Fact-checked by Grok 2 weeks ago

Tendon

A tendon is a tough, flexible band of dense fibrous that connects muscle to or other structures, such as the eyeball, serving as a mechanical bridge to transmit the force generated by to enable movement and skeletal stability. Unlike ligaments, which connect to to maintain structural integrity, tendons specifically facilitate motion by linking contractile muscle to the skeletal . Tendons exhibit a hierarchical structure optimized for tensile strength and force transmission, consisting of collagen molecules organized into , fibers, fascicles, and finally the tendon proper, with all components aligned parallel to the tendon's long axis. Their composition is dominated by , accounting for 60–85% of dry weight—primarily (about 95%)—along with smaller amounts of types III, V, XI, XII, and XIV, as well as non-collagenous elements like proteoglycans (e.g., , comprising ~80% of this category), glycoproteins such as for , and elastic fibers including and fibrillins. This provides the tendon with remarkable mechanical properties, allowing it to withstand high tensile forces while exhibiting varying strain capacities: energy-storing tendons, like the Achilles, can stretch over 10%, whereas positional tendons typically strain 2–3%. Tendons play a critical role in locomotion and load-bearing across the body, with over 4,000 named tendons in humans varying in size, shape, and location to suit specific biomechanical demands, such as the robust at the ankle or the slender flexor tendons in the hand. They receive blood supply primarily from surrounding tissues and intrinsic vascular networks, which influences healing potential, and are susceptible to injuries like or rupture due to overuse, aging, or , highlighting their importance in musculoskeletal health.

Overview

Definition and Basic Characteristics

A tendon is a tough, flexible band of dense fibrous that connects muscle to or other structures, serving as a mechanical bridge to transmit the forces generated by to the skeletal system. This structure enables efficient movement by converting muscular effort into precise actions while minimizing energy loss. Tendons are primarily composed of , which constitutes 60–85% of their dry weight, predominantly that provides structural integrity. They exhibit high tensile strength, typically ranging from 50 to 100 MPa, allowing them to withstand substantial loads without rupture, alongside low elasticity that ensures force transmission with minimal deformation. In adults, tendons are poorly vascularized, with nutrition supplied by both from surrounding fluids (particularly in sheathed tendons via ) and limited vascular networks, contributing to their durability but limiting rapid repair. Unlike ligaments, which connect to to stabilize joints, tendons specifically link muscles to bones to facilitate motion. The contains approximately 4,000 tendons, a number that varies across depending on locomotor demands and anatomical complexity.

Etymology and Historical Context

The term "tendon" derives from the tendōn-, tendō, borrowed from tendron and ultimately tracing back to the ténōn (τένων), meaning "sinew" or "tendon," which evokes the structure's stretched, fibrous quality. This root aligns with the Proto-Indo-European ten-, signifying "to stretch," reflecting the tendon's role in extending muscular force, while the Latin influence through tendere ("to stretch") further emphasized its elastic properties in early anatomical . In ancient contexts, similar concepts appeared in medical texts, where sinews and tendons were part of the metu system—encompassing vessels, ducts, muscles, and cords vital to life—often viewed mystically as conduits for vital energies sustaining the body. Early historical understanding of tendons emerged in Greek medicine, with (c. 460–370 BCE) describing them as "sinews" (neura in ), robust cords connecting muscles to bones and essential for movement, though sometimes conflated with due to shared . Building on this, (129–216 CE), the Roman physician and anatomist, advanced the distinction between tendons and ligaments in works like Anatomical Procedures, portraying tendons as white, pliant, tear-resistant fibers transmitting muscle contractions to bones, while ligaments served primarily to bind joints, marking a shift toward functional differentiation based on dissection of animal models. These ancient contributions laid foundational observations, transitioning from empirical wound descriptions to systematic anatomical inquiry. The revitalized tendon study through detailed illustrations, as seen in Andreas Vesalius's De Humani Corporis Fabrica (1543), which featured precise woodcuts of human tendons integrated with musculature, correcting Galenic errors via direct cadaver dissection and emphasizing their gross structural attachments. By the , early advanced the understanding of structures, pioneering histological analysis beyond macroscopic views. In the , further refined tendon , describing their cellular and extracellular components—such as nucleated fibroblasts amid dense fibrous matrices—in his Manual of Human Histology (1853–1854), establishing tendons as specialized connective tissues and bridging microscopic detail with physiological function. This progression from ancient mystical and descriptive accounts evolved into modern , where tendons are analyzed as viscoelastic structures optimizing force transmission, informed by quantitative imaging and material science.

Anatomy and Structure

Gross Anatomy and Location

Tendons are tough, fibrous connective tissues that typically appear as elongated, cord-like structures or broader flat sheets known as aponeuroses, serving to connect muscle to or to other muscles. These structures vary in shape and size depending on their location and function, with many enclosed within synovial sheaths that provide to facilitate smooth gliding over bony surfaces during movement. In the human body, tendons are distributed across major regions, including the upper and lower limbs and the trunk. For example, in the upper limb, the biceps brachii tendon originates from the supraglenoid tubercle of the scapula and the coracoid process, extending through the shoulder joint to insert on the radial tuberosity, forming a key component of elbow flexion. In the lower limb, the Achilles tendon represents one of the largest examples, connecting the gastrocnemius and soleus muscles to the calcaneal tuberosity of the heel bone; it measures approximately 15 cm in length with an average thickness of 4–7 mm. Similarly, the patellar tendon links the inferior patella to the tibial tuberosity, spanning roughly 5 cm in length and 20-30 mm in width, while the quadriceps tendon unites the four heads of the quadriceps femoris muscle to the superior patella. In the trunk, tendons of the erector spinae muscles attach along the vertebral column and ribs, providing support for spinal extension and posture. Notable variations in tendon organization include sesamoid tendons, which incorporate small sesamoid bones embedded within them to reduce friction and alter force direction at joints; prominent examples occur in the hand, such as within the flexor pollicis brevis tendon at the of . Additionally, some muscles feature tendinous intersections, transverse fibrous bands that segment the muscle belly, as seen in the rectus abdominis where three such intersections divide the muscle into distinct segments along its length. The tendons in the exemplify a specialized grouping, comprising the tendons of the supraspinatus, infraspinatus, teres minor, and subscapularis muscles, which converge to form a continuous musculotendinous cuff encircling the humeral head for stability.

Microscopic Composition

Tendons exhibit a hierarchical organization at the microscopic level, consisting of fibers bundled into primary fiber units, which are further grouped into larger fascicles that form the core of the tendon unit. These fascicles are surrounded by delicate sheaths: the endotenon, which forms internal septa separating individual fascicles and providing structural support, and the epitenon, an outer sheath that encases the entire bundle of fascicles. This layered architecture allows for efficient force distribution while maintaining flexibility and resilience. The collagen fibers within fascicles are arranged in a parallel, unidirectional alignment, optimizing the tendon's ability to withstand high tensile loads during . A characteristic feature of these fibers is the crimp pattern, a wavy with a crimp typically ranging from about 20 μm in energy-storing tendons to 100–400 μm in positional tendons, which contributes to the tendon's elasticity by allowing limited extension under low loads before straightening for maximum strength. This microstructural alignment ensures that tendons can transmit forces effectively without fracturing under physiological . Tendons possess sparse compared to other connective tissues, reflecting their for durability over metabolic activity. In flexor tendons, which are often intra-synovial, blood supply is provided through vincula—thin mesothelial folds containing arteries and veins that connect the tendon to surrounding structures. In contrast, extensor tendons and other extra-synovial types rely on the paratenon, a loose fibroelastic layer that facilitates diffusion and vascular ingress. This limited supports tendon longevity but can pose challenges during . Nerve innervation in tendons is of low density, primarily serving proprioceptive functions rather than sensory or . Specialized mechanoreceptors, such as Golgi tendon organs, are embedded among the fibers near the musculotendinous junction, detecting changes to provide on muscle force and joint position. This sparse helps regulate movement and prevent overload without compromising the tendon's compact structure.

Extracellular Matrix

The () of tendons is predominantly composed of , which constitutes 60-85% of the dry weight and forms the primary structural scaffold responsible for the tissue's tensile strength. This is organized into with diameters ranging from 50 to 500 , assembled through a quarter-stagger where individual collagen molecules are offset by approximately 67 along their length, enabling the formation of banded structures visible under electron microscopy. The structure of these collagen molecules follows a repeating sequence of (\text{[Gly](/page/Glycine)-X-Y})_n, where () occupies every to facilitate tight packing, X is frequently (), and Y is often (), stabilizing the through hydrogen bonding. Intermolecular cross-links, such as pyridinoline, further enhance the stability of these by forming covalent bonds between and hydroxylysine residues, contributing to the ECM's resistance to mechanical stress. Other key matrix elements include , which account for 1-5% of the dry weight and include as the predominant small leucine-rich that regulates assembly and spacing. comprises 1-2% of the dry mass, providing limited recoil properties to the otherwise stiff matrix, while reaches 60-70% of the total weight, ensuring and facilitating diffusion within the avascular . With aging, the tendon ECM undergoes remodeling characterized by increased cross-linking density, particularly of and enzymatic cross-links like pyridinoline, which stiffens the matrix and reduces its elasticity, potentially predisposing older tendons to . These changes alter the , leading to larger diameters and decreased compliance without significant shifts in overall content.

