Biceps brachii muscle

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For other uses, see biceps.
Biceps brachii
Latin musculus biceps brachii
Gray's subject #124 443
Origin: short head: coracoid process of the scapula. long head: supraglenoid tubercle
Insertion: radial tuberosity
Artery: brachial artery
Nerve: Musculocutaneous nerve (C5–C7)
Action: flexes elbow and supinates forearm
Antagonist: Triceps brachii muscle
Dorlands/Elsevier m_22/12548475

In human anatomy, the biceps brachii is a muscle located on the upper arm. The biceps has several functions, the most important simply being to flex the elbow and to rotate the forearm.

The biceps brachii is arguably the best known muscle, as it lies fairly superficially, and is often well-defined even in non-athletes. The muscle is popular amongst bodybuilders, and can grow quite large through weight training.

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[edit] Terminology

The term biceps brachii is a Latin phrase meaning "two heads of the arm", in reference to the fact that the muscle consists of two bundles each with its own origin but with a common insertion point near the elbow.

Note that the word biceps is both singular and plural: the form bicep, although common, is incorrect. (The Latin plural bicipites is considered pedantic and rarely used.)

[edit] Anatomy

Proximally, the short head of the biceps attaches to the coracoid process of the scapula. The tendon of the long head passes into the joint capsule at the head of the humerus, and attaches on the scapula at the supraglenoid tubercle.

Distally, biceps attaches to the radial tuberosity, and because this bone can rotate, the biceps also supinates the forearm. The biceps also connects with the fascia of the medial side of the arm, at the bicipital aponeurosis.

Two additional muscles lie underneath the biceps brachii. These are the coracobrachialis muscle, which like the biceps attaches to the coracoid process of the scapula, and the brachialis muscle which connects to the ulna and the humerus.

[edit] Functions

The biceps is tri-articulate, meaning that it works across three joints. The most important of these functions are to flex the elbow and to supinate the forearm.

These joints and the associated actions are as follows:

  • Shoulder joint (glenohumeral joint) - flexion (bringing arm upward by a forward motion)
  • Proximal radioulnar joint - supination of the forearm. One of the main functions of the biceps is to, along with the supinator muscle, aid in supination of the forearm, which refers to the allowing the forearm, and subsequently, the palm, to be rotated or moved toward the anatomical position, the resulting hand position not dissimilar to that of the biceps curl. This has also been achieved through the use of functional electrical stimulation as a means of emulating electrical impulses used within the synapses, and allow slight movement within those with paralysis. [1] It has also been proven through several tests into muscle group stimulation, that a supinated grip allows for close and normal-grip bench press exercises to have a much more profound effect on the biceps brachii and the clavicular portion of the pectoralis major.[citation needed]

[edit] Training

There are many forms of resisted elbow flexion, better known as a curling motion, which exercise the biceps.

Some common iterations include:

Working out the upper back muscles through rowing and pulling motions will also incorporate some Biceps Brachii due to great amounts of necessary elbow flexion. However, simultaneous extension of the glenohumeral joint will result in some lengthening of the biceps, thus weakening the biceps' contraction and deferring a great deal of the elbow flexion work to the brachialis and brachioradialis. The role of the biceps during such motions is what is known as a dynamic stabilizer.

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[edit] References

  1. ^ Naito A, Yajima M, Fukamachi H, Ushikoshi K, Handa Y, Hoshimiya N, Shimizu Y. (1994) Functional electrical stimulation (FES) to the biceps brachii for controlling forearm supination in the paralyzed upper extremity. Tohoku journal of experimental medicine

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