the joint structures. Key contributors include the radial recurrent artery (a branch of the radial artery), the middle collateral artery and radial collateral artery (branches of the deep brachial artery from the brachial artery), and the anterior and posterior ulnar recurrent arteries (from the ulnar artery), which interconnect to form the periarticular arterial anastomosis.[11][12][13] This network provides blood flow to the capitulum of the humerus and the radial head, with the radial recurrent artery particularly supplying the brachialis muscle and elbow joint capsule.[13] Venous drainage of the humeroradial joint follows the arterial pathways through accompanying venae comitantes, which converge into the deep veins of the forearm and ultimately drain into the brachial vein and then the axillary vein.[14] Superficial veins, such as the cephalic vein on the lateral aspect, contribute to overall drainage from the elbow region.[15] Lymphatic drainage from the humeroradial joint proceeds via superficial and deep lymphatic vessels, primarily directing to the supratrochlear (epitrochlear) nodes located superior to the medial epicondyle and lateral supracondylar nodes, before ascending to the axillary lymph nodes.[1] This pathway facilitates clearance of interstitial fluid from the lateral elbow structures.[16] Innervation of the humeroradial joint arises from articular branches of multiple nerves, providing sensory and proprioceptive feedback. The primary supply is from the radial nerve, particularly its deep branch (posterior interosseous nerve), which delivers sensory innervation to the joint capsule and radiocapitellar articulation after emerging at the radiohumeral joint line.[17][18] Additional contributions come from the musculocutaneous nerve (anterior capsule), ulnar nerve (medial aspects), and median nerve, adhering to Hilton's law of joint innervation by surrounding muscles.[19][1] The radial nerve's superficial course over the radiocapitellar (humeroradial) joint renders it vulnerable to injury during surgical procedures, such as radial head fixation or excision, potentially leading to posterior interosseous nerve palsy if not carefully protected at the arcade of Frohse.[20][21]Function
Movements
The humeroradial joint primarily facilitates flexion and extension of the forearm relative to the arm, functioning as a hinge joint between the capitulum of the humerus and the fovea of the radial head. Flexion involves bending the forearm toward the humerus, achieving a typical range of motion from 0° (full extension) to approximately 145–150° of flexion, which enables essential activities such as bringing the hand to the mouth or lifting objects. Extension returns the forearm to the straight position, completing the hinge-like motion that is crucial for reaching and pushing movements. This uniaxial hinge mechanism allows for smooth gliding of the radial head against the capitulum during these actions, contributing to the overall elbow complex's stability and efficiency.[1][22][23] In addition to its primary role, the humeroradial joint secondarily supports pronation and supination of the forearm through a pivot action at the capitulum, where the rounded radial head rotates within the joint space. Pronation turns the palm downward, with a normal range up to 80°, while supination turns the palm upward, also reaching up to 80°, allowing for tasks like turning a doorknob or screwing in a lightbulb. These rotational movements occur most effectively when the elbow is in semiflexion, as the articular surfaces maintain close contact to guide the radius's circular motion without significant translation. The joint's contribution to these motions integrates with the proximal radioulnar joint to enable compound forearm positioning.[23][8][24] Key muscles drive these movements at the humeroradial joint, with the biceps brachii acting as a primary flexor and supinator, originating from the scapula and inserting on the radial tuberosity to flex the elbow while rotating the forearm supinated. The brachioradialis, a flexor originating from the lateral supracondylar ridge of the humerus and inserting on the distal radius, assists in flexion particularly when the forearm is in mid-pronation or supination, providing stability during dynamic activities. The supinator muscle, arising from the lateral epicondyle and inserting on the proximal radius, primarily facilitates supination by winding the radius around the ulna, enhancing the joint's pivot function in compound elbow motions. The pronator teres (innervated by the median nerve) and pronator quadratus (innervated by the anterior interosseous nerve) facilitate pronation by rotating the radius medially around the ulna. These muscles work synergistically to produce the joint's actions, with innervation primarily from the musculocutaneous, radial, and median nerves.[1][25][26][27] The range of motion at the humeroradial joint is constrained by bony contact between the capitulum and radial head, which prevents hyperextension beyond 0°, and by tension in surrounding soft tissues that limit excessive flexion or rotation. Full extension aligns the arm and forearm in a straight line, serving as the neutral position for the joint's hinge and pivot functions. These anatomical limits ensure controlled movement while protecting the joint from overload during everyday and athletic activities.[6][8]Biomechanics