Cellular Components

The primary cellular components of tendons are tenocytes, which comprise approximately 90% of the resident cell population and function as highly specialized fibroblasts responsible for synthesizing and maintaining the . Recent studies have revealed heterogeneity among tenocyte subpopulations with distinct profiles. In younger tendon tissue, tenoblasts predominate as the immature precursors to tenocytes, exhibiting greater proliferative capacity to support tissue growth and repair. These cells are characteristically elongated and aligned longitudinally parallel to the fibers, enabling efficient force transmission and interaction with the surrounding matrix. Tenocytes display a distinctive with elongated nuclei and a thin, stretched that contains abundant rough and Golgi apparatus, facilitating the production of and other extracellular proteins. Their stellate shape in cross-section allows sparse distribution in rows between collagen bundles. Due to the relative avascularity of tendon mid-substance, tenocytes maintain a low , characterized by quiescence and limited proliferation, which contributes to the tissue's slow remodeling and healing processes. In addition to tenocytes, tendons contain minor populations of other cell types, including chondrocytes within fibrocartilaginous regions such as entheses, where they form a graded between tendon and to distribute mechanical stress. Resident immune cells, notably macrophages, are present in small numbers and contribute to ongoing remodeling by modulating and matrix turnover. Tendon cellularity is notably low, with cell densities decreasing progressively with age, which further constrains regenerative potential.

Physiology and Function

Mechanical Properties

Tendons exhibit remarkable mechanical properties that enable them to withstand substantial loads while transmitting forces efficiently. The of human tendons typically ranges from 50 to 150 , allowing them to endure high stresses without rupture under normal physiological conditions. The modulus of elasticity, which quantifies the tendon's , generally falls between 1.0 and 2.0 GPa, reflecting their ability to deform elastically under . These properties vary slightly across tendon types and individuals, influenced by factors such as age and loading history, but they collectively ensure tendons function as durable, compliant connectors between muscle and . Tendons display viscoelastic behavior, meaning their mechanical response depends on the rate and includes time-dependent phenomena like and . This is evident in the characteristic stress- curve, which consists of three regions: the initial toe region (up to ~2% ), where collagen fibers uncrimp; the linear region, where the tendon behaves elastically; and the region, marked by progressive damage leading to rupture. in this curve indicates energy dissipation as during loading-unloading cycles, with the area between the curves representing lost energy, which increases at higher rates due to the viscoelastic nature. The Young's modulus E is defined as the ratio of stress \sigma (force per unit area) to strain \varepsilon (relative deformation) in the linear region: E = \frac{\sigma}{\varepsilon} This parameter typically yields values of 1-2 GPa for human tendons, with failure occurring at strains of 10-15%, beyond which irreversible damage predominates. A key aspect of tendon is their capacity for storage and , particularly in tendons like the Achilles, which can return approximately 90% of stored energy during gait cycles to enhance efficiency. This contributes to overall by recycling , though the exact efficiency varies with activity intensity and individual tendon properties.

Role in Locomotion and Force Transmission

Tendons serve as critical intermediaries in the musculoskeletal system, transmitting contractile forces generated by muscles to s, thereby enabling joint motion and overall locomotion. In the classic Hill-type muscle model, the tendon functions as the series elastic component (), positioned in series with the contractile muscle fibers to absorb and relay forces without significant energy loss. This arrangement allows muscle contractions to produce precise and efficient movements, such as during walking or jumping, where the tendon's elasticity decouples muscle shortening from bone movement, optimizing force application across joints. A key physiological role of tendons lies in enhancing energy efficiency through the stretch-shortening cycle (SSC), particularly in dynamic activities like running. During the eccentric phase of the SSC, tendons such as the Achilles store elastic energy as they stretch under load, which is then released during the subsequent concentric phase to augment muscle power output. This mechanism reduces the metabolic cost of locomotion by minimizing the work required from muscles; for instance, elastic energy recovery from the Achilles tendon during running can decrease overall muscle work by up to 35%, contributing to greater endurance and speed. Tendons also provide essential passive stability to joints and by generating that resists excessive motion. In upright standing, the maintains ankle through its non-linear elastic properties, preventing unintended dorsiflexion and supporting without constant muscular effort. This passive helps stabilize the body against gravitational forces, ensuring efficient energy use during prolonged static s. Adaptations in tendon length and properties further refine their role in , particularly in high-power activities. The length-tension relationship of associated muscles is influenced by tendon length, allowing longer tendons—as observed in elite sprinters—to position muscle fibers near their optimal operating lengths on the force-velocity curve, thereby enhancing power output and stride efficiency. These adaptations enable greater storage and rapid recoil, supporting explosive movements like sprinting.

Sensory and Regulatory Functions

Tendons contribute to sensory functions primarily through specialized mechanoreceptors that provide feedback on muscle tension and position. , located at the musculotendinous junction, serve as key proprioceptors by detecting active and passive tension in the tendon. These encapsulated sensory endings are innervated by group Ib afferent fibers, which transmit signals to the to modulate muscle activity. When tension exceeds the GTO threshold—typically in the range of low to moderate forces—these organs activate, triggering autogenic inhibition of the agonist muscle via inhibitory interneurons, thereby preventing excessive force and protecting the tendon-muscle unit from overload. This reflex mechanism enhances proprioceptive awareness during movement by integrating tension feedback with . In addition to proprioception, tendons play a role in pain signaling through nociceptive pathways. Free nerve endings, primarily from small-diameter Aδ and C fibers, are distributed within the tendon tissue and serve as polymodal nociceptors, responding to mechanical, thermal, and chemical stimuli. These endings detect damaging levels of tension or inflammation, initiating pain perception that alerts the body to potential injury. During inflammatory responses, such as in tendinopathy, sensory nerves release neuropeptides including substance P and calcitonin gene-related peptide (CGRP), which amplify nociception and promote vasodilation, edema, and further neuropeptide release in a positive feedback loop. Substance P, in particular, correlates with increased pain and neural sprouting in pathological tendons, while CGRP contributes to neurogenic inflammation. Tendons also exhibit regulatory functions through cellular mechanotransduction and metabolic adaptations. Tenocytes, the primary resident cells, sense mechanical loading via and focal adhesions, transducing physical cues into biochemical signals that regulate . A prominent pathway involves the Hippo effectors (Yes-associated protein) and TAZ (transcriptional coactivator with PDZ-binding motif), which translocate to the under appropriate strain to upregulate genes for production, such as type I, thereby maintaining tendon and adapting to load. This mechanoregulation ensures long-term integrity without excessive remodeling. Metabolically, tendons have a low basal rate, with oxygen consumption approximately 7.5 times lower than , reflecting their avascular nature and reliance on . Under stress or , tenocytes shift to increased production via elevated glycolytic flux, supporting needs while tolerating low oxygen environments.

Development and Maintenance

Embryonic and Postnatal Development

Tendons originate during embryonic development from distinct mesodermal compartments. Axial tendons derive from the sclerotome of somites, while limb tendons arise from the lateral plate mesoderm. Tendon progenitor cells are marked by the expression of the scleraxis (Scx) gene, a basic helix-loop-helix transcription factor that initiates and maintains tendon lineage specification. The initial stages of tendon formation involve mesenchymal condensation, occurring around weeks 6-7 of , where progenitor cells aggregate near developing muscles and bones. By week 12, further maturation includes of tenocytes and alignment of fibers along the longitudinal axis to form the tendon proper, facilitating force transmission. At the tendon-bone interfaces, known as entheses, transitional tissues begin to develop during the fetal period, with fibrocartilaginous zones forming postnatally to enable graded mechanical transitions. Genetic regulation plays a pivotal role in tendon patterning and differentiation. , particularly Hox11 paralogs, coordinate regional specification and integration of tendon, muscle, and tissues during embryogenesis. Additionally, transforming growth factor-β (TGF-β) signaling induces Scx expression in progenitors and promotes tenocyte differentiation, ensuring proper tendon morphogenesis. Postnatally, tendons undergo significant and maturation, particularly during childhood, with increasing approximately 2-3 times in proportion to overall body from birth to adulthood. Mechanical properties, including stiffness and strength, continue to develop through , reaching peak levels by ages 20-30 due to progressive organization and cross-linking.

