Characteristics of Fascia in Reference to Treatment Possibilities of Chosen Hand Diseases in to Possibilities of

The patomechanism of changes encountered in many movement system dysfunctions gives a basis for applying manual techniques, which have an impact on fascia’s structure, on treatment of chosen orthopedics afflictions.


Introduction
An architecture of fascia and its precise connections with many od movement system components creates a basis for putting forward presumptions of prospects of applying a fascial modelling as an important element in many orthopedic afflictions treatment.
Three-dimensional fascial web covers and penetrates such structures as: muscles, intermuscular septum's, tendons, ligaments, retinaculum's, periosteum, perineurium or dura mater. Fascia of those structures is not a separate connective tissue formation, but it bonds adjacent tissues into functional unity [1,2]. Pathological process within one of those structures will therefore effect with dysfunctions on many regions of fascial system.

Mini Review
The fascia is an anatomical structure that corresponds with dense connective tissue. Its characteristic feature is the presence of collagen fibers with minor amount of basic substance. Those properties give the tissue a net structure. It means that the fascia fibers run in several directions and at several interchanging angles, they can create a regular or irregular texture [3]. The main building material is type I collagen and highly hydrated proteoglycans [3,4]. By virtue of those components, fascia fibers are stretchable and plastic, and also resistant to mechanic stimulus. The current definition of the fascia emphasizes its meaning in tensional force transmission [5]. Collagen layers of the fascia are separated from each other by fatty tissue [2]. The outermost layer of the fascia is at least two adjacent units in vertical alignment. Myofascial chains are therefore paths, embracing distant muscle groups, including the surrounding fascia. These connections originate from the initial attachment of one muscle and go through the attachments of another muscle and are linear to the muscle fibers from head to toe [7,8]. There are four main anatomy trains in the upper limb. The DFL of the upper extremity plays a stabilizing role, participating, among other actions, in coordinated motions, as well as in the grasping motions of the thumb [2,7,8]. From the tissue physiology point of view, the fascia has been characterized as strong [9], but flexible [10], demonstrating piezoelectric properties, revealing varying rigidity with changing hydration [11], rich in nerve endings [12,13], containing a fairly high number of mechanoreceptors and able to undergo small contractions [14,15].
Its structure becomes denser [16] and thicker along the vector of the active force, which, in turn, increases it rigidity in that direction [17]. The fascia surrounds each muscle and organ in the body [10]. Its functions include motion stabilisation [18] and load transfer, not only between adjacent muscle fibres but also between muscle bundles [19,20]. It protects blood and lymphatic vessels [21], secures muscles against damage from excessive stretching [20] and protects adjacent structures from rubbing against each other [22]. The fascia also influences the venous return, ensuring appropriate drainage [23,24], improves the coordination process and enhances the muscle functionality, ensures proper tension within the musculoskeletal system [25] and suppresses the spread of infections [26]. It has been demonstrated that a more rigid fascia supports the force responsible for load transfers among muscles [27].
Due to the presence of Golgi tendon organs (GTO), Ruffini corpuscles (Bulbous corpuscles) and Pacinian corpuscles, this tissue takes part in the generation of the reflex to stretching [10], as well as in proprioception [12] and nociception [28] processes.
Changes are observed in fascia structures in the process of ageing.
Its viscoplastic properties deteriorate with age, with a higher tendency towards the occurrence of adhesions and densifications [16]. Collagen, when submitted to loads, rebuilds its structure [28,29], while oestrogens play a significant role in the process stimulation [30]. The properties of the fascia may also be changing as a result of muscle lesions or surgical intervention [31]. A pathological process within the fascia triggers inflammation, which may be a potential cause of pain [32]. Wrong motion patterns or imposed immobilisation may cause the formation of bridges between adjacent fascia layers, leading to adhesions [33].
Therefore, interventions into fascia structures would seem fairly appropriate, supporting the healing process of many orthopaedic or neurological conditions. Some scientific reports suggest that the proper manual stimulation may provide positive modelling of fascia structures in pathological conditions [34][35][36][37][38][39][40][41].
A case report, describing a patient after reconstruction of the anterior cruciate ligament (ACL), shows the positive effects of manual-fascial therapy with a rapid improvement of muscle activity [42]. In addition, the preliminary results of studies carried out among patients after a total knee replacement, proved efficacy of the manual-fascial therapy in motion recovery and in improved activity of the muscles responsible for the proper functionality of the knee joint [43]. In the mentioned study, the therapy was provided to the patients only once, which provides no grounds to draw more general conclusions regarding its applicability. At the same time, it encourages the undertaking of studies, leading to an assessment of the efficacy of the fascial therapy to be included in the global, long-term process of improving patient functionality after knee alloplastic procedures. in orthopedic afflictions. The pathomechanism of changes in carpal tunnel syndrome also seems to provide a firm basis for the application of the muscle-fascial techniques in the treatment of this condition. In nerve compression syndrome, nerve sliding becomes a constraint, which decreases its resistance to mechanical stress [47]. Adhesions, fibrosis and scars bring about pathomechanical and pathophysiological changes in the nerve [48]. A correlation has also been shown between the pathological mechanic changes within the nerve and its functionality [49].
A therapeutic strategy should also take into account the connections of the transverse carpal ligament with the structures that affect its tension, such as carpal thenar muscles, finger flexor muscle or the long palmar muscle.
The transverse carpal ligament is a collagen line, which restricts the carpal tunnel and also forms the initial attachment for the carpal thenar muscles [50]. It stabilizes the structure of the carpal tunnel [51], acts as a stretcher of flexor muscle tendons [52] and supports the flexibility of the carpal tunnel [53]. It has been shown that the transverse carpal ligament is co-formed by the long palmar muscle, thus its activity will be modelling the tendon's tension. The long palmar muscle is attached to the medial epicondyle of the humerus, while its fascia is connected with the superficial antebrachial fascia [24]. The coracobrachialis, some fibers of which terminate on the medial epicondyle of the humerus, also has attachments to the medial septum of the arm [54], the fibres of which are part of the clavipectoral fasci, surrounding the minor pectoral muscle, and which also integrates into the coracobrachialis fascia [5].
The superficial fascia connections seem to be much simpler. The palmar aponeurosis is connected with the transverse ligament and, farther, it is a continuation of the antebrachial fascia [55]. The antebrachial fascia is a continuation of the brachial fascia, while its tension is modelled by the activity of the brachial biceps muscle, the aponeurosis of which integrates into it. This aponeurosis also covers the medial nerve at the region of the ulnar joint, while its thickening may limit the sliding functionality of the nerve [56].
The brachial fascia receives bundles from the fascia of the greater pectoral muscle [57]. Increased rigidity or thickness of the transverse carpal ligament may result from the activity of repeatable forces, generated by the thenar muscles and the long palmar muscle [58]. It seems that a manual intervention within the structures may decrease their tension and improve their flexibility.
In result, decreasing the tension of the transverse carpal ligament and protecting it against changes, leading to its thickening and increased rigidity, may bring about a permanent success of the prophylactic treatment of carpal tunnel syndrome. The application of techniques, intervening into the pathologically changed fascia structures in orthopedic patients, including hand dysfunction, seems to be particularly significant in the therapeutic process. The reduced time of the patient's recovery to full mobility seems to have a number of advantages, both social and economic.