Stretching is traditionally viewed as a tool for improving flexibility. However, animal research has shown something surprising: many hours of daily stretching can also lead to muscle growth and strength gains. This raises an important question for clinicians and therapists—can long-duration stretching produce similar benefits in humans? To answer this, researchers tested whether one hour
For decades, stretching has been associated primarily with flexibility gains. However, emerging research shows that long-duration, high-intensity stretching can also induce structural and functional changes in muscle—potentially influencing strength, hypertrophy, and even contralateral performance. These findings are clinically relevant for therapists working in rehabilitation, mobility restoration, athletic preparation, and return-to-function programs. Stretching and ROM: Well-Established
1) Your north star: calm the nervous system, load the bone Two things drive recovery: a quieter, less “wound-up” nervous system and a progressively loaded, better-moving limb. Every intervention below maps to one (or both) of these. 2) Phase-based care (typical flow; adapt to surgeon protocols) Early protection (weeks 0–2) Goals: pain control, swelling reduction,
Fractures are among the most common injuries worldwide, and although most people heal well, a significant number continue to experience pain long after the bone has united. With global aging and rising osteoporosis, the number of fractures—and complications such as delayed healing or nonunion—is expected to grow. For many patients, the ongoing pain becomes more
Why this matters Muscle injuries are the most common sports trauma and a top reason for time lost from training—half of all injuries in soccer, with hamstrings leading, then adductors, rectus femoris, and calf. Despite better imaging and rehab, recurrence remains high. A key reason: the injury is often framed as a fiber tear, while
Introduction Tendinopathy, once regarded mainly as a degenerative or overload injury of tendon collagen, is now recognized as a much more complex neurobiological condition. Traditional models emphasized mechanical stress and microtrauma, describing tendon pain as an imbalance between damage and repair. However, recent research has revealed that nerve ingrowth (neoinnervation) and neuroinflammatory signaling within the
Tendinopathy accounts for up to half of all sporting injuries and around one-third of musculoskeletal pain consultations. Traditionally described as a degenerative or inflammatory disorder of the collagen matrix, new evidence challenges this view. Current research points to neurogenic inflammation and pathologic nerve ingrowth as key drivers of chronic tendon pain. The New Biology of