Among several primary tissues in humans, connective tissue is the most abundant and widely distributed one. Connective tissue consists of collagen fibers, proteins such as elastin, fibronectin, laminin and proteoglycans. The proteoglycans which form extremely thin fibrils interact with the surrounding interstitial fluid to form a gel-like environment 10. The CTIF system forms a body fascia frame with connected layers 911 which embeds the neurovascular tracts and connects tunicae around the visceral organs. The frame also extends to form the periosteum which supplies vascular structure to the bone, which can be considered as just another connective tissue or extracellular matrix 12. Thus the CTIF system with the "hard part" and "soft part" is an integrated network to maintain the integrity of body shape against gravity.

Electrolytes, proteins, O₂, CO₂, pass through this connective tissue-interstitial fluid (CTIF) system in transit. The cells in the CTIF system include macrophages, lymphocytes, T- and NK cells, eosinophils, adipocytes, plasma cells, fibroblasts, chondroblasts, osteoblasts, stem cells and mast cells.

The interstitial fluid (IF) transports nutrient proteins, electrolytes, oxygen and water from the blood circulation to tissues of the whole body for their functions. The IF also sends CO₂ and cellular excreta from these tissues back to the circulation and lymphatic system respectively. The nerve endings of various types of nerves are rich in the skin. The superficial fascia of the CTIF system therefore embeds a large numbers of nerve endings which contain specific and polymodal nociceptive receptors that carry out the three functions: (a) nociceptive signal as bio-warning; (b) facilitating reflexive modulation of organs; (c) defense mechanism via immune effector functions 1314151617.

Mechanical, thermal, chemical or polymodal receptors are abundant in the CTIF system 17. Moreover, there is an abundance of nociceptive receptors of various types in the deep fascia layers which are close or connecting to neurovasculature as well as lymphatic structure. For examples, the inter-muscular septa, tunicae around visceral organs, periosteum around bones are such deeper fascia layers 91011. According to Chinese medicine, the meridian channels support and regulate the functions of visceral and other organs. There is accumulative evidence that most, if not all, of the earth positions (the deepest position of the three acupuncture needling positions of depth, i.e. "sky", "man", "earth" positions) 18 of the acupoints are located in the connective tissues of the CTIF system 23456789. Thus, the author hypothesizes that those channels which can play the strongest supportive roles to organs form the Chinese medicine meridian channels.

High density sites of polymodal and specific nociceptive receptors near neurovascular structure, lymphatic vessel, mast cells become acupoints. Acupuncture applied at the collagen fibers embedding nerve fibers (Aδ and C) could send signals to the nerve fibers via the fundamental mechanotransduction mechanism 19. At a dense neurovascular structure which also innervates the lymphatic vessel, acupuncture at one branch of a "sensory tree" could therefore affect the blood circulation and lymphatic pumping activities 20.

Since nerve fibers are connected to one or more spinal cord segments, the stated mechanical stimulation can be transmitted to internal organs via the somato-visceral organ reflex 212223. Thus many sites with high density of polymodal and specific nociceptive receptors could be sites fulfilling part of the function of acupoints 24.

However, a polymodal (or certain specific) nociceptive receptor can also carry out certain effector functions 1314151617. With secretion of small amounts of neuropeptides like substance P and calcitonin-gene-related-peptide (CGRP) from nerve endings arising from noxious stimulus, the effector functions that can be fulfilled are very limited. Those polymodal and other specific receptors that are near mast cell migration tracks would have much better chances of interaction with the mast cells, leading to the degranulation of these "storage cells". The released biochemicals could engage in at least 12 physio-pathological functions under the general areas of homeostasis, immunity responses, repair and growth 252627. These functions can be grouped together to be called effector functions, as if controlled by efferent nerves from the brain. Moreover, the biochemicals involved in the effector functions can diffuse readily in a flowing interstitial fluid.

Thus as an outcome of biological development, sites with high density of polymodal and specific receptors which are also near fine blood, nervous, lymphatic structures, as well as near mast cells would develop into functional sites with high efficiency. Maneuvering with needles at these sites, which are the Chinese medicine acupoints, could lead to therapeutic effects. In fact, acupoints have been found to be near dense neurovascular structure, lymphatic structure via anatomical analysis 7, and the mast cell densities were found to be high around acupoints 2829303132.

Biophysical forces (such as mechanical and electrical forces) acting on the cell surface are effective and fast, leading to intracellular and intercellular architecture remodeling and resulting in the occurrence of accompanying biochemical reactions 19. It was shown that the nucleus, focal adhesion complex, the extracellular matrix (ECM) in connective tissue and gap junction form an integrated network to transmit mechanical stimuli, resulting even in gene regulation 333435. The connective tissues provide a living architecture for mechanical transduction which leads to subsequent biochemical responses in complex living organisms.

