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A glimpse - Tendon compression explained ππ
Justas Muzikevicius
June 14, 2024
Sports Med U | Educating Minds, Elevating Potential
Is compressive load a factor in the development of tendinopathy?
Cook, J.L. and Purdam, C., 2012. Is compressive load a factor in the development of tendinopathy?. British journal of sports medicine, 46(3), pp.163-168.Β§
In todayβs letter
Overview of how compression may affect the development of tendinopathy
Rapid Results = Excessive load without adequate rest changes the extra cellular matrix properties near the bony attachments of the tendon which make them more susceptible to compression based forces at end ranges
3 Reads to check out to further you knowledge about compression in tendinopathy
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Bite-size study - A glimpse into our Infographic
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A little note, the wording in this study was a little technical and complex, to say the least π I did my best to simplify where I think necessary, but I may have missed a few sentences here or there
Deeper look
Aim of study
This paper investigated how compressive loads may contribute to the onset and persistence of tendinopathy, reviewing anatomical, epidemiological, and clinical evidence supporting this idea
Did you know?
Excessive training volume or overuse of tendon elasticity are key factors in tendon overload, leading to tendinopathy.
Tendons primarily transmit tensile loads due to their fibrous structure, so traditionally, tendon overload was considered purely tensile.
Recent studies show evidence of compressive loads at or near regions where tendinopathy occurs.
Almekinders et al. were the first to propose that compression or varying tensile loads could overload tendons, suggesting that the Achilles tendon insertion experiences different types of strains with potential compressive loads at the heel attachment
What is the evidence that compression affects tendons?
Collagen-based connective tissues adapt to various loads by modifying their structure.
Compression induces changes in tendon matrix composition, as demonstrated by Milz et al.
Using 3-D reconstruction of the Achilles tendon, fibrocartilage was observed near the Achilles insertion, indicating the influence of compressive forces.
Tenocytes respond to cyclic compression by adopting a chondrocytic phenotype (specialised cells responsible for cartilage formation and maintenance) and producing large proteoglycans like aggrecan (maintains the structure and function of cartilage tissue, providing resilience and resistance to compression)
Increased deposition of aggrecan and type II collagen occurs in compressed tendon areas, especially near bony prominences.
Biomechanical modeling and cell culture studies suggest that hydrostatic pressure stimulates these adaptive responses.
What is the relationship between tissue adaptation, compression & tendinopathy?
Normal tendon have Fibrous tissue with highly structured type I collagen-based extracellular matrix, few cells, and nerve endings
Altered tendons (tendinoapthy) have more cellular tissue with substantial matrix changes including increased large aggregating proteoglycans, type III collagen, disorganisation of fibres, and neurovascular ingrowth (leading to increased sensitivity/discomfort/pain)
Tissue/cell responses to load suggests compressive forces lead to fibrocartilage formation in tendons.
Fibrocartilage = Has strong and resilient properties, making it suitable for locations in the body subjected to high levels of mechanical stress
This suggest that compressive loads induce tendon pathology.
Study by Soslowsky et al.: Different loads on rat supraspinatus tendon β compressive, tensile, and combination.
They found that the only the combination of compressive and tensile loads were particularly damaging to tendons, leading to increased cross-sectional are and decreased resilience
How does this relate to tendinopathy?
Wren et al. used a model to suggest that compression zones with low-fluid permeability, due to aggrecan's water binding properties, protect cells and collagen.
Conversely, tensile regions with higher fluid permeability are less suitable for high cyclic compression loads.
Transition zone between compressive (adjacent to bone) and tensile (removed from bone) zones of tendon show features of both
Excessive loading may partially deplete bound water in tensile and transitional zones, as suggested by Grigg et al.
Loss of water may expose tenocytes to greater cyclic compressive load, encouraging creation of large water binding proteoglycans, a process seen in tendinopathy.
Reduced permeability in this region protects against further insult but further loading may perpetuate response, hindering equilibrium attainment.
How does this concept help clinically?
Common aggravating activities for insertional tendinopathy align with this concept.
For instance, dorsiflexion load like walking barefoot or on sand aggravates Achilles tendon insertion issues.
Patients with Achilles insertional tendinopathy may experience pain during ankle dorsiflexion load (e.g., push-off) but not when hopping on toes.
Load on gluteal tendon during hip adduction, as seen in walking with poor lumbopelvic stability, induces compressive load and provokes pain.
Although Soslowsky reported minimal impact from solely compressive loads, sustained compressed positions often cause discomfort
For example, sleep disruption from lying on the affected side is common in gluteal tendinopathy, as is sitting for hamstring tendinopathy.
Stretching may provoke pain in insertional tendinopathies with muscle tension, such as stretching the Achilles
Compression at bony prominence proximal to insertion helps explain gender differences of pelvic tendinopathies.
Women are more likely to get gluteal tendinopathy, men are over-represented in adductor tendinopathy.
Application of enthesis organ and compression model suggests increased neck of femur angles may increase tendon compression against greater tuberosity more in women than in men; whilst men are more prone to adductor tendinopathy due to lesser abduction/extension before compression of tendon complex against pubic ramus
What about achilles the mid-tendon?
Mid-substance of Achilles tendon primarily endures high tensile and elastic loads.
Achilles tendinopathy common among badminton players, sprinters, and distance runners
Sedentary people are also susceptible to mid-Achilles tendinopathy despite lack of tensile overload.
Theres a potential for compressive loads even in mid-tendon.
Internal tendon shear force may result from gastrocnemius and soleus fibers' contribution to Achilles tendon.
Plantaris tendon may apply compressive force in some athletes, contributing to Achilles tendinopathy.
Invaginated plantaris tendon, stiffer than Achilles, creates shearing or compressive load, especially in dorsiflexion/ eversion.
Raised heel height in shoe may alleviate mid-Achilles pain for those with invaginated plantaris tendon, but not necessarily for those with solely mid-Achilles tendinopathy.
Role of posterior retinaculum may also contribute to purely compressive load, similar to retinacular metaplasia in de Quervainβs tendinopathy and trigger finger.
Achilles tendon bowstrings over retinaculum during plantarflexion, potentially contributing to tendinopathy even in inactive individuals or those with minimal elastic and tensile loads
Top 3 resources
To further your knowledge about compression and tendons
Tendinopathy & running
Exercises for progressing achilles & patellar tendinopathy
https://ars.els-cdn.com/content/image/1-s2.0-S1886658117300580-mmc1.pdf
FANTASTIC video explaining tendon compression
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