Collagen Synthesis and Tissue Remodeling

Collagen synthesis in tendons primarily occurs within tenocytes, the resident fibroblast-like cells, where type I procollagen is assembled intracellularly through a series of post-translational modifications. The process begins with the transcription and translation of procollagen chains, followed by of and residues for stability and to facilitate folding and . Once properly modified, the procollagen trimer is packaged into vesicles and secreted into the via . In the , procollagen undergoes proteolytic to mature : the N-terminal propeptide is removed by ADAMTS-2, -3, or -14 enzymes, while the C-terminal propeptide is cleaved by bone morphogenetic protein 1 (). This enables the spontaneous self-assembly of molecules into quarter-staggered , which are further stabilized by cross-linking enzymes such as lysyl oxidase. These aggregate into larger fibers, forming the hierarchical structure essential for tendon tensile strength. Tendon remodeling maintains integrity through a balance of and , with exhibiting a of approximately 300-1000 days in humans, reflecting relatively slow turnover compared to other connective s. is mediated by matrix metalloproteinases (MMPs), particularly MMP-1, -2, and -13, which cleave , while inhibitors of metalloproteinases (TIMPs), such as TIMP-1 and -2, regulate MMP activity to prevent excessive breakdown. This allows tendons to adapt to mechanical demands without compromising structural integrity. Mechanical loading, such as from exercise, upregulates in tenocytes via mechanotransduction pathways, including the PI3K/Akt signaling cascade, which activates transcription factors and enhances procollagen production. Studies in humans show that acute exercise can increase tendon rates by 50-100% within hours to days post-loading, promoting thickening and improved tensile properties. With aging, tendon collagen turnover decreases due to reduced tenocyte proliferative capacity and increased advanced end-product () cross-links, leading to greater rigidity and brittleness. solubility, a measure of extractability, declines with age, correlating with diminished remodeling efficiency and heightened susceptibility.

Factors Influencing Tendon

Several lifestyle, environmental, and physiological factors influence tendon health by modulating collagen synthesis, tissue remodeling, and mechanical integrity. Moderate mechanical loading through exercise promotes tendon adaptations, including and increased stiffness, which can enhance tendon strength by approximately 5-10% over training periods of several weeks to months. In contrast, excessive or overuse loading contributes to the accumulation of microdamage within tendon fibers, impairing self-repair mechanisms and leading to degeneration if not adequately managed. Nutritional factors play a critical role in maintaining tendon extracellular matrix stability, with vitamin C serving as an essential cofactor for prolyl hydroxylase in the hydroxylation of proline residues during collagen synthesis. Deficiency in vitamin C, as seen in scurvy, disrupts this process, resulting in weakened collagen structures and tendon fragility due to impaired cross-linking and increased susceptibility to rupture. Supplementation with collagen peptides has shown mixed efficacy in supporting tendon health, with some studies reporting improvements in tendon cross-sectional area and biomechanical properties when combined with resistance training, while others indicate inconsistent benefits for preventing degeneration. Hormonal influences significantly affect tendon resilience, particularly in sex-specific ways. Estrogen exerts protective effects on female tendons by enhancing synthesis and maintaining biomechanical properties, potentially reducing degeneration risk during reproductive years. Conversely, systemic or local administration of corticosteroids accelerates tendon degeneration by suppressing , inducing in tenocytes, and inhibiting production, thereby weakening tendon structure over time. Age and genetic predispositions further shape tendon health trajectories. Tendons typically achieve peak structural integrity and functional capacity between 20 and 40 years of , after which age-related declines in cellular activity and turnover lead to reduced and increased vulnerability to overload. Genetic variations, such as in the COL1A1 gene, underlie conditions like certain forms of Ehlers-Danlos syndrome, where defective production results in tendon hyperextensibility, fragility, and heightened injury risk.

Clinical Significance

Common Injuries and Pathologies

Tendon injuries can be broadly classified into acute and chronic categories, each presenting distinct pathological features. Acute injuries typically result from sudden, high-force events and include tendon strains and ruptures. Tendon strains are graded from 1 to 3 based on severity: grade 1 involves minor stretching or micro with minimal fiber disruption and no significant loss of function; grade 2 represents partial affecting a portion of the tendon fibers, leading to moderate functional impairment; and grade 3 denotes complete or ruptures where the tendon is fully severed, resulting in substantial loss of strength and mobility. Ruptures are particularly common in tendons like the Achilles, often occurring in athletes or active individuals aged 40 to 60 years during explosive activities such as sprinting or jumping. Chronic conditions encompass degenerative and inflammatory disorders that develop over time due to repetitive stress. , a prevalent overuse injury, involves tendon degeneration without prominent and affects sites like the , where it is common among athletes in overhead sports such as or , with shoulder injury rates up to 30% in collegiate overhead athletes including rotator cuff tendinopathy. Another common chronic pathology is , characterized by of the , often seen in the or hand tendons and leading to restricted gliding motion. The of these injuries includes mechanical overload, degenerative changes, and systemic factors. Overload, particularly from eccentric loading where the tendon lengthens under tension, is a primary trigger for both acute strains and chronic , as it exceeds the tendon's adaptive capacity. Degeneration in hypovascular zones—regions with poor blood supply, such as the mid-portion of the —predisposes to weakening and failure over time. Systemic conditions like contribute by promoting widespread inflammation that affects tendon integrity. Symptoms of tendon injuries generally include localized that worsens with activity, swelling, and due to impaired force transmission. In chronic cases like , patients may experience stiffness and reduced , while often presents with —a grating sensation during movement. Diagnostic signs aid in identification; for instance, the for Achilles rupture involves squeezing the calf while observing for absent plantarflexion of the foot, indicating discontinuity.

Healing Mechanisms

Tendon healing following is a complex, overlapping process involving three distinct : , , and remodeling. The inflammatory , lasting approximately 1 to 7 days, is characterized by the influx of inflammatory cells such as neutrophils and macrophages, which release cytokines like interleukin-1 and tumor necrosis factor-alpha to clear debris and initiate repair signals. This sets the stage for subsequent regeneration but can contribute to excessive if prolonged. The proliferative phase follows, spanning roughly weeks 1 to 6, during which fibroblasts migrate to the injury site and begin synthesizing components, predominantly type III , to form a preliminary bridge. Tenocyte is driven by growth factors such as (PDGF), which stimulates cell migration and division, while (VEGF) promotes to supply nutrients and oxygen to the healing area. This results in the formation of a disorganized matrix, often leading to that lacks the hierarchical structure of native tendon. The remodeling phase begins around 3 months post-injury and can extend for 6 to 12 months or longer, involving the gradual replacement of type III collagen with aligned fibers to restore tensile strength and organization. During this period, matrix metalloproteinases and other enzymes facilitate tissue maturation, though the healed tendon typically achieves only 80-90% of its original biomechanical properties. Biomechanically, the repaired tendon exhibits significant initial weakness, emphasizing the need for protected loading to prevent failure. Full functional recovery, including near-normal strength and stiffness, generally requires 6 to 12 months, as collagen cross-linking and fiber alignment continue progressively. Complications in tendon healing include scar adhesions, which can limit motion by tethering the tendon to surrounding tissues, and re-rupture, with rates of 1-4% following surgical repair and 5-12% in conservative management, influenced by rehabilitation protocols. These issues arise from inadequate matrix organization and excessive mechanical stress during early phases.

Diagnosis and Treatment Approaches

Diagnosis of tendon disorders typically begins with a thorough clinical evaluation, including patient history and to assess , swelling, and functional limitations. Specific clinical tests, such as the empty can test for supraspinatus tendon involvement, involve positioning the arm in 90 degrees of and internal with the thumb down, resisting downward pressure to detect indicative of a tear; this test demonstrates high sensitivity for supraspinatus pathology when combined with imaging. Imaging modalities play a crucial role in confirming tendon abnormalities. Ultrasound is particularly valuable for dynamic assessment, allowing real-time visualization of tendon structure, motion, and blood flow during movement, with sensitivity often exceeding that of MRI for detecting certain tears like those in ankle tendons. Magnetic resonance imaging (MRI) serves as the gold standard for detailed evaluation of tendon tears, especially partial or full-thickness ones greater than 3 mm in depth, providing high-resolution images of tendon integrity, surrounding tissues, and associated pathologies. Conservative treatments form the first-line approach for most tendon disorders, emphasizing non-invasive methods to reduce and promote recovery. The RICE protocol—rest, ice, compression, and elevation—is widely recommended initially to manage acute symptoms and minimize swelling. Eccentric exercises, such as the Alfredson protocol for Achilles tendinopathy, involve three sets of 15 repetitions twice daily for 12 weeks, focusing on controlled lengthening of the tendon under load to stimulate remodeling and improve tensile strength. Nonsteroidal anti-inflammatory drugs (NSAIDs) are commonly used to alleviate and , though evidence suggests they do not alter long-term outcomes and should be limited to short-term use. Surgical interventions are reserved for cases unresponsive to conservative management or severe structural damage. Debridement involves removing degenerative or calcified to preserve healthy tendon portions, often yielding good outcomes with return to in 2 weeks using supportive devices. Tendon repair techniques, such as methods for Achilles ruptures, utilize small incisions to suture the tendon ends, minimizing disruption and facilitating faster compared to open surgery. Augmentation with grafts, including autografts or allografts, reinforces repairs in chronic or large defects, enhancing biomechanical stability during the phases of , , and remodeling. Emerging therapies aim to accelerate tendon repair through biologic augmentation, though evidence remains mixed and further research is needed. (PRP) injections, derived from autologous blood, deliver growth factors to the injury site; clinical trials show variable results, with some demonstrating improvements in pain and function while meta-analyses indicate no consistent superiority over . therapies, particularly mesenchymal stem cells, promote regeneration by modulating and enhancing production; as of 2024, a phase IIa trial has demonstrated safety and proof-of-concept efficacy in treating non-insertional Achilles , with ongoing studies evaluating long-term outcomes.

