Abstract
In humans, enhanced joint range of motion is observed after static stretch training and results either from an increased stretch tolerance or from a change in the biomechanical properties of the muscle-tendon unit. We investigated the effects of an intermittent stretch training on muscle biomechanical and structural variables. The left plantarflexors muscles of seven anesthetized New Zealand (NZ) White rabbits were passively and statically stretched three times a week for 4 wk, while the corresponding right muscles were used as nonstretched contralateral controls. Before and after the stretching protocol, passive torque produced by the left plantarflexor muscles as a function of the ankle angle was measured. The left and right plantarflexor muscles were harvested from dead rabbits and used to quantify possible changes in muscle structure. Significant mass and serial sarcomere number increases were observed in the stretched soleus but not in the plantaris or medial gastrocnemius. This difference in adaptation between the plantarflexors is thought to be the result of their different fiber type composition and pennation angles. Neither titin isoform nor collagen amount was modified in the stretched compared with the control soleus muscle. Passive torque developed during ankle dorsiflexion was not modified after the stretch training on average, but was decreased in five of the seven experimental rabbits. Thus, an intermittent stretching program similar to those used in humans can produce a change in the muscle structure of NZ White rabbits, which was associated in some rabbits with a change in the biomechanical properties of the muscle-tendon unit.
Highlights
In humans, the effects of a stretching program on muscle-tendon biomechanical properties are studied through the changes in passive-torque-angle curves measured before and after the stretching program
Different results are obtained when different stretching programs are used on the same muscle group
When changes in passive force following stretch training are observed, they are thought to result from changes in structure of connective tissues that are arranged in parallel with the muscle fibres [21] or from changes in muscle fascicle lengths resulting from an increase in serial sarcomere number [26]
Summary
The effects of a stretching program on muscle-tendon biomechanical properties are studied through the changes in passive-torque-angle curves measured before and after the stretching program. When studying stretch training in animals, typically continuous stretching to the target muscles is imposed for several days The effects of these continuous programs on muscle-tendon units are studied by measuring biomechanical parameters, such as the passive stiffness and the passive-forcelength curve, or by measuring muscle tissue parameters, such as the intramuscular connective tissue amount or organization, the muscle’s mass or length, or its serial sarcomere number. The purpose of this study was to impose an intermittent stretching program to rabbit ankle plantarflexor muscles and measure serial sarcomere numbers in these muscles together with the passive ankle dorsiflexor torque-angle curves before and after the stretch intervention. We wanted to quantify possible changes in muscle structure by measuring muscle mass, serial sarcomere number, collagen content, and titin isoforms in the stretched and the non-stretched control soleus, gastrocnemius and plantaris muscles
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