Over the next several weeks, this newsletter series will serve as your runway to the Traverse City Tendon Summit.

Each installment highlights key ideas across the Summit’s three major content areas:

1. Foundational Science

2. Evaluation and Diagnostics

3. Management and Decision Making

The goal is simple. We want everyone arriving in April with a shared platform of understanding so that the conversations can move quickly past the basics and into the deeper, more meaningful discussions that drive real progress. None of the ideas introduced here should be taken as settled science. These nuances invite debate and discussion, and that exchange is central to the purpose of the Summit.

In our last installment, we examined the hierarchical architecture and mechanical behaviors that allow tendons to store, transmit, and release force. That structural foundation is essential, but it is only part of the story. Tendons are living tissues that adjust their properties over time. Every step taken, jump landed, or squat performed provides information that can influence how a tendon behaves.

Foundational Science: Part II

KEY TAKEAWAYS

• Collagen turnover is low, but tendons still adapt. In healthy tissue, changes in stiffness, modulus, and CSA arise through remodeling of dynamic compartments rather than replacement of the core collagen network.

• Tendons respond to strain, not load. Mechanical deformation is the biologically meaningful signal that drives cellular and structural adaptation. Exercise parameters are our interface with that biology, but they function as a proxy rather than a rule of law.

• The effective strain window is narrow. Adaptation is most consistently stimulated around 4.5%-6.5% strain. Lower strains produce little change, while higher strains increase mechanical demand and may elevate risk.

• Muscle–tendon imbalance determines strain. When muscle strength outpaces tendon stiffness, tendons experience higher strain under the same external load, which alters the internal mechanical environment.

• Personalized loading improves tendon behavior. When training is aligned with an athlete’s actual strain response, individualized prescriptions reduce imbalances and guide tendon adaptation more reliably than percentage-based loading.

Mechanobiology and How Load Shapes Tendon Adaptations

Load is not simply a stressor. It is a signal, and tendons interpret that signal with remarkable specificity. 

Understanding how tendons interpret these forces requires a look at the biology that governs this process.

This brings us to mechanobiology, the study of how physical forces influence biological systems at the molecular, cellular, and tissue levels [1-4]. In tendon research, we often talk more specifically about mechanotransduction. This phenomenon outlines how mechanical deformation is detected and converted into biochemical signals that alter gene expression to initiate broad changes in cellular activity and tissue organization [2-4].

These downstream effects matter because they determine whether tendon structure remains static or adjusts to meet demands. This creates a recursive system in which structure influences load distribution, load distribution shapes cellular signaling, and those signals remodel structure to support future demands. 

For practitioners, this regulatory loop provides a clear entry point to drive changes in durability, performance, and long‑term function. Applied load is the mechanism that guides tendon adaptation. 

Load as a Language

You can think of “load” as the language tendons speak. It is not a single stimulus but a collection of distinct inputs, each sensed and interpreted through different cellular pathways.

Type:

The mechanical input mirrors our syntax, the structural pattern that shapes how a message is interpreted. 

Tensile strain, compression, and shear load different regions of the tendon and activate distinct mechanosensors, shaping which pathways initiate the response.

Intensity:

Strain magnitude parallels the volume of our voice, the aspect that modulates how strongly a message is received. 

Small differences in deformation can shift the cellular environment toward anabolic, neutral, or catabolic signaling.

Repetition Parameters:

The temporal characteristics compare to our cadence and rhythm, the pacing cues that influence how a message unfolds over time.

Loading rate, frequency, and duration determine how the tendon integrates repeated inputs and how long key pathways remain active.

Once we understand this language, we can begin to shape it intentionally.

Tendon cells do not receive load as a single, uniform message. They act as listeners, detecting specific features of the mechanical signal through different mechanosensors and routing them into distinct regulatory pathways [1-3]. 