Comparative and Evolutionary Aspects

Tendons in Non-Human Animals

Tendons in non-human animals exhibit diverse structural and functional adaptations tailored to species-specific locomotor demands, differing notably from those in humans by emphasizing , recoil efficiency, or robustness in extreme environments. In mammals, these adaptations are particularly evident in specialized locomotion. For instance, kangaroos possess highly elastic hindlimb tendons analogous to the , which stretch during hopping to store and return elastic energy, enhancing jumping efficiency and reducing metabolic costs by up to 70% at speeds of 6 m/s. Similarly, in , the superficial digital flexor tendon (SDFT) functions as a key energy-storing structure during galloping, where it stretches and recoils to absorb and release , supporting high-speed propulsion while bearing substantial up to 16% per stride. These mammalian tendons often feature optimized collagen-elastin compositions to balance and elasticity for repetitive, high-impact activities. In and reptiles, tendon adaptations prioritize rapid force transmission over extensive , reflecting aerial or terrestrial constraints. muscles, such as the pectoralis, are typically parallel-fibered with short tendons that minimize , enabling direct power delivery for flapping wings without significant delay. In contrast, the supracoracoideus muscle has a longer tendon for upstroke control, but overall, tendons are reduced in relative to body size to optimize speed and reduce mass. Reptilian tendons show similar trends, but crocodiles display robust tendons integrated with their adductor musculature, supporting powerful bite forces exceeding 16,000 Newtons through reinforced tendinous insertions that enhance mechanical during prey capture. Elastin content varies markedly across species, influencing tendon compliance for environmental adaptations. Cetaceans, such as whales and dolphins, have tendons with notably high elastin levels to facilitate elastic recoil during prolonged diving and tail-powered swimming, allowing energy storage for efficient propulsion in aquatic media. In amphibians, tendons contain elastic fibers that support recoil, suited to short bursts of jumping or crawling. These variations underscore how tendon composition evolves to match ecological niches, such as buoyancy challenges in cetaceans or terrestrial hopping in amphibians. Veterinary medicine highlights the clinical impact of these adaptations, particularly in performance animals. In racehorses, SDFT tendinitis is a prevalent , with incidence rates ranging from 6% to 20% across age groups, often triggered by repetitive galloping strains that exceed the tendon's energy-storage limits and lead to microdamage accumulation. Such conditions underscore the trade-off between enhanced locomotor performance and injury vulnerability in domesticated species.

Evolutionary Origins and Adaptations

Tendons trace their evolutionary origins to early chordates during the Cambrian period, approximately 500 million years ago, when the phylum first emerged. In the basal chordate Branchiostoma (commonly known as amphioxus), the earliest tendinous structures appear as myosepta—thin, sheet-like connective tissues composed of a two-dimensional array of collagen fibers arranged to transmit tension across multiple directions between muscle segments. These myosepta represent a primitive adaptation for force transmission in an aquatic environment, predating the more specialized linear tendons seen in jawless vertebrates like hagfish. Homologs of scleraxis, a key transcription factor involved in tendon progenitor cell specification in vertebrates, have been identified in amphioxus, suggesting conserved genetic mechanisms for connective tissue development across chordates. Over phylogenetic time, tendons exhibited increased structural complexity, particularly with the transition to tetrapods and around 360 million years ago. In early tetrapods, tendons co-evolved with and to support and on land, evolving from simple myoseptal sheets into hierarchical bundles capable of handling unidirectional tensile loads. This co-evolution is evident in the development of specialized tendon insertions at muscle-bone interfaces, enhancing force transmission efficiency and enabling more dynamic movement compared to the axial undulations of aquatic chordates. In jawed vertebrates, further adaptations included fibrocartilaginous pads and sesamoid bones within tendons to manage compressive forces, first appearing in cartilaginous fishes and becoming widespread in bony fishes and tetrapods. Tendons display diverse adaptations shaped by locomotor demands and ecological pressures. In cursorial mammals, such as antelopes and horses, evolutionary selection has favored longer distal tendons, particularly the , which store and release to improve running efficiency and reduce metabolic cost during high-speed . in tendon properties also occurs, with males often exhibiting greater tensile strength and cross-sectional area to support larger body sizes and agonistic behaviors; for instance, male possess robust tendons adapted for powerful upper limb exertion in territorial displays. These variations highlight tendons' role in optimizing force transmission for species-specific lifestyles. Fossil evidence provides direct insights into ancient tendon function, including impressions preserved in dinosaur tracks that reveal patterns of force transmission through soft tissues. Such impressions, recording the contours of , , and tendons alongside bony structures, indicate that non-avian utilized tendons for efficient load distribution during , similar to modern vertebrates. Ossified tendons, common in ornithischian and theropod , further demonstrate evolutionary continuity in tendon mineralization as an adaptation for stiffening the tail and to enhance stability.

Cultural and Practical Uses

Culinary and Nutritional Roles

Tendons, primarily composed of , are utilized in various culinary traditions where their tough, fibrous texture requires slow cooking methods to break down into tender, gelatinous forms. In , tendons are a staple in , a , where they are simmered for hours in aromatic to contribute a chewy texture and rich flavor. Similarly, in dim sum, tendons appear in braised preparations such as suan bao niu jin, marinated with and slow-cooked until soft and succulent. These preparations often involve blanching to remove impurities before prolonged or , enhancing the extraction of into the for a silky consistency. In , tendons may be incorporated into , a spicy where connective tissues from or cuts gelatinize during extended with chiles and spices. The high content in tendons makes them an excellent source for production, achieved through where raw tendons are treated with or and heated to yield a gel-forming protein. derived from tendons typically exhibits a high bloom strength of 200-300 grams, indicating strong gelling properties suitable for culinary applications like stocks and desserts. This process not only tenderizes the tissue but also enriches soups and stews with natural thickening agents. Nutritionally, tendons are a dense source of protein, with 100 grams of cooked beef tendon providing approximately 146 calories and 35 grams of protein, predominantly from . This protein is rich in essential amino acids such as (comprising about one-third of collagen's structure) and , which support health but are not complete proteins due to low levels of and other essentials. Their tough texture necessitates tenderizing techniques like slow cooking, making them less ideal for quick meals but valuable for low-fat, high-protein diets. Culturally, tendon consumption holds significance in various traditions, often linked to beliefs in food-as-medicine principles. In and , tendons are prized for their purported benefits to joint and tendon health, aligning with the concept that consuming similar tissues strengthens corresponding body parts, as seen in offerings and restorative soups. Mexican , featuring tenderized beef including tendons, is a festive dish associated with celebrations, where the collagen-rich is thought to nourish and soothe in folk remedies for vitality. In broader folk medicine, tendon-based dishes are traditionally recommended for joint support, reflecting cross-cultural practices of using animal connective tissues to address musculoskeletal concerns. Modern processing of tendons focuses on extracting collagen peptides for supplements, often derived from bovine or porcine sources through enzymatic . A 2024 randomized controlled trial showed that daily doses of 10 grams of peptides alleviated symptoms of , improving pain and function without significant adverse effects. These supplements capitalize on the profile of tendons, providing bioavailable building blocks for maintenance. As of 2025, studies on peptides continue to explore their role in , with ongoing meta-analyses supporting efficacy in symptom relief.

