2. Single-Leg Sit-to-Stand (STS) Test
Procedure:
• Use a chair height that matches roughly the individuals knee height to standardize demand.
• The athlete places one foot firmly on the floor, lifts the non-test leg so it is off the ground (does not contribute), and places hands on hips (or across chest, depending on protocol).
• On command, they rise from sitting to standing, then sit back, for either a fixed number of repetitions or for time, depending on chosen protocol. One common variant is 5 repetitions; in research, the one-leg STS with 5 stands is used.
• Measure the time taken to complete the repetitions.
Why this test matters for runners:
• Assesses unilateral lower-limb strength (especially knee extensors, hip extensors and ankle muscles) under functional, weight-bearing conditions.
• Reveals side-to-side strength asymmetries, which are important in runners for power, stability, and injury prevention.
• It has excellent test reliability (ICC ~ 0.96 in healthy young adults) and good correlation with isokinetic muscle strength.
Normative (Reference) Values:
Unlike the calf-rise test, well-established decade-by-decade normative data for one-leg STS time across 20–60 years is scarce in the literature. The validated studies (e.g., Thongchoomsin et al.) largely involve young adults (mean age ~28).
• In Thongchoomsin’s study, the mean time for 5 one-legged sit-to-stands was approximately 11.8 ± 1.4 seconds in young adults.
• Given limited normative data across decades, clinicians may use this young adult benchmark as a reference in runners, then look for significant deviations or asymmetries (> 1 s change or side-gap) as clinically meaningful.
Clinical Integration & Interpretation As a physiotherapist working with runners, here’s how I integrate these tests:
• I conduct both tests at baseline (e.g., Initial assessment or return-to-run after injury) and periodically (e.g., every 8–12 weeks) to monitor progress.
• I compare performance to normative values, but more importantly, track individual changes and limb symmetry.
• If a runner demonstrates fewer than age/sex normative calf raises or a significantly slower one-leg STS time (or a large asymmetry), I consider targeted strength or endurance interventions.
• Improvement in these tests correlates with functional resilience: better calf endurance reduces risk of calf or Achilles injury, improved STS performance suggests stronger unilateral push-off and control, which can translate to more efficient and safer running.
Conclusion
Objective strength assessments like the single-leg calf raise at 60 bpm and the one-leg STS test are powerful tools in a physio’s toolkit. They provide quantifiable, functional data, are directly relevant to running demands, and help guide training, rehab, and return-to-run decisions. By benchmarking against normative values and closely monitoring change over time, I can help runners build stronger, more balanced, and injury-resilient lower limbs.