Deformation, tension, fluid flow, matrix stiffness, and cytoskeletal strain each deliver their own “phrasing,” generating unique intracellular signatures. These signatures reorganize the cytoskeleton, alter nuclear mechanics, and reshape chromatin accessibility [1], allowing the cell to interpret the message and craft an appropriate response. These downstream shifts help determine the tendon’s regulatory fate [2-4]. 

This is why the way we load athletes in the clinic or weightroom carries such weight. Each parameter drives different biological responses and sets the stage for how tendons adapt over time.

This naturally leads to a deeper question: if specific loading parameters activate separate regulatory pathways, which tissue components are actually being modified in response?

The Collagen Turnover Paradox

Advanced collagen‑dating methods have revealed that much of the collagen laid down during growth appears to persist throughout adulthood with very little measurable turnover [5]. This finding might suggest that tendons are largely static once maturity is reached. At first glance, this raises a clear tension: if the core collagen network is essentially permanent, how can tendons adapt to training as we’ve been suggesting?

The adaptability of tendons is a topic that has generated considerable debate in recent years. What specifically is changing, to what extent, and through which exact mechanisms are all questions that remain incompletely answered. Rather than attempting to resolve every detail, we can outline the evidence that gives rise to this apparent paradox and draw reasonable inferences from those observations.

Despite the relative stability of the collagen matrix, multiple systematic reviews of human loading interventions consistently show that tendons do respond to mechanical stimuli in meaningful ways [6-7]. These adaptations have been observed across dozens of studies using ultrasound, MRI, dynamometry, and stress–strain assessments.

Across these reviews, several patterns emerge:

• Tendon stiffness often increases after sustained loading [6-7].

• Young’s modulus tends to rise as well [6-7].

• Cross‑sectional area may increase modestly, sometimes in region‑specific ways [6-7].

• These changes depend more on strain magnitude than contraction type [6-7].

Taken together, these findings indicate that tendons are not static structures. They do change. But the nature of that change appears to be more nuanced than simple collagen replacement.

What Actually Adapts?

Several mechanisms have been proposed to explain how tendons adapt without replacing their core collagen network. These explanations differ in scope and mechanism, reflecting genuinely different hypotheses about where and how adaptation occurs.

One line of thought suggests that the adaptations observed in training studies do not require wholesale replacement of the original collagen network. Instead, they may reflect processes that operate within the existing matrix, such as reorganization of fibrils, alterations in crosslinking, shifts in water and proteoglycan content, or remodeling in metabolically active peripheral regions [8-9].

However, there are straightforward challenges to this view, including human studies showing changes in tendon mechanics without detectable alterations in collagen content, fibril morphology, or cross‑linking [18]. More broadly, many of the proposed mechanisms are inferred from cellular or compartment‑level findings rather than demonstrated directly in vivo.

Another proposal is the idea that a large, relatively stable collagen pool forms during growth while a smaller, more dynamic pool supports ongoing maintenance and localized remodeling [8]. 

Zhang and colleagues evaluated whether collagen turnover varies across macroscopically defined regions of the human patellar tendon using bomb‑pulse dating and found little evidence of non‑uniformity within the fascicular matrix [10].

This negative finding applies only to the larger regions they were able to sample. It does not rule out the presence of microscopic compartments such as the peritenon, epitenon, or interfascicular matrix that represent a very small proportion of total tissue mass and would be diluted beyond detection in homogenized biopsies. 

Work from Thorpe and colleagues has shown that these compartments exhibit greater cellularity, higher turnover markers, and more dynamic remodeling than the fascicular collagen in both equine and human tendons [9]. Because they represent a small fraction of total tissue mass, they are difficult to isolate in homogenized biopsies and largely invisible to bomb‑pulse methods that capture long‑term collagen integration.

What we have outlined here represents only a fraction of the contrasting hypotheses and methodological debates in the tendon literature. The result is an incomplete picture, even when only considering healthy tendons.