Biomedical and Industrial Applications

In biomedical applications, tendons serve as valuable sources for allografts and xenografts in surgical repairs, particularly for reconstruction. Porcine tendon xenografts, such as decellularized digital extensor tendons, have been employed in () reconstruction, demonstrating positive safety and performance outcomes over five years in clinical studies involving 40 patients, with no graft failures reported. Similarly, porcine bone-patellar tendon-bone xenografts have shown long-term efficacy in human reconstruction trials, providing an alternative to human-sourced grafts by reducing donor site morbidity. Tissue engineering leverages decellularized tendon matrices as scaffolds to promote regeneration, preserving the extracellular matrix's biomechanical properties while minimizing . These scaffolds facilitate , , and , supporting tendon repair in models of rupture and degeneration. For instance, decellularized tendon-derived scaffolds have been integrated with mesenchymal cells to enhance healing at tendon-bone interfaces, as reviewed in studies on their application for osteotendinous junction regeneration. In research, the rat Achilles tendon injury model is widely used to investigate tendon and therapeutic interventions due to its anatomical similarity to tendons and . This model, involving partial or complete transection, allows quantitative assessment of healing through biomechanical and histological analyses across multiple injury severities. Additionally, 3D techniques utilizing hydrogels enable the fabrication of tendon scaffolds mimicking the aligned fibrillar structure to support tenocyte viability and matrix deposition. Industrially, collagen extracted from tendons contributes to leather tanning processes by providing raw material for stabilization and enhancement of hides, often derived from trimming wastes to improve product durability. As of 2025, recycled from tannery waste has been increasingly used as a filling agent to enhance low-quality , promoting . In pharmaceuticals, tendon-derived is incorporated into delivery systems for hormones like insulin-like factor-1 (IGF-1), which stimulates synthesis and improves tendon repair outcomes in preclinical models. Bioinspired materials drawing from tendon's tensile properties—such as high strength and elasticity—inform robotic actuators, where fiber-reinforced composites replicate muscle-tendon units for enhanced compliance and load-bearing in . Recent advances include CRISPR-based gene editing targeting the scleraxis (Scx) gene to boost tenogenic and regeneration. In 2024 studies, CRISPR-Cas13 editing of macrophages modulated inflammatory responses in tendon injuries, promoting scarless healing in animal models. Overexpression of Scx via CRISPR in stem cells has further enhanced tendon lineage commitment, offering potential for scalable regenerative therapies.