The humeroradial joint, formed by the articulation between the capitulum of the humerus and the fovea of the radial head, exhibits kinematics characterized by a primary axis of rotation passing through the center of the capitulum and the radial head. This configuration enables uniaxial hinge-like flexion and extension, complemented by a pivot mechanism that facilitates forearm rotation during pronation and supination. The joint's concave-convex geometry ensures congruent contact throughout the range of motion, with the radial head translating minimally (1-2 mm proximally during pronation) to maintain stability.[10][5] In terms of kinetics, the humeroradial joint bears approximately 60% of axial compressive loads transmitted across the elbow in full extension, with the remaining load distributed to the ulnohumeral articulation. This load-sharing role is most pronounced at 0°-30° of flexion, where forces peak, particularly in pronation, due to the joint's orientation and contact area. Additionally, the radial head contributes about 30% to overall valgus stability, serving as a critical secondary restraint, especially in low flexion angles (0°-30°) and pronated forearm positions.[6][28][6] Stability of the humeroradial joint relies on osseoligamentous constraints, including the lateral collateral ligament (LCL) complex, which primarily resists varus and valgus stresses by tensioning across the radial head and capitulum. The LCL, particularly its lateral ulnar band, prevents posterolateral rotatory subluxation and maintains joint centering under lateral forces. Dynamic stabilization is provided by muscles such as the anconeus and the common extensor origin group (e.g., extensor carpi radialis brevis and extensor digitorum), which generate compressive forces and enhance varus resistance through co-contraction during activity.[9][29] Load distribution through the humeroradial joint is vital for elbow resilience, as the radial head acts as a primary absorber of axial and valgus forces during dynamic impacts, such as falls onto an outstretched hand. This mechanism dissipates energy and prevents excessive stress on the ulnohumeral joint, with the fovea's broad articular surface distributing up to 60% of impact loads to mitigate overall joint overload. Preservation of this function underscores the joint's role in maintaining elbow integrity under high-stress conditions.[30][31]Clinical Significance
Subluxation
Humeroradial subluxation, commonly known as nursemaid's elbow or pulled elbow, refers to the partial displacement of the radial head from the capitulum of the humerus, typically resulting from the annular ligament slipping over the radial head.[32] This injury occurs when axial traction is applied to the extended and pronated forearm, causing the ligament to interpose between the radial head and capitellum, thereby disrupting normal joint stability.[33] In children, this mechanism often arises from a sudden pull on the arm, such as lifting a toddler by the hand or wrist.[34] Epidemiologically, humeroradial subluxation is the most common upper extremity injury in young children, accounting for more than 20% of such cases in pediatric emergency departments, with a peak incidence between 1 and 4 years of age (mean around 28 months).[32] It predominantly affects toddlers through traction injuries like pulling the arm during play or falls, showing a slight female predominance (about 60%) and a preference for the left arm (around 60% of cases); the condition is rare in adults and uncommon after age 5 as the annular ligament strengthens.[33][34] Clinically, patients present with sudden onset of pain following the injury, leading to refusal to use the affected arm, which is typically held in extension and pronation to minimize discomfort.[32] There is usually no visible swelling, ecchymosis, or deformity, though tenderness may be elicited at the radial head with attempted supination.