Pathological tissue introduces additional complexities that further limit our ability to map the downstream consequences of loading.

Tendons operate according to physical and biological principles. There are real determinants of how they function and multiscale phenomena that change when they are loaded. Yet with our current tools, many of those features remain difficult to resolve.

A Tissue That Is Both Durable and Responsive

Regardless of the exact tissue alterations, what emerges is a picture of a tissue that is both durable and responsive. Tendons are built for long‑term stability yet still capable of adjusting their mechanical behavior when the loading environment changes. The precise mechanisms behind these adjustments remain an active area of research, but the evidence suggests that tendons possess a subtle and context-dependent capacity for adaptation.

If we cannot yet pinpoint which tissue components are changing, the more pragmatic question becomes which characteristics of the loading environment actually drive those adjustments. Across the literature, the most consistent signal is that tendon adaptation depends on the magnitude and distribution of strain rather than on load in a general sense [6-7]. This is where the work of Falk Mersmann and colleagues becomes especially useful, because it clarifies which factors most consistently predict tendon adaptation [11].

How Mersmann’s Work Advanced Tendon Loading

Muscle-Tendon Imbalance as a Driver of Strain

Over the past decade, the work of Adamantios Arampatzis, Falk Mersmann, Sebastian Bohm and their collaborators has provided some of the clearest evidence for how tendons experience strain in vivo [11]. Although it is well established that the rate, duration, and intensity of loading influence the strain experienced by the tendon, these external parameters do not translate uniformly to the tissue level.

In practice, we often prescribe load based on an individual’s maximal strength, paired with a defined tempo and volume, assuming this will produce a predictable mechanical stimulus. Yet Mersmann’s work shows that individuals performing the same external task can experience markedly different tendon strains [11].

As we discussed in Part I of this series, structural features shaped by genetics and environment contribute to this variability. Mersmann’s work adds another layer by showing how muscle–tendon balance influences the strain experienced under the same external load [11].

Muscle and tendon do not adapt at the same rate across development or training, and in many individuals, increases in muscle strength outpace increases in tendon stiffness. This discrepancy exposes the tendon to higher strain during maximal efforts [11]. Higher strain is not inherently harmful, but their work suggests that it increases mechanical demand and, in some cases, may contribute to micromorphological disruption or heightened injury risk [11-12].

The Effective Strain Window

With this framework in place, Mersmann’s group demonstrated that tendon adaptation is consistently stimulated within a relatively narrow strain range. Across multiple in vivo studies, loading the tendon between 4.5–6.5% strain produced reliable improvements in stiffness and mechanical behavior [11]. Strain magnitudes below this range produced little measurable change, while substantially higher strains were associated with catabolic signaling or increased risk in certain populations [11-12].

This work reframed the conversation around tendon loading. External load is not the biologically relevant variable. Internal strain is. And because individuals reach a given strain magnitude at different external loads, effective training requires consideration of this relationship.

Personalized Strain‑Based Training in Applied Settings

This concept was tested in youth male and female athletes with healthy tendons during recent in‑season trials, offering a practical example of how a strain‑based model can be implemented in applied settings [13-14]. By tailoring training to each athlete’s measured tendon strain, the researchers evaluated whether this specificity would lead to distinct changes in tendon mechanical properties and PSF measures (peak spatial frequency, reflecting the local organization of collagen fascicles on ultrasound).

Diagnostic Assessment: Measuring Tendon Strain

The process began with a standardized assessment of patellar tendon strain during maximal voluntary contractions (MVCs), captured using B‑mode ultrasound [13-14].

Classifying Athletes Based on Measured Strain

Athletes were grouped according to their maximum tendon strain during MVCs:

• Low strain (≤ 4.5%) — muscle strength deficit relative to tendon stiffness

• Balanced (4.5–9%) — balanced muscle–tendon relationship

• High strain (≥ 9%) — tendon stiffness deficit relative to muscle strength (a threshold previously associated with elevated risk for tendon pain [11])

These categories allowed the researchers to tailor training toward the specific tissue most in need of adaptation.