References

  1. [1]
    Tendon vs. ligament: MedlinePlus Medical Encyclopedia Image
    ### Definition and Basic Anatomy of Tendons vs. Ligaments
  2. [2]
    Tendon Functional Extracellular Matrix - PMC - NIH
    Tendons connect muscle to bone, carrying some of the highest forces experienced by any vertebrate tissue, as they facilitate movement and provide skeletal ...Missing: anatomy | Show results with:anatomy
  3. [3]
    Anatomy, Tendons - StatPearls - NCBI Bookshelf
    May 1, 2024 · The tendon is a "mechanical bridge," transmitting muscle forces to the bones and joints. This tough, fibrous structure also helps muscles complete joint ...Introduction · Structure and Function · Embryology · Blood Supply and Lymphatics
  4. [4]
    Tendon (Sinew): What It Is, Anatomy & Function - Cleveland Clinic
    Tendons (sinews) are fibrous tissues that connect your muscles to your bones all over your body. They allow your limbs to move and help prevent muscle injury.Overview · What Is A Tendon (sinew)? · Anatomy
  5. [5]
    Tendon material properties vary and are interdependent among ...
    Breaking tests for four of the tendons revealed significant variation in ultimate tensile stress, ranging from 66.83±14.34 to 112.37±9.39 MPa.
  6. [6]
    Tendon Vasculature in Health and Disease - PMC - NIH
    Tendons represent a bradytrophic tissue which is poorly vascularized and, compared to bone or skin, heal poorly. Usually, a vascularized connective scar ...
  7. [7]
    Protect Your Tendons | NIH News in Health
    You have about 4,000 tendons throughout your body. Tendons make it possible for you to bend your knee, rotate your shoulder, and grasp with your hand. ...
  8. [8]
    Tendon - Etymology, Origin & Meaning
    Tendon, from Greek tenon via Medieval Latin, means a dense, fibrous band at a muscle's end for attachment to bone, originating from PIE root *ten- "to ...
  9. [9]
    https://www.merriam-webster.com/dictionary/tendon
  10. [10]
    Ancient Egyptian Views About Health and the Body
    “The vessels, sinews, and muscles of the physical body were known as mtw, and the Egyptians had some conception of bodily fluids, especially blood, flowing ...<|control11|><|separator|>
  11. [11]
    The History of Nerves
    ... tendons, ligaments, arteries, veins, membranes, and flesh)." He offered a more precise physical description of them -- "white, soft, pliant, difficult to tear.
  12. [12]
    Galen on Anatomical Procedures - Google Books
    Oct 15, 2024 · On Dissection in General and on Muscles and Ligaments of Upper Limb in particular 1 Galens Reasons for writing I. 1 ; How to study the Skeletons ...
  13. [13]
    The Art of the Fabrica | Vesalius
    The over 200 large plates and smaller illustrations are not simply scientific: they present a deliberate, singular beauty and are treasures of Renaissance art ...Missing: tendon | Show results with:tendon
  14. [14]
    Rudolf Albert von Kölliker | Cellular Biology, Anatomy, Histology
    Oct 29, 2025 · Rudolf Albert von Kölliker was a Swiss embryologist and histologist, one of the first to interpret tissue structure in terms of cellular ...
  15. [15]
    Anatomy, Shoulder and Upper Limb, Biceps Muscle - NCBI - NIH
    Jan 30, 2024 · The tendon of the biceps long head is enclosed by a synovial sheath and moves back and forth in the bicipital groove during arm movement. This ...Introduction · Structure and Function · Embryology · Surgical Considerations
  16. [16]
    The Achilles Tendon: Imaging Diagnoses and Image-Guided ...
    May 4, 2022 · The Achilles tendon is approximately 15 cm in length and is formed by components of the gastrocnemii and soleus tendons. The tendon begins its ...Missing: average | Show results with:average
  17. [17]
    Patellar tendon | Radiology Reference Article | Radiopaedia.org
    Aug 14, 2025 · It measures approximately 5 cm in length (i.e. height of the patella) and 20-30 mm in width, being wider proximally and narrower distally, and ...Missing: diameter | Show results with:diameter
  18. [18]
    Anatomy, Back, Muscles - StatPearls - NCBI Bookshelf
    Three muscles that span the entire back comprise the erector spinae. · Action: It controls the forward flexion of the thorax, which can occur secondary to ...
  19. [19]
    Anatomy, Sesamoid Bones - StatPearls - NCBI Bookshelf
    Apr 4, 2023 · A sesamoid bone is a small bone commonly found embedded within a muscle or tendon near joint surfaces, existing as focal areas of ossification and functioning ...Introduction · Structure and Function · Embryology · Blood Supply and Lymphatics
  20. [20]
    Tendinous Inscriptions of the Rectus Abdominis - NIH
    Aug 4, 2018 · The rectus abdominis muscles are interrupted by tendinous inscriptions, which typically appear as fibrous bands crossing the muscle.
  21. [21]
    Anatomy, Rotator Cuff - StatPearls - NCBI Bookshelf
    The tendons of the rotator cuff muscles blend with the joint capsule and form a musculotendinous collar that surrounds the posterior, superior, and anterior ...Missing: gross | Show results with:gross
  22. [22]
    BOFAS > Hyperbook > Miscellaneous > Physiology of Tendons
    Structure. Tendons are composed of hierarchical structures of collagen fibres organised in fascicles, surrounded by endotenon, epitenon, and paratenon layers. * ...Missing: microscopic blood supply vincula innervation
  23. [23]
    Tendons and Ligaments | Musculoskeletal Key
    Apr 14, 2020 · ... tendon gliding). GROSS MORPHOLOGY, HISTOLOGY, MICROANATOMY, AND CELL BIOLOGY. The connection of the tendon between muscle and its point of ...
  24. [24]
    The Dynamics of Collagen Uncrimping and Lateral Contraction in ...
    Jul 19, 2013 · Crimp is ubiquitous in tendons of all types (Dale et al., 1972), and measured crimp wavelengths in unloaded tendon range from around 30 μm in ...
  25. [25]
    Structure and collagen crimp patterns of functionally distinct equine ...
    Apr 1, 2018 · SDFTs showed much finer crimp (21.1 ± 5.5 µm) than positional CDETs (135.4 ± 20.1 µm). Further, tendon crimp was finer in injured tendon, as ...
  26. [26]
    Tendon: Principles of Healing and Repair - PMC - PubMed Central
    The extrinsic system supplies blood through the paratenon or through the synovial sheath via vincula, which are connective tissue bands bridging tendon to bone ...
  27. [27]
    Tendons - Basic Science - Orthobullets
    Sep 14, 2025 · Tendons ; Composition. Perforating mineralized collagen fibers. 4 distinct zones (tendon, fibrocartilage, calcified fibrocartilage, and bone).
  28. [28]
    Mechanoreceptors Specialized for Proprioception - NCBI - NIH
    These mechanoreceptors, called Golgi tendon organs, are innervated by branches of group Ib afferents and are distributed among the collagen fibers that form ...
  29. [29]
    Tendon Receptor - an overview | ScienceDirect Topics
    Tendon receptors (referred to as Golgi tendon organs) are sensitive to tendon stretch and provide information about muscle force.
  30. [30]
    The “other” 15–40%: The Role of Non‐Collagenous Extracellular ...
    Aug 13, 2019 · 125 On an ultrastructural level, TSP2-deficient tendons showed a higher percentage of larger collagen fibrils.126 In addition, tendon fascicle ...
  31. [31]
    Mimicking the Hierarchical Organization of Natural Collagen
    On the contrary, tendon fibrils show a heterogeneous distribution of large diameters (≈50–250 nm), and the fibers are all arranged along the longitudinal axis ...
  32. [32]
    COLLAGEN STRUCTURE AND STABILITY - PMC - NIH
    Thus, before a (ProHypGly)n strand can fold into a triple helix, all the cis peptide bonds must isomerize to trans. N-Methylalanine (an acyclic, tertiary amide ...
  33. [33]
    REGULATORS OF COLLAGEN CROSSLINKING IN DEVELOPING ...
    The most abundant types of enzyme-mediated crosslinks within adult tendon are mature trivalent HP (HP or HylPyr, or pyridinoline, 428 Da) crosslinks – composed ...
  34. [34]
    Tendon Functional Extracellular Matrix - Screen - Wiley Online Library
    Jan 30, 2015 · SLRPs are the abundant proteoglycans in tendon, with decorin accounting for roughly 80% of the total proteoglycan content of the tissue.13 ...ABSTRACT · TENDON COMPOSITION · ACKNOWLEDGMENTSMissing: percentage | Show results with:percentage
  35. [35]
    Tendon's ultrastructure - PMC - NIH
    A tendon consists of 70% of water and 30% of dry mass, which is composed by 60–80% of type I collagen and 2% of elastin. Among collagens, the most abundant ...
  36. [36]
    Effect of Aging on Tendon Biology, Biomechanics and Implications ...
    Oct 14, 2023 · Overall, the above-mentioned factors increase AGE-mediated collagen crosslinking, which further disrupts ECM homeostasis during tendon aging.
  37. [37]
    Proteomic Analysis Reveals Age-related Changes in Tendon Matrix ...
    Several studies have reported alterations in matrix content as a function of aging, including increased type III collagen (12), changes in cross-link profile as ...
  38. [38]
    Mechanical Properties of Ligament and Tendon | Musculoskeletal Key
    May 22, 2017 · Ultimate tensile strengths for tendons and ligaments range from 50 to 150 MPa (for comparison, recall that the tensile strength of bone is about ...
  39. [39]
    Tendon biomechanics and mechanobiology - a mini-review of basic ...
    Ultrastructurally, tendons have a hierarchy of fibrillar arrangement which is sequentially composed of collagen molecules, fibrils, fibers, fascicles (or fiber ...
  40. [40]
    Quantification of Internal Stress-Strain Fields in Human Tendon
    Feb 27, 2017 · Tendon stiffness and Young's modulus values can be calculated from the slopes of the force-deformation and stress-strain plots. Figure 1. ...
  41. [41]
    Relationship between tendon stiffness and failure: a metaanalysis
    Elastic modulus and ultimate stress are highly correlated (R 2 = 0.785), suggesting that tendon failure is highly strain-dependent.
  42. [42]
    Achilles tendon work loops during human locomotion | PLOS One
    In other words, for every 1 J of energy stored elastically by tendon, Direct estimates would suggest that 0.51–0.98 J of this energy was returned. In contrast, ...
  43. [43]
    Neuromusculoskeletal Modeling: Estimation of Muscle Forces and ...
    Hill-Type Models. The general arrangement for a muscle-tendon model has a muscle fiber in series with an elastic or viscoelastic tendon (Figure 5A). The muscle ...
  44. [44]
    The capacity of the human iliotibial band to store elastic energy ...
    Sep 18, 2015 · Prior studies have estimated that energy recovered from the Achilles tendon during running reduces muscle work by as much as 35% (Alexander and ...<|separator|>
  45. [45]
    Non-linear properties of the Achilles tendon determine ankle ...
    Summary: During postural conditions, the stiffness of the ankle in humans is determined primarily by the stiffness of the Achilles tendon, not that of the.
  46. [46]
    More than energy cost: multiple benefits of the long Achilles tendon ...
    Jul 31, 2023 · That is, movement efficiency is improved, and therefore muscle (metabolic) 'fatigue' will be reduced, when tendons are able to return previously ...
  47. [47]
    Human tendon behaviour and adaptation, in vivo - PMC
    ... length–tension relationship. That force generated by the contractile machinery is transferred to bones via tendons to produce moments about joints is intuitive.