Acupuncture applied to connective tissue causes cytoskeletal remodeling of mechanically connected cells. A pull by the connective tissue to the mechanically connected distal cells would apply stress to the surface integrin receptors. There is growth of focal adhesion, leading to a stress-dependent increase in cytoskeletal (CSK) stiffness. The CSK stiffness changes because there is rearrangement of the microfilaments (MF), microtubules (MT) and intermediate filaments (IF). Since these structures join directly or indirectly to the nucleus surface (after such CSK remodeling), expressions of different genes are affected to produce the relevant proteins to maintain the cell integrity and the necessary physiological processes in response to the stimulus. Thus, cell nucleus, via mechanotransduction, can react directly to mechanical stress (which is initiated by acupuncture) at the cell surface receptor. Such mechanical stress when applies at the cell surface also triggers intracellular Ca²⁺ oscillation and intercellular Ca²⁺ wave, leading to a cascade of biochemical events. Details will be ready for publication shortly.

According to the electron-microscopic work of Messlinger 20, an example of Aδ nerve trunk has three branches. One branch innervated the neighbouring venous vessel, another branch innervated the lymphatic vessel, whereas the third branch was embedded in collagen fibers forming the "sensory tree". The main trunk is within the perineurium but with bead-like structure exposing in part of the main branch and all the three branches stated. The Schwann cell that myelinated the main trunk of the sensory tree was actually detached from the axon so that more bead-like structure could be exposed by mechanical pulling of the collagen fibers (like acupuncture action) which embed the third nerve branch. The beads contain more mitochondria and other vesicles which are capable of releasing neurotransmitters. Mechanical maneuvering of the collagen fibers would transmit mechanical signals to the connected blood and lymphatic vessels through the mechanotransduction mechanism. There are abundant Aδ fiber and C fiber endings in the CTIF system. Thus acupuncture could influence circulation property and lymphatic activity, as well as sensitization of polymodal receptors by inducing change in collagen tension.

Cells have long been known to orient and migrate responding to gradients of various potentials like photo-, galvano-, geo-, chemo-, hapto-taxis 36373839. Another cell migration process relevant to acupuncture research is durotaxis. Durotaxis is a process via which cells migration is guided by gradients of substrate rigidity. Mechanical properties of ECM have been reported to affect fibronectin fibril assembly inside the cell 40, to change cytoskeletal stiffness 34, strength of integrin-cytoskeleton linkages 4142. These factors not only affect the cell structure, but also cell locomotion. It was demonstrated 43 that when cells are cultured on substrates of different rigidities (but with the same chemical properties), the morphology and motility rates of cells are different. Lo et al. 42 demonstrated 3T3 fibroblasts migrate into the rigid substrate. In a more recent study, Guo et al. 44 also showed that migration of 3T3 fibroblasts could be directed by altering the tension of the substrate. Similar process is likely to occur in acupuncture which directs cells migration by affecting the stiffness of the pathway in the CTIF system.

There are many "loose cells" residing in connective tissues including macrophages, lymphocytes, adipocytes, plasma cells, eosinophils, fibroblasts, chondroblasts, osteoblasts, stem cells and mast cells 45. The solid substrate tissues can serve as the tracks of migration for the cells for physiological functions. The author hypothesizes that there are special migration tracks for fibroblasts and mast cells. Fibroblasts sustain collagen fibers 10 and mast cells upkeep the proliferation of fibroblasts 27 which tend to migrate along collagen fibers with higher stiffness 4244. The anatomical findings of Yuan et al. 9 suggest that the densities of the collagen fibers plus some proteins are higher along certain tracks correlating with the Chinese medicine meridian channels. On the other hand, mast cell densities were found to be higher around acupoints than nearby non-acupoints 2829303132 and acupoints are along the meridian channels. These four sets of experimental findings suggest the formation of special migratory tracks for fibroblasts and mast cells in the CTIF system correlating with Chinese medicine meridian channels.

Mast cells (size ~10–20 μm) are produced in bone marrow and migrate to the blood stream, peripheral tissues, and eventually to various types of connective tissues, adjacent to blood and lymphatic vessels and to the sites associated with peripheral nerves 25464748. Mast cells can go through multiple cycles of de- and re-granulation for regulating the release of at least 15 types of biomolecules including serotonin, proteases, heparin, granulocyte macrophage colony-stimulating factor (GM-CSF), leukotrienes, interleukins, tumor necrosis factor-α (TNFα), calcitonin, nerve growth factor (NGF), stem cell factor (SCF), substance P, histamine, prostaglandin, thromboxane, and other peptides like fibroblast growth factor (FGF) 252627. These biomolecules, working separately or cooperatively, are involved in (1) allergy response, (2) acquired immunity, (3) innate immunity, (4) maintaining the life of sensory neurons, (5) inflammation, (6) supporting the growth of T cells and various tissues, (7) metabolic rate, (8) noxious stimuli response, (9) blood vessel tone regulation, (10) fibroblast growth, (11) wound healing, and (12) osteoblast formation 27. Mast cells are believed to interact with connective tissue matrix components through integrins 49. There is ample evidence of mast cell – nerve cell interaction 505152. The interaction between mast cells and nerve cells would cause degranulation of the former leading to the release of said biomolecules as physiological or pathophysiological responses. Mast cells densities are higher at acupoints 2829303132. There is evidence that acupuncture could also cause degranulation of mast calls directly through mechanical stress 30. Thus, mast cells could be mediators of the effector functions of acupuncture action.

