Back To Search Results

Anatomy, Shoulder and Upper Limb, Hand Palmar Interosseous Muscle

Editor: Bruno Bordoni Updated: 7/24/2023 4:12:39 PM

Introduction

The palmar interossei are a group of paired intrinsic muscles of the hand located between the metacarpals. They consist of four, and sometimes three, palmar muscles that, adduct fingers. The palmar interossei also assist in flexion of the metacarpophalangeal joints and extension of the interphalangeal joints. All interossei muscles receive their innervation by the deep ulnar branch of the ulnar nerve. As such, any injury to the ulnar nerve may have debilitating implications on specific intrinsic hand muscle functions, including finger adduction, which is primarily controlled by the palmar interosseous muscles.  

Structure and Function

Register For Free And Read The Full Article
Get the answers you need instantly with the StatPearls Clinical Decision Support tool. StatPearls spent the last decade developing the largest and most updated Point-of Care resource ever developed. Earn CME/CE by searching and reading articles.
  • Dropdown arrow Search engine and full access to all medical articles
  • Dropdown arrow 10 free questions in your specialty
  • Dropdown arrow Free CME/CE Activities
  • Dropdown arrow Free daily question in your email
  • Dropdown arrow Save favorite articles to your dashboard
  • Dropdown arrow Emails offering discounts

Learn more about a Subscription to StatPearls Point-of-Care

Structure and Function

The palmar interossei are unipennate muscles that originate from the metacarpals of the respective digit to which they are associated. These muscles adduct the first, second, fourth, and fifth digits about a long axis through the third digit. The adduction occurs at the metacarpophalangeal joints. Additionally, the palmar interossei contribute to flexion at the metacarpophalangeal joints and extension at the proximal interphalangeal (PIP) and distal interphalangeal (DIP) joints of their respective digits.

When present as an individual entity, the first palmar interossei originates at the medial, palmar surface of the first metacarpal and inserts into the base of the proximal first phalanx as well as into the extensor hood or the first phalanx. The first palmar interosseus is often considered rudimentary, with most anatomy texts deeming it to be often a component of either the adductor pollicis or the flexor pollicis brevis. Recent studies, however, dispute this notion and found that the first palmar interossei, termed the “pollical palmar interosseous,” is present in over 85% of specimens.[1][2][3] This muscle is thought to be derived from the oblique head of the adductor pollicis, with these studies suggesting that it played a role in human evolution.[1]

The second palmar interosseous originates at the medial surface of the base of the second metacarpal and inserts onto the medial portion of the extensor hood of the first digit as well as the base of the first phalanx.

The third and fourth palmar interossei originate at the lateral aspect of the fourth and fifth metacarpals and insert into the lateral aspect of their respective extensor hood. They additionally insert into the base of their respective proximal phalanx.

Embryology

At the end of the fourth week of embryonic development, four limb buds arise from somites and mesenchyme of the lateral plate mesoderm that is covered by a layer of ectoderm. Development of the upper extremities is propagated by a plethora of protein factors, with fibroblast growth factors (FGF) and sonic hedgehog (Shh) playing vital roles. The gene expression and subsequent interactions of these various proteins contribute to the development of three spatial limb axes: proximo-distal, anteroposterior, and dorsoventral.[4][5]

Development of the hand begins with flattening of the distal upper extremity buds around days 34-38 of embryonic development. Somites form the limb musculature while mesenchyme of the lateral plate mesoderm forms bone and cartilage. Somitic mesoderm of the hand divides into superficial and deep layers. Both palmar and dorsal interossei muscles develop from the deep layer of this mesoderm. By the twelfth week of development, tendons are fully developed and functional.[5]

Blood Supply and Lymphatics

Blood supply to the palmar interossei comes from the palmar metacarpal arteries and drains into the palmar metacarpal veins. The palmar metacarpal arteries derive from the deep palmar arch, which is comprised of the terminal portion of the radial artery and the deep branch of the ulnar artery. Furthermore, an anastomosis is present between the palmar metacarpal arteries and the common palmar digital arteries that stem from the superficial palmar arch.

Lymphatic drainage of the upper limbs divides into superficial and deep lymphatic drainage. Lymphatic plexuses of the skin of the palm and dorsum of the hand ascend with the cephalic and basilic veins towards the axillary and cubital lymph nodes, respectively. Deep lymphatic vessels follow the primary deep veins and eventually terminate in the humeral lymph nodes.

Nerves

The palmar interossei receive nerve supply from the deep branch of the ulnar nerve. The deep branch of the ulnar nerve arises from nerve roots of C8 and T1 with T1 being the primary innervating segment.

Physiologic Variants

Most students are taught in standard anatomy courses that all palmar interossei possess one head, termed a unipennate head. One retrospective study found that approximately only 62 percent of palmar interossei were unipennate.[6] This study also concludes that textbooks have oversimplified the attachment sites of both palmar and dorsal interossei, which possess a high degree of variability. This variability includes distal insertions into any component of the extensor hood, volar plate, bony attachment, or a combination of these sites.[6]

As previously mentioned, most contemporary anatomy texts teach that the first palmar interosseous muscle is commonly a component of either the adductor pollicis or the flexor pollicis brevis and rarely functional on its own. The notion that the first palmar interosseous muscle is an independent and function intrinsic hand muscle was first suggested by Henle (1858), with several recent studies supporting this claim.[1][2][3]  One study dissected 72 hands and found that the first palmar interosseous, referred to as the “pollical palmar interosseous” (PPI) muscle of Henle, was present in 67 hands (93%).[1] The authors also analyzed six other, similar studies and found that the PPI was present in over 80 percent of cadaveric hands.[1] The presence of the PPI in humans, researchers believes, had great implications on the development of the human species from non-humanoid primates, due to its significant contribution to dexterous movements of the thumb.[1][2][3]

