Fascia

A fascia (/ˈfæʃ(i)ə/; pl.: fasciae /ˈfæʃii/ or fascias; adjective fascial; from Latin fascia 'band') is a generic term for macroscopic membranous bodily structures. Fasciae are classified as superficial, visceral or deep, and further designated according to their anatomical location.

The knowledge of fascial structures is essential in surgery, as they create borders for infectious processes (for example Psoas abscess) and haematoma. An increase in pressure may result in a compartment syndrome, where a prompt fasciotomy may be necessary. For this reason, profound descriptions of fascial structures are available in anatomical literature from the 19th century.

Fasciae were traditionally thought of as passive structures that transmit mechanical tension generated by muscular activities or external forces throughout the body. An important function of muscle fasciae is to reduce friction of muscular force. In doing so, fasciae provide a supportive and movable wrapping for nerves and blood vessels as they pass through and between muscles.

In the tradition of medical dissections it has been common practice to carefully clean muscles and other organs from their surrounding fasciae in order to study their detailed topography and function. However, this practice tends to ignore that many muscle fibers insert into their fascial envelopes and that the function of many organs is significantly altered when their related fasciae are removed. This insight contributed to several modern biomechanical concepts of the human body, in which fascial tissues take over important stabilizing and connecting functions, by distributing tensional forces across several joints in a network-like manner similar to the architectural concept of tensegrity. Starting in 2018 this concept of the fascial tissue serving as a body-wide tensional support system has been successfully expressed as an educational model with the Fascial Net Plastination Project.

Fascial tissues – particularly those with tendinous or aponeurotic properties – are also able to store and release elastic potential energy.

Beyond storing and releasing elastic energy, fascial tissues contribute to proprioception and motor control through dense innervation with mechanoreceptors and nociceptors. Recent biomechanical studies also emphasize the role of fascial networks in distributing strain across multiple joints. This is an idea often framed as a body-wide tensegrity system, so that fascia participates dynamically in coordinated movement and postural stability.

A fascial compartment is a section within the body that contains muscles and nerves and is surrounded by fascia. In the human body, the limbs can each be divided into two segments. The upper limb can be divided into the arm and the forearm; their sectional compartments are the fascial compartments of the arm and the fascial compartments of the forearm, which both contain an anterior and a posterior compartment. The lower limbs can also be divided into two segments: the leg and the thigh; those contain the fascial compartments of the leg and the fascial compartments of the thigh respectively.

Fascia itself becomes clinically important when it loses stiffness, becomes too stiff, or has decreased shearing ability. Fascial dysfunction has been implicated in a range of musculoskeletal pain syndromes, including myofascial pain and some cases of chronic low back pain, where altered fascial gliding or adhesions may contribute to symptoms. Surgical disruption of fascial planes can produce postoperative adhesions and functional limitations. Rehabilitation approaches such as targeted physical therapy and myofascial release aim to restore fascial mobility and reduce pain, though high-quality randomized trials assessing long-term efficacy are limited.When inflammatory fasciitis or trauma causes fibrosis and adhesions, fascial tissue fails to differentiate the adjacent structures effectively. This can happen after surgery, where the fascia has been incised and healing includes a scar that traverses the surrounding structures.