Exercise Prescription Based on Diagnostic Category

Two distinct exercise types were used depending on the athlete’s classification.

Low‑strain athletes (≤ 4.5%)

Goal: Increase muscle strength

Protocol:

• 4 sets to failure

• Dynamic knee extensions

• Load permitting 25–30 repetitions per set

This high‑rep, metabolic stimulus was selected to promote muscle adaptation while providing insufficient mechanical load to meaningfully stimulate tendon adaptation [13-14].

Balanced athletes (4.5–9%)

Goal: Stimulate both muscle and tendon

Protocol:

• 5 × 4 repetitions

• 3‑second contraction duration

• Fixed‑end isometric knee extensions

• Load personalized to achieve ~5.5% tendon strain (capped at 90% MVC)

High‑strain athletes (≥ 9%)

Goal: Increase tendon stiffness without exceeding high strain

Protocol:

• Same fixed‑end isometric protocol

• Load personalized to achieve ~5.5% tendon strain

Practically, this resulted in a lower relative external load for high‑strain athletes, bringing their training strain down into the effective window [13-14].

Exercise Setup and Frequency

Exercises were performed in a mobile training device with a non‑elastic band fixed to the shank, standardized to a knee joint angle of 60 degrees. Training was completed three times per week for the 31–32 week season durations [13-14].

Results

Across both male and female adolescent athletes, the personalized loading approach stabilized tendon strain profiles over the season and reduced the prevalence of muscle–tendon imbalances [13-14]. Athletes who entered the season with high tendon strain showed meaningful reductions, driven primarily by increases in tendon stiffness [13-14]. In some cohorts, these mechanical improvements were accompanied by favorable changes in tendon micromorphology [14].

Collectively, these findings show that individualized, strain‑based loading can guide tendon behavior in consistent and targeted ways. This reduces uncertainty in prescription and brings training closer to the underlying biology of tendon adaptation.

Why These Concepts Matter Clinically

Although the work focused on mechanistic outcomes, the framework carries direct implications for practitioner priorities such as symptom management, performance readiness, and player availability.

Tailoring load to an athlete’s actual strain response provides far greater precision than traditional percentage‑based methods. For practitioners, this translates into a more dependable strategy for managing tendon load, correcting imbalances, and supporting long‑term tissue resilience.

At a broader level, this approach reinforces a central mechanobiological principle: tendons adapt to the strain they experience, not the external load prescribed. By aligning training with the internal mechanical stimulus that drives remodeling, personalized loading creates the biological conditions necessary for meaningful and durable tendon adaptation.

Looking Ahead

Even with a clearer understanding of tendon mechanobiology, we have only addressed part of the picture. Tendons differ in their internal architecture and functional roles, and those differences shape how they experience and respond to load. The Achilles tendon illustrates this clearly. It does not behave as a single uniform structure. It contains multiple subtendons that vary in size, twist, and sliding behavior across individuals, and these differences influence how forces are transmitted and how the tissue adapts [15-16].

In the final installment covering Foundational Science, we will explore this idea through the work of Dr. Stephanie Cone. Her findings show why energy‑storage tendons like the Achilles cannot be treated as interchangeable with positional tendons, and why tendon‑specific structure should guide how we load, manage, and rehabilitate these tissues [15-17].

For practitioners, this is where the pieces come together.

The Achilles subtendon work provides a concrete example of the principle we have been building toward: tendon structure shapes mechanical behavior, which in turn shapes the biological response by altering the internal strain environment. Effective intervention depends on recognizing those differences and aligning load with the tendon’s specific architecture and functional role.

- Research review written by: Jason Eure, PT, DPT, OCS, CSCS

*If you plan to attend the Summit, but haven't yet registered, we recommend doing so soon—we're limited to 40 attendees.

Reference List 

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