Surgical Considerations

Conventional treatment of metacarpal fractures is with hand surgery, with metacarpal shortening ranging from 2mm to 10mm. Researchers have found that with metacarpal shortening of 2 mm, there is an approximate 8 percent in strength reduction of the respective interossei. Moreover, a 10mm shortening can reduce the respective interossei strength of roughly 55 percent.[7]

Compartment syndromes of the interossei are relatively rare and are typically associated with severe ischemia, crush injuries, or burns.[8] One case report described two children who experienced suction injuries when they had their hands their hands get caught in a swimming-pool intake pipe filtration system. This system caused acute interossei compartment syndrome requiring emergent surgical decompression. As noted in other studies describing the procedure, the authors made two incisions, one between the index and the middle fingers and the other between the middle and ring fingers.[8][9] Dissection along the sides of the metacarpals released the dorsal interossei, with further dissection along the index metacarpal releasing the first palmar interossei and the adductor compartment. Subsequent deep dissection along the radial and ulnar aspects of the ring metacarpal released the remaining palmar interossei.[8][9]

Clinical Significance

The palmar interossei receive innervation from the deep palmar branch of the ulnar nerve. As such, injury to the ulnar nerve can manifest as weakness or even atrophy of the interossei muscles and is typically caused by nerve root impingement, brachial plexus compression, or nerve entrapment at the elbow, forearm, or wrist. Ulnar nerve entrapment is the second most prevalent compression neuropathy with which patients present.[10] Depending on which nerve fibers are compromised, patients may have weakness in adduction of the fingers. The lumbricals are the major contributors to flexion at the metacarpophalangeal joints as well as extension at the DIP and PIP joints; however, the interossei also play a minor role in these movements. A late manifestation of ulnar nerve injury, the ulnar claw hand deformity is caused by weakness of the third and fourth lumbricals, in addition to the interossei, which manifests as an extension of the fourth and fifth metacarpophalangeal joints and flexion of the fourth and fifth PIP and DIP joints.[10]

Several clinical examinations are used to assess the integrity of ulnar nerve function. In a positive Wartenberg’s sign, patients are instructed to adduct all fingers. A positive test will produce abduction of the fifth finger relative to all other digits, implying weakness of the third palmar interosseous muscle and fourth lumbrical.[10] A patient can be instructed to hold a sheet of paper between any of the second through fifth digits to examine the palmar interossei, with dropping of the piece of paper indicative palmar interossei weakness.[10]

Media


(Click Image to Enlarge)
The image shows the intrinsic muscles of the hand, in the dorsal and palmar portion.
The image shows the intrinsic muscles of the hand, in the dorsal and palmar portion. Contributed by Bordoni Bruno, PhD.

References


[1]

Bello-Hellegouarch G, Aziz MA, Ferrero EM, Kern M, Francis N, Diogo R. "Pollical palmar interosseous muscle" (musculus adductor pollicis accessorius): attachments, innervation, variations, phylogeny, and implications for human evolution and medicine. Journal of morphology. 2013 Mar:274(3):275-93. doi: 10.1002/jmor.20090. Epub 2012 Oct 29     [PubMed PMID: 23109102]

Level 3 (low-level) evidence

[2]

Susman RS,Nyati L,Jassal MS, Observations on the pollical palmar interosseous muscle (of Henle). The Anatomical record. 1999 Feb 1;     [PubMed PMID: 9972800]

Level 3 (low-level) evidence

[3]

Morrison PE, Hill RV. And then there were four: Anatomical observations on the pollical palmar interosseous muscle in humans. Clinical anatomy (New York, N.Y.). 2011 Nov:24(8):978-83. doi: 10.1002/ca.21253. Epub 2011 Aug 25     [PubMed PMID: 22009503]


[4]

Tickle C. How the embryo makes a limb: determination, polarity and identity. Journal of anatomy. 2015 Oct:227(4):418-30. doi: 10.1111/joa.12361. Epub 2015 Aug 7     [PubMed PMID: 26249743]


[5]

Cole P, Kaufman Y, Hatef DA, Hollier LH Jr. Embryology of the hand and upper extremity. The Journal of craniofacial surgery. 2009 Jul:20(4):992-5. doi: 10.1097/SCS.0b013e3181abb18e. Epub     [PubMed PMID: 19553860]


[6]

Eladoumikdachi F, Valkov PL, Thomas J, Netscher DT. Anatomy of the intrinsic hand muscles revisited: part I. Interossei. Plastic and reconstructive surgery. 2002 Oct:110(5):1211-24     [PubMed PMID: 12360058]


[7]

Meunier MJ, Hentzen E, Ryan M, Shin AY, Lieber RL. Predicted effects of metacarpal shortening on interosseous muscle function. The Journal of hand surgery. 2004 Jul:29(4):689-93     [PubMed PMID: 15249095]


[8]

Shin AY, Chambers H, Wilkins KE, Bucknell A. Suction injuries in children leading to acute compartment syndrome of the interosseous muscles of the hand: case reports. The Journal of hand surgery. 1996 Jul:21(4):675-8     [PubMed PMID: 8842965]

Level 3 (low-level) evidence

[9]

Leversedge FJ,Moore TJ,Peterson BC,Seiler JG 3rd, Compartment syndrome of the upper extremity. The Journal of hand surgery. 2011 Mar;     [PubMed PMID: 21371631]


[10]

Andrews K, Rowland A, Pranjal A, Ebraheim N. Cubital tunnel syndrome: Anatomy, clinical presentation, and management. Journal of orthopaedics. 2018 Sep:15(3):832-836. doi: 10.1016/j.jor.2018.08.010. Epub 2018 Aug 16     [PubMed PMID: 30140129]