The whole interstitium is considered to be four times of the blood in volume. All extracellular fluids are in dynamic equilibrium with other fluid systems (like lymphatic fluid) of the body. The instantaneous interstitial fluid pressures Pi at different locations in the interstitium are not equal, depending on many factors, such as: (1) difference in protein and electrolyte concentrations between the blood and the interstitial fluid, (2) blood flow rates at the capillaries and venules, (3) pressures at the arterial and venous ends of these small vessels which vary in different organs, (4) the effective pumping activities of the lymphatic ducts 4553.

The interstitial fluid pressures are different at different sites and different body positions 54555657. As the interstitial fluid flows, a pressure acts on the adjacent connective tissues inside the interstitium and changes the shapes of these connective tissues. Such changes in pressure would in turn influence the flow speed and the value of Pi until a dynamic equilibrium is restored 58. Like a stream flowing along a bank with stones of various sizes, not all the water molecules flow at the same speed; rather, the flow with the fastest speed emerges.

There is experimental evidence to show that interstitial fluid flows along the meridian channels as demonstrated by radioactive tracing studies 59606162. On the other hand, other radioactive studies on animal and humans demonstrated that the tracks of flow were not along blood vessels 636465. The above experimental evidence of Chinese medicine meridian channel research, knowledge of physiology and basic physics suggest that the interstitial fluid is not stationary, but flows along certain parts of the body, which is a consequence of difference in Pi in different parts of the body. The lymphatic pumps are part, but not all the causes of fluid flow in IF.

Using biorheology techniques designed by Guyton et al. 66 and Levick 67, Zhang et al. 6869 found that interstitial fluid flows with the smallest resistance existed along the longitudinal directions of animal bodies. The measured speed of flows is much slower than that of blood circulation.

Using magnetic resonance angiography and magnetic resonance imaging (MRI) techniques, Li et al. 70 demonstrated in humans that the six specific migration channels of interstitial fluid were not blood and lymphatic vessels. The flows followed the six Yin Chinese medicine meridian channels in the upper and lower limbs 70. Thus, this is an important piece of evidence to support that some interstitial fluid flows along the six Yin meridian channels.

Meridian channels embedded in the CTIF system provide specific paths of cell migration and interstitial fluid flows 282930313259606162636465. Such specific paths indicate that meridian channels should have tissue boundaries. While the tissue boundaries throughout meridian channels have not been fully elucidated, investigation into the sites of acupoints 2345678, which are hypothesized to be high efficient, specific functional sites along meridian channels, do provide information about the tissue boundaries of meridian channels near the acupoints. In particular, Yuan et al. 9 analyzed the images from digital data set derivable from slices of cadavers and found that 361 acupoints were located in five types of connective tissues: (a) dense connective tissue in the dermal reticular; (b) subcutaneous loose connective tissue; (c) intermuscular (loose) septa; (d) (loose) connective tissues embedding neuromuscular tracts; (e) (loose) connective tissues at the visceral hili and tunicae. Dang et al. 4's work indicated that 9 out of 11 of the acupoints of the lung meridian were on the periosteum, one on the perineurium of the (radial) nerve, another on the adventia of the (radial) artery. These findings suggest that the meridian channels are bound below by a layer of connective tissues of various types. On the other hand, longitudinally distributed lines with rich sympathetic substance (neurotransmitters) were found in the skin in animal studies by Liu et al. 7172, suggesting that these lines with high nerve activities form the "upper boundary" of the Chinese medicine channels. As the acupoints along the meridian channels are proposed to be functional sites with high efficiency and specificity, they need to be: (1) near dense nerve structure (abundant nerve endings with polymodal and other receptors) and (2) dense vasculature, (3) near lymphatic vessels, (4) with interstitial fluid flowing through. Such characteristics are also supported by anatomical studies 773.

Based on the modern concepts of biomedical science and recent advances in acupuncture research, the author puts forth the following hypothesis:

The Chinese medicine meridian channel system has a structure bounded by the skin where there are abundant nociceptive receptors of various types and bound below by another layer of connective tissue with flowing interstitial fluid (including proteins with surface charges and ions) as ground substance. The interstitial fluid in the meridian channel participates in the continuous redistribution of the interstitial fluid pressure Pi in the body during body movement. These extracellular channels provide favorable migratory tracks mainly due to durotaxis for mast cells, fibroblasts and other cells (including adult stem cells) which carry out a number of physiological functions like triggering neurogenic inflammation, vasotone homeostasis, wound repair, giving the organism the optimum chance of survival. Acupoints are functional sites along the meridian channels. Acupuncture applied to these sites could improve the efficiency of the above functions through mast cell degranulation with specificity.