  48. [48]
    Molecular correlates of muscle spindle and Golgi tendon organ ...
    Proprioceptive feedback mainly derives from groups Ia and II muscle spindle (MS) afferents and group Ib Golgi tendon organ (GTO) afferents.
  49. [49]
    Regulating muscle spindle and Golgi tendon organ proprioceptor ...
    GTOs are located at the myotendinous junction and are innervated by a single group Ib afferent (Figure 1). Group Ib terminals are particularly sensitive to ...
  50. [50]
    Golgi Tendon Organ - an overview | ScienceDirect Topics
    Tendon organs are innervated by large myelinated afferent axons of group I size (Ib afferents) with one afferent per receptor in over 85% of cases. The Ib ...
  51. [51]
    Free Nerve Ending - an overview | ScienceDirect Topics
    Free nerve endings are found in muscle and tendon, where they may serve as nociceptors and thermoreceptors, as in the skin.
  52. [52]
    Neuropeptides in tendinopathy - PMC - PubMed Central - NIH
    Substance P has emerged as a potential source of tendon pain and tissue abnormality. Neural sprouting of Substance P-positive fibres accompanies the vascular ...
  53. [53]
    Neuronal regulation of tendon homoeostasis - PMC - PubMed Central
    In normal tendon repair, sensory nerve ingrowth and expression of SP and CGRP are correlated with increased nociception (Ackermann et al. 2003). Normally, the ...
  54. [54]
    Tendon Mechanobiology: Current Knowledge and Future Research ...
    Similar tissue engineered constructs also require precise mechanical loading to mimic native tendon cell organization, structure, and gene expression.Figure 1 · Tenocyte Biomarkers And... · The Hippo Pathway And...
  55. [55]
    Pathogenesis of tendinopathies: inflammation or degeneration? - PMC
    The metabolic rate of tendons is relatively limited and is lower than that of skeletal muscle; oxygen consumption is 7.5 times lower and the turnover time for ...<|control11|><|separator|>
  56. [56]
    Metabolic regulation of tendon inflammation and healing following ...
    The basal metabolic rate of tendon is relatively low, likely due to the high degree of quiescence observed in tendon cells during tissue homeostasis.<|control11|><|separator|>
  57. [57]
    Signals regulating tendon formation during chick embryonic ...
    Jan 28, 2004 · In summary, tendon and cartilage cells originate from common mesodermal compartments (sclerotome for somites and lateral plate for limbs) that ...
  58. [58]
    Fetal development of the human trapezius and sternocleidomastoid ...
    Dec 31, 2020 · A single mesenchymal condensation of the SCM and trapezius muscles. CS 16 (6 WD) human embryo (maximum length, 11 mm). Horizontal sections ...
  59. [59]
    Development and morphogenesis of human wrist joint during ...
    Mar 19, 2012 · extensor carpi ulnaris) tendon sliding on the ulnar collateral ligament can be clearly seen in week 10 (Fig. 2B). In week 12, the oblique head ...
  60. [60]
    Hox11 genes are required for regional patterning and integration of ...
    The tendon and muscle defects in Hox11 mutants are independent of skeletal patterning events as disruption of tendon and muscle patterning is observed in Hox11 ...<|control11|><|separator|>
  61. [61]
    Development and maintenance of tendons and ligaments - PMC
    Induction of Scx in tendon progenitors relies on Tgfβ signaling during embryonic development. Later, tendon cells differentiate and multiply in the presence of ...Introduction · Establishment Of Tendon... · Tendon Cell Fate In Repair<|control11|><|separator|>
  62. [62]
    Muscle–tendon structure and dimensions in adults and children - PMC
    It is concluded that the fascicle, muscle and tendon lengthen proportionally during maturation, thus the muscle–tendon stiffness and excursion range are likely ...
  63. [63]
    Effect of aging and exercise on the tendon
    Both enzymatic and nonenzymatic cross-links can be affected by age. In tendons, the enzymatic cross-link composition changes greatly with maturation, replacing ...
  64. [64]
    Procollagen trafficking, processing and fibrillogenesis
    Apr 1, 2005 · Here, we focus on the synthesis, trafficking, post-translational processing and assembly of collagen into fibrils, as well as some potentially important ...
  65. [65]
    Stepwise proteolytic activation of type I procollagen to collagen ... - NIH
    Dec 21, 2011 · Proteolytic cleavage of procollagen I to collagen I is essential for the formation of collagen fibrils in the extracellular matrix of vertebrate tissues.
  66. [66]
    Mini reviews The procollagen N-proteinases ADAMTS2, 3 and 14 in ...
    ADAMTS2, 3 and 14 cleave the amino-propeptide of fibrillar collagens. ADAMTS2 deficiency leads to the dermatosparactic type of Ehlers–Danlos syndrome.
  67. [67]
    Heterogeneity of proteome dynamics between connective tissue ...
    May 12, 2020 · As expected, the smallest k values related to collagenous proteins, with corresponding half-lives of 330 to 1086 days. By contrast, the protein ...
  68. [68]
    Fibrillar Collagen: A Review of the Mechanical Modeling of Strain ...
    Nov 16, 2021 · Collagenases are key enzymes in the remodeling processes of collagen [165]. TIMPs regulate the MMP activities. A deregulation of the MMPs ...2.1 Fibril Forming Collagen · 2.2. 1 Collagen Synthesis · 2.2. 2 Collagen Degradation
  69. [69]
    In Vitro and In Vivo Effects of IGF-1 Delivery Strategies on Tendon ...
    IGF-1 is a potent stimulus for improving tendon healing due to its inherent support of cell proliferation, DNA and matrix synthesis, particularly collagen I.3. Igf-1 And Its Receptor... · 4.1. Igf-1 Supplemented... · 4.2. Igf-1 In Combination...
  70. [70]
    Coordinated collagen and muscle protein synthesis in human ... - NIH
    We hypothesized that an acute bout of strenuous, non-damaging exercise would increase rates of protein synthesis of collagen in tendon and skeletal muscle.Missing: PI3K/ | Show results with:PI3K/
  71. [71]
    CURRENT CONCEPTS OF MUSCLE AND TENDON ADAPTATION ...
    The purpose of this clinical commentary is to review the muscular and tendinous adaptations associated with strength training, link training adaptations and ...
  72. [72]
    Tendon tissue microdamage and the limits of intrinsic repair
    Our findings indicate that the tendon core has very little capacity for self-repair of microdamage.
  73. [73]
    Efficacy of Vitamin C Supplementation on Collagen Synthesis and ...
    Oct 25, 2018 · Preclinical studies demonstrated that vitamin C has the potential to accelerate bone healing after a fracture, increase type I collagen synthesis, and reduce ...
  74. [74]
    Scurvy: Rediscovering a Forgotten Disease - MDPI
    May 26, 2023 · Vitamin C deficiency weakens collagen triple-helix structures and fragile capillaries, which can lead to complications such as diffuse mucosal ...
  75. [75]
    Impact of Collagen Peptide Supplementation in Combination with ...
    Jul 26, 2024 · As shown in the current meta-analysis, tendon CSA (mostly comprising patella tendons) was significantly increased following long-term RT ...
  76. [76]
    Impact of oestrogen deficiency and aging on tendon: concise review
    The aim of this paper is to elucidate the current findings in the correlation between oestrogen deficiency, aging and tendon pathology.Materials And Methods · Aging And Tendon... · Oestrogen Deficiency And...
  77. [77]
    Corticosteroid injections in tendon lesions - PMC - NIH
    Local corticosteroids are used to reduce inflammation in patients with chronic tendinopathies. · Studies on animal models have shown that intratendinous ...
  78. [78]
    COL1A1 gene: MedlinePlus Genetics
    Dec 1, 2019 · Ehlers-Danlos syndrome. Expand Section. Mutations in the COL1A1 gene have been found to cause several forms of Ehlers-Danlos syndrome, a group ...Missing: effects | Show results with:effects
  79. [79]
    An update on the grading of muscle injuries: a narrative review ... - NIH
    Grade III, Severe pain, and disability; severe swelling, ecchymosis, hematoma; palpable defect and loss of muscle function; muscle or tendon rupture ...Clinical Grading Systems · Ultrasound Grading Systems · Magnetic Resonance Grading...
  80. [80]
    Return to Play Post Achilles Tendon Rupture: A Systematic Review ...
    The greatest increases in incidence occur in the 40–60 and over 60 age groups[1,10,11].Missing: prevalence | Show results with:prevalence
  81. [81]
    Rotator Cuff Injuries in Tennis Players - PMC - NIH
    The prevalence of rotator cuff tears in overhead athletes may be underreported as many cuff tears are asymptomatic in athletes.
  82. [82]
    Tenosynovitis - StatPearls - NCBI Bookshelf - NIH
    Tenosynovitis is a broad term describing the inflammation of the fluid-filled synovium within the tendon sheath. It commonly manifests as pain, swelling, ...
  83. [83]
    Tendinosis - StatPearls - NCBI Bookshelf - NIH
    Mar 28, 2025 · Tendinopathy is a broad term that describes tendon pain and dysfunction without specifying the underlying pathology. This condition ...
  84. [84]
    Overview: Tendon overuse injuries (tendinopathy) - NCBI - NIH
    Mar 29, 2022 · Other risk factors include diabetes, joint diseases such as rheumatoid arthritis and osteoarthritis, autoimmune diseases that attack the tendon ...
  85. [85]
    Achilles Tendon Rupture - StatPearls - NCBI Bookshelf
    Aug 17, 2023 · The examiner should perform the Thompson test to assess for Achilles tendon continuity in the setting of suspected rupture. The patient is ...
  86. [86]
    Mechanisms of tendon injury and repair - PMC - NIH
    Rotator cuff disorders are the most common causes of shoulder disability and are very common in the aging population. Full-thickness rotator cuff tears are ...
  87. [87]
    Tendon healing: a concise review on cellular and molecular ...
    Aug 10, 2022 · The main cell population (90%) in tendon consists of tenocytes and tenoblasts. Tenocytes, representing a highly specialized type of fibroblast, ...
  88. [88]
    Review Biology and physiology of tendon healing - ScienceDirect.com
    Cell density and vascularity decrease as the tissue repairs. However, animal studies have shown that natural healing leads to tendon biomechanical properties ...
  89. [89]
    The Role of Vascular Endothelial Growth Factor in Tendon Healing
    Unlike in other highly vascularized tissues, such as skin or bone, a poor vascular network and cells with low metabolic rate result in poor intrinsic tendon ...Missing: avascularity | Show results with:avascularity
  90. [90]
    Biologics for tendon repair - PMC - PubMed Central
    ... tendon strength was approximately 20–60% that of an uninjured tendon. In addition, only few studies have examined tendon healing after 6 weeks, thus the ...
  91. [91]
    Complications after flexor tendon repair: a systematic review and ...
    Results: Unadjusted meta-analysis revealed rates of re-operation of 6%, rupture of 4%, and adhesions of 4%. Meta-regression analysis of 29 studies showed ...
  92. [92]
    Nonoperative or Surgical Treatment of Acute Achilles' Tendon Rupture
    Apr 13, 2022 · The number of tendon reruptures was higher in the nonoperative group (6.2%) than in the open-repair or minimally invasive surgery group (0.6% in ...
