A leucine-rich diet and exercise affect the biomechanical characteristics of the digital flexor tendon in rats after nutritional recovery.
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2012
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Resumo
An increase in the capacity of athletic performance
depends on adequate nutrition, which ensures optimal
function of the musculoskeletal system, including
tendon stability. However, little is known about the status
of tendons and extracellular matrix modifications during
malnutrition and nutritional recovery when leucine is used
in response to exercise conditioning. The purpose of this
study was to evaluate the collagen content and biomechanical
aspects of the deep digital flexor tendon (DDFT) in
malnourished rats submitted to nutritional recovery (control
diet or leucine-rich diet) and aerobic physical activity. After
60 days of undernourishment (6% protein diet), the malnourished
rats were subsequently nutritionally recovered
with a control diet or leucine-rich diet and trained or not
(swimming, without overload) for 5 weeks. The biomechanical
analysis and quantification of hydroxyproline were
assessed in the DDFT in all experimental groups. The
leucine-rich diet increased hydroxyproline content in the
tension region, independently of the training. In the compression
region, hydroxyproline content was higher in the
malnourished and leucine-trained groups. Biomechanical
analysis showed a lower load in the malnourished and
all-trained groups. The lowest stress was observed with
control-trained animals. The nutritional-recovered groups
showed higher strain values corresponding to control group,
while the lowest values were observed in malnourished and
trained groups. The results suggest that a leucine-rich diet
stimulates collagen synthesis of the DDFT, especially when
in combination with physical exercise, and seems to
determine the increase of resistance and the biomechanical
characteristics of tendons.An increase in the capacity of athletic performance
depends on adequate nutrition, which ensures optimal
function of the musculoskeletal system, including
tendon stability. However, little is known about the status
of tendons and extracellular matrix modifications during
malnutrition and nutritional recovery when leucine is used
in response to exercise conditioning. The purpose of this
study was to evaluate the collagen content and biomechanical
aspects of the deep digital flexor tendon (DDFT) in
malnourished rats submitted to nutritional recovery (control
diet or leucine-rich diet) and aerobic physical activity. After
60 days of undernourishment (6% protein diet), the malnourished
rats were subsequently nutritionally recovered
with a control diet or leucine-rich diet and trained or not
(swimming, without overload) for 5 weeks. The biomechanical
analysis and quantification of hydroxyproline were
assessed in the DDFT in all experimental groups. The
leucine-rich diet increased hydroxyproline content in the
tension region, independently of the training. In the compression
region, hydroxyproline content was higher in the
malnourished and leucine-trained groups. Biomechanical
analysis showed a lower load in the malnourished and
all-trained groups. The lowest stress was observed with
control-trained animals. The nutritional-recovered groups
showed higher strain values corresponding to control group,
while the lowest values were observed in malnourished and
trained groups. The results suggest that a leucine-rich diet
stimulates collagen synthesis of the DDFT, especially when
in combination with physical exercise, and seems to
determine the increase of resistance and the biomechanical
characteristics of tendons.
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Aerobic exercise, Extracellular matrix, Nutrition
Citação
BARBOSA, A. W. C. et al. A leucine-rich diet and exercise affect the biomechanical characteristics of the digital flexor tendon in rats after nutritional recovery. Amino Acids, v. 42, p. 329-336, 2012. Disponível em: <http://link.springer.com/article/10.1007%2Fs00726-010-0810-1>. Acesso em: 19 fev. 2017