Back to knowledge hub
Stroke is one of the leading causes of long-term disability worldwide. One of the most common gait abnormalities following stroke is knee hyperextension (genu recurvatum), which affects approximately 65% of stroke survivors. This abnormal movement pattern results from impaired proprioception, muscle weakness, spasticity and poor neuromuscular control, reducing walking efficiency while increasing the risk of falls and degenerative knee injury.
A 2025 randomized controlled study investigated whether combining aquatic proprioceptive training with bilateral prowling exercises would improve gait and reduce knee hyperextension more effectively than performing the same exercises on land.
The purpose of the study was to compare:
The primary outcomes were:
Assessments were performed at baseline and after 2, 4 and 6 weeks.
Twenty-eight adults with chronic stroke completed the study.
Participants were randomly allocated into:
Both groups received identical conventional physiotherapy. The only difference was whether the proprioceptive training and bilateral prowling exercises were performed on land or in water.
The aquatic programme lasted 6 weeks and progressed over time.
Participants performed:
Progression included:
Exercises were performed in an aquatic environment under supervision.
The authors describe several mechanisms explaining why aquatic therapy may enhance recovery after stroke.
Water reduces effective body weight, allowing individuals with weakness and impaired balance to perform movements that may be difficult or unsafe on land.
Continuous pressure around the limbs enhances proprioceptive input and contributes to improved postural stability and circulation.
Viscosity provides multidirectional resistance throughout movement, promoting muscle strengthening and neuromuscular control.
Warm water promotes muscle relaxation, reduces spasticity and pain, and creates an environment that facilitates motor relearning.
Both rehabilitation programmes significantly improved walking.
However, the aquatic group achieved greater improvements.
Land-based rehabilitation
Aquatic rehabilitation
Lower scores indicate better gait quality, demonstrating a larger improvement in the aquatic group.
Knee extension angles also improved in both groups.
Between-group analysis demonstrated significantly greater improvement following aquatic rehabilitation (p = 0.0001).
Bilateral prowling requires walking while maintaining approximately 15–20° of knee flexion throughout stance.
According to the authors, this technique:
When combined with aquatic therapy, these effects may be amplified by the enhanced sensory feedback provided by water.
The authors suggest several reasons why aquatic therapy produced better outcomes than land-based therapy.
Hydrostatic pressure continuously stimulates cutaneous and deep sensory receptors, improving joint position awareness.
Reduced joint loading allows patients to safely perform more repetitions without excessive fatigue.
Water resistance promotes coordinated activation of the quadriceps and hamstrings, improving dynamic knee stability.
The supportive environment encourages patients to practise larger, more confident movements, which may enhance motor learning and neuroplasticity.
The combination of buoyancy, resistance and continuous sensory feedback may facilitate reorganization of central nervous system motor patterns.
Aquatic therapy appears particularly valuable for post-stroke patients presenting with:
The study suggests that combining aquatic proprioceptive training with bilateral prowling may accelerate improvements in gait quality compared with identical exercises performed on land.
Several limitations should be considered:
Although statistically significant differences were found, larger multicentre randomized trials are needed before definitive clinical recommendations can be made.
This randomized controlled study found that aquatic proprioceptive training combined with bilateral prowling exercises produced greater improvements in gait quality and significantly reduced knee hyperextension compared with the same rehabilitation programme performed on land. The supportive properties of water—including buoyancy, hydrostatic pressure, viscosity and thermal effects—appear to enhance proprioceptive retraining, improve dynamic knee stability and facilitate safer, more effective gait rehabilitation after stroke.