[33] Diagnosis is primarily clinical, relying on a characteristic history of traction injury and physical examination findings, without the need for routine radiographs unless the presentation is atypical or recurrent to rule out fractures.[32] Confirmation often involves reproducing symptoms during exam maneuvers, such as gentle supination.[33] Treatment consists of closed reduction using either the supination-flexion maneuver—where the elbow is flexed to 90 degrees, the forearm supinated, and upward pressure applied to the radial head—or hyperpronation of the forearm, both of which reposition the annular ligament with a first-attempt success rate of approximately 90%.[32] Post-reduction, pain typically resolves within 30 minutes, allowing immediate arm use without immobilization, though recurrence occurs in up to 20-30% of cases, particularly in children under 3 years, necessitating parental education on avoiding traction forces.[33]Dislocation
The humeroradial joint, also known as the radiocapitellar articulation, rarely dislocates in isolation due to its inherent stability provided by surrounding ligaments and the annular ligament; dislocations typically occur as part of a complex elbow dislocation, with posterolateral displacement of the radial head posterior to the capitulum being the most common type, accounting for approximately 80% of elbow dislocations.[35] These dislocations often involve concurrent ulnohumeral disruption, forming a combined injury pattern.[36] The primary mechanism of humeroradial dislocation is high-energy trauma, such as a fall on an outstretched hand with axial loading, supination, and valgus stress, leading to sequential rupture of the lateral collateral ligament (LCL) complex, starting from the lateral ulnar collateral ligament and progressing to the annular ligament.[35] In children, low-energy mechanisms like minor falls or pulling on the arm can cause similar disruptions due to the relative weakness of the annular ligament compared to the bone.[37] This injury disrupts the normal hinge stability of the elbow, as detailed in biomechanical studies of joint loading.[6] Clinically, patients present with severe pain, significant swelling, and visible deformity, often with the elbow held in 45 degrees of flexion to minimize discomfort; neurovascular compromise is a critical concern, with risks to the radial nerve from stretching or the brachial artery from kinking.[36] Diagnosis relies on anteroposterior (AP) and lateral radiographs to confirm radial head displacement and assess joint congruency, with computed tomography (CT) or magnetic resonance imaging (MRI) recommended for evaluating associated soft tissue injuries or subtle fractures.[35] Treatment begins with closed reduction under sedation or anesthesia, aiming to restore radiocapitellar alignment through longitudinal traction and direct pressure on the radial head, followed by immobilization in a posterior splint at 90 degrees of flexion for 1-3 weeks to allow ligament healing.[36] Surgical intervention is indicated for unstable reductions, vascular injuries requiring exploration, or complex cases with incarceration, involving open reduction, ligament repair, or fixation of associated ulnar fractures.[35] Complications include post-traumatic stiffness from capsular contracture, recurrent instability due to incomplete LCL healing, and potential neurovascular deficits if not promptly addressed.[36]Fractures and Other Disorders
Radial head fractures represent a primary bony pathology affecting the humeroradial joint, often resulting from indirect trauma that disrupts the articular surface between the radial head and capitellum. These fractures account for approximately 20% to 33% of all elbow fractures and 1% to 5% of fractures in adults, with a higher incidence in women aged 30 to 40 years. The typical mechanism involves an axial load transmitted through the forearm during a fall on an outstretched hand (FOOSH injury), or valgus stress that compresses the radial head against the capitellum. In up to 75% of displaced cases, these fractures are associated with lateral collateral ligament (LCL) injuries or elbow dislocations, which can exacerbate joint instability.[38][39][40] The Mason classification, modified by Hotchkiss and Broberg-Morrey, categorizes radial head fractures into three types based on displacement and fragmentation:| Type | Description | Key Features |
|---|---|---|
| I | Nondisplaced or minimally displaced (<2 mm) | No mechanical block to motion; marginal or small avulsion fractures.[30][41] |
| II | Displaced (>2 mm) or angulated partial articular | Angulation >30° or depression >2 mm; may cause mechanical block.[38][30] |
| III | Comminuted and displaced | Multiple fragments involving the entire articular surface; often unstable.[38][30] |