  93. [93]
    Which is more useful, the "full can test" or the "empty can ... - PubMed
    The purpose of this study was to determine the clinical usefulness of the full can and empty can tests for determining the presence of a torn supraspinatus ...
  94. [94]
    Clinical Examination of the Rotator Cuff - PMC - NIH
    Jan 1, 2014 · Jobe's Test (Empty Can Test)​​ This test is regarded as positive when there is weakness to resistance with arm in 90° of abduction as compared ...
  95. [95]
    Tendinopathy - Diagnosis and treatment - Mayo Clinic
    Mar 22, 2025 · Ultrasound. This type of imaging test uses sound waves to make images of structures within your body, such as muscles and tendons. Magnetic ...
  96. [96]
    Use of ultrasonography versus magnetic resonance imaging for ...
    Ultrasound results were more sensitive and accurate than MRI in the detection of ankle tendon tears in our study.Missing: clinical tests
  97. [97]
    Imaging of Tendons - PMC - NIH
    A normal tendon on MRI demonstrates low signal intensity and on sonography, an echogenic fibrillar pattern. MRI is considered the imaging gold standard, ...
  98. [98]
    3.0-T MRI of the Supraspinatus Tendon | AJR
    MRI of the shoulder has been found to be highly sensitive and specific for detection of full-thickness supraspinatus tendon tears at 1.5-T or lower field ...
  99. [99]
    Physical Therapy for Achilles Tendonitis: Expert Treatment
    Aug 8, 2025 · The RICE method means rest, ice, compression, and elevation; it is typically used in the initial phase to reduce swelling and discomfort. Pain ...
  100. [100]
    Alfredson Protocol for Achilles Tendonitis Explained - Verywell Health
    Apr 29, 2025 · The treatment involves doing three sets of 15 eccentric heel drop exercises per day, twice daily, seven days a week, for twelve weeks. You ...Missing: conservative NSAIDs
  101. [101]
    Eccentric Exercise for Achilles Tendinopathy: A Narrative Review ...
    Jun 5, 2019 · Alfredson's protocol consisted of a 12-week program where the subjects performed solely eccentric strengthening exercises three sets of 15 ...Missing: RICE NSAIDs
  102. [102]
    Achilles Tendon Injuries - MedCentral
    May 17, 2016 · ⁷Conventional treatment usually consists of RICE (rest, ice, compression, and elevation) and nonsteroidal anti-inflammatory medication (NSAIDS) ...Missing: protocol | Show results with:protocol
  103. [103]
    Achilles tendon debridement-overview - OrthOracle
    A debridement can be expected to work in 90% of patients with a return to limited weight-bearing possible in most after 2 weeks if using a post-operative boot.<|separator|>
  104. [104]
    Surgery for Achilles Injury | NYU Langone Health
    Our surgeons perform Achilles repair using a minimally invasive percutaneous technique, in which they make several tiny incisions in the skin along the back of ...
  105. [105]
    What does Achilles tendon repair surgery involve?
    Dec 23, 2024 · Tendon graft: The surgeon uses a tissue graft to reconstruct some of the tendon. · Tendon transfer: The surgeon moves a healthy foot tendon into ...
  106. [106]
    The Efficacy of Platelet-Rich Plasma on Tendon and Ligament Healing
    This systematic review and meta-analysis has found evidence that suggests PRP may provide both short-term and long-term pain relief for tendon and ligament ...
  107. [107]
    Do Plasma Injections Improve Chronic Achilles Tendinopathy? - AAFP
    Nov 15, 2010 · Results: At 24 weeks, the PRP group had improved their VISA-A score by 21.7 points, and the placebo group improved their score by 20.5 points, ...
  108. [108]
    Mesenchymal stem cells: An efficient cell therapy for tendon repair ...
    Jun 30, 2023 · MSCs promote tendon repair through four mechanisms: Decreasing inflammation and promoting neovascularization and cell proliferation and differentiation.Mesenchymal Stem Cells: An... · Mscs Decrease The... · Mscs Stimulate Proliferation...
  109. [109]
    Autologous stem cells safe for Achilles tendinopathy treatment
    May 19, 2024 · This phase IIa study demonstrated the safety of autologous MSC injection for non-insertional Achilles tendinopathy and provides proof-of-concept ...
  110. [110]
    Scaling of elastic strain energy in kangaroos and the benefits of ...
    Nov 2, 1995 · The potential for elastic energy storage in hoppers is shown to scale with strong positive allometry. This is a function of the structural ...Missing: percentage | Show results with:percentage
  111. [111]
    Microdamage in the equine superficial digital flexor tendon - PubMed
    The forelimb superficial digital flexor tendon (SDFT) is an energy-storing tendon that is highly susceptible to injury during activities such as galloping ...
  112. [112]
    Building a Bird: Musculoskeletal Modeling and Simulation of Wing ...
    Whereas most flight muscles are parallel-fibered with short tendons, the supracoracoideus muscle is pennate with a long tendon that likely stores a ...<|separator|>
  113. [113]
    New frontiers in imaging, anatomy, and mechanics of crocodylian ...
    Jun 20, 2022 · Crocodylian heads are relatively robust ... The jaw muscles of the crocodiles and some relating structures of the crocodilian skull.
  114. [114]
    Comparative mechanical and elastic properties of the doral and ...
    ... elastin in functionally distinct tendons across species. Tendons with an energy-storing function had slightly more elastin content than tendons with a ...
  115. [115]
    The elastic system of a pressure-bearing tendon of thebullfrog Rana ...
    The compression region exhibited pre-elastic and mature elastic fibers, which were shown to be associated with the surface of the convoluted collagen bundles.
  116. [116]
    Risk factors for superficial digital flexor tendinopathy in ... - NIH
    Dec 18, 2019 · The SDF tendinopathy prevalence in racehorses is 6% in 2-year-olds, 20% in 3-year-olds, 17% in 4-year-olds and 12% in 5-year-olds and older ...
  117. [117]
    The evolution of tendon — morphology and material properties
    We conclude that the evolutionary history of tendon gives us insight into the use of model systems for investigating tendon biology.
  118. [118]
    Development of somites and their derivatives in amphioxus, and ...
    May 14, 2015 · FGF acts directly on the somitic tendon progenitors through the Ets transcription factors Pea3 and Erm to regulate scleraxis expression.
  119. [119]
    Evidence for an elongated Achilles tendon in Australopithecus
    Mar 5, 2020 · In mammals, a long AT serves as a cursorial adaptation that increases the efficiency of rapid locomotion by stretching and releasing stored ...
  120. [120]
    Sex differences in tendon structure and function - PMC
    It is possible that sex-based differences in tendon morphology, composition and mechanical properties may contribute to the greater susceptibility that women ...
  121. [121]
    Who Was That Dinosaur? | AMNH
    Prints record skin, flesh and tendon as well as bone. But fossil dinosaurs are only bone, so prints often don't resemble what we have of the printmaker.
  122. [122]
    Truly Authentic Vietnamese Pho Recipe - i am a food blog
    Rating 4.8 (43) · 1 hrMar 12, 2025 · Tendon is chewy, a little crunchy, and so satisfying in a bowl of otherwise very soft things. It can be extremely hard to find unless you go to ...
  123. [123]
    Beef Tendons - Chefs Resources
    Tendon is also fairly common at Dim Sum restaurants, marinated with lots of garlic, cooked until soft, and parading around with the name Suan Bao Niu Jin.Missing: pho | Show results with:pho
  124. [124]
    Birria de Res Recipe (Beef Birria) - Mexican Please
    Rating 4.7 (63) · 6 hr 30 minMay 24, 2024 · Ingredients · 3 lbs. beef brisket or chuck roast · 4-5 Roma tomatoes · 1 onion · 6 garlic cloves · 3-4 Ancho dried chiles · 2-3 New Mexican dried ...
  125. [125]
    Extraction and functional characterization of halal gelatin from ...
    Oct 14, 2025 · The high bloom gels have a gel strength of 200–300 g, medium bloom gels have 100–200 g and low bloom gelatin gels have a gel strength of 50–100 ...<|control11|><|separator|>
  126. [126]
    Calories in Beef Tendon and Nutrition Facts - MyNetDiary
    A 100g serving of beef tendon has 146 calories, 0g carbs, 35g protein, 0.6g fat, 79mg cholesterol, 53mg sodium, 7.7mg iron, and 149mg potassium.
  127. [127]
    Collagen Supplementation for Joint Health: The Link between ...
    Mar 8, 2023 · Although most of the studies report improvements in pain and function, the daily dose is highly variable. Bernardo et al. [101] in a randomized ...3.1. Native Collagen · 4. Clinical Evidence · Table 2
  128. [128]
    Joint Health direct link to Liver Health
    In TCM, "the Joint/Tendon belongs to Liver Zang". Most of the people believe the pain and stiffness in the back, the neck and the joint are caused by incorrect ...<|separator|>
  129. [129]
    Results from a randomized, double-blind, placebo-controlled study
    In summary, a daily dietary supplement containing 10 g of collagen peptides (MW 1–3 kDa) demonstrated efficacy in alleviating osteoarticular pain and improving ...
  130. [130]
    Five‐year clinical study of a novel porcine xenograft for anterior ...
    Sep 23, 2025 · Porcine digital extensor tendon (p‐DET) xenograft was used for anterior cruciate ligament (ACL) reconstruction in 40 patients with follow‐up to ...
  131. [131]
    Xenograft bone-patellar tendon-bone ACL reconstruction - NIH
    Sep 6, 2023 · This report describes the long-term outcomes from the first human clinical trial using a porcine xenograft ACL reconstruction device.
  132. [132]
    Decellularized and Engineered Tendons as Biological Substitutes
    Among biological scaffolds, the use of decellularized tendon-derived matrix increasingly represents an interesting approach to treat tendon ruptures. We ...
  133. [133]
    Advances focusing on the application of decellularization methods ...
    Our review assesses the application of various decellularized scaffolds in tendon-bone healing and its potential mechanisms.
  134. [134]
    Quantitative Comparison of Three Rat Models of Achilles Tendon ...
    Mar 27, 2019 · Utilizing three distinct models of rat Achilles tendon injury, the objective of this study was to define and compare the effects and ...
  135. [135]
    Exploring the Frontier of 3D Bioprinting for Tendon Regeneration
    Aug 7, 2024 · This review elucidates how 3D bioprinting holds promise for tendon repair and regeneration, detailing the steps involved and the various approaches employed.
  136. [136]
    Extraction of collagen from raw trimming wastes of tannery
    Feb 1, 2016 · A simple and effective method to extract collagen from trimming waste is established using acetic and propionic acid.
  137. [137]
    Bioinspired actuators with intrinsic muscle-like mechanical properties
    Sep 24, 2021 · This study presents a bioinspired soft actuator, named HimiSK (highly imitating skeletal muscle), designed by spatially arranging a set of synergistically ...
  138. [138]
    [PDF] Crispr strategies for stem cell engineering: a new frontier in ...
    This review will abridge the past and present of CRISPR for the regeneration of bone, cartilage, skeletal muscle, tendon, and ligament, highlighting the current ...