6至28月龄mdx小鼠快、慢骨骼肌的力和功率输出
Force and power output of fast and slow skeletal muscles from mdx mice 6-28 months old.
作者信息
Lynch G S, Hinkle R T, Chamberlain J S, Brooks S V, Faulkner J A
机构信息
Institute of Gerontology, University of Michigan, Ann Arbor, MI 48109-2007, USA.
出版信息
J Physiol. 2001 Sep 1;535(Pt 2):591-600. doi: 10.1111/j.1469-7793.2001.00591.x.
Abstract
- Differences in the effect of age on structure-function relationships of limb muscles of mdx (dystrophin null) and control mice have not been resolved. We tested the hypotheses that, compared with limb muscles from age-matched control mice, limb muscles of 6- to 17-month-old mdx mice are larger but weaker, with lower normalised force and power, whereas those from 24- to 28-month-old mdx mice are smaller and weaker. 2. The maximum isometric tetanic force (P(o)) and power output of limb muscles from 6-, 17-, 24- and 28-month-old mdx and control mice were measured in vitro at 25 degrees C and normalised with respect to cross-sectional area and muscle mass, respectively. 3. Body mass at 6 and 28 months was not significantly different in mdx and control mice, but that of control mice increased 16 % by 17 months and then declined 32 % by 28 months. The body masses of mdx mice declined linearly with age with a decrease of 25 % by 28 months. From 6 to 28 months of age, the range in the decline in the masses of EDL and soleus muscles of mdx and control mice was from 16 to 28 %. The muscle masses of mdx mice ranged from 9 % to 42 % greater than those of control mice at each of the four ages and, even at 28 months, the masses of EDL and soleus muscles of mdx mice were 17 % and 22 % greater than control values. 4. For mdx mice of all ages, muscle hypertrophy was highly effective in the maintenance of control values for absolute force for both EDL and soleus muscles and for absolute power of soleus muscles. Throughout their lifespan, muscles of mdx mice displayed significant weakness with values for specific P(o) and normalised power approximately 20 % lower than values for control mice at each age. For muscles of both strains, normalised force and power decreased approximately 28 % with age, and consequently weakness was more severe in muscles of old mdx than in those of old control mice.
摘要
- 年龄对mdx(肌营养不良蛋白缺失)小鼠和对照小鼠肢体肌肉结构-功能关系的影响差异尚未明确。我们检验了以下假设:与年龄匹配的对照小鼠的肢体肌肉相比,6至17月龄mdx小鼠的肢体肌肉更大但更弱,归一化力和功率更低,而24至28月龄mdx小鼠的肢体肌肉更小且更弱。2. 在25℃下体外测量6、17、24和28月龄mdx小鼠和对照小鼠肢体肌肉的最大等长强直力(P(o))和功率输出,并分别相对于横截面积和肌肉质量进行归一化。3. 6个月和28个月时mdx小鼠和对照小鼠的体重无显著差异,但对照小鼠的体重在17个月时增加了16%,然后在28个月时下降了32%。mdx小鼠的体重随年龄呈线性下降,到28个月时下降了25%。从6至28月龄,mdx小鼠和对照小鼠的趾长伸肌(EDL)和比目鱼肌质量下降范围为16%至28%。在四个年龄阶段的每个阶段,mdx小鼠的肌肉质量比对照小鼠大9%至42%,甚至在28个月时,mdx小鼠的EDL和比目鱼肌质量仍比对照值分别大17%和22%。4. 对于所有年龄的mdx小鼠,肌肉肥大在维持EDL和比目鱼肌的绝对力以及比目鱼肌的绝对功率的对照值方面非常有效。在其整个寿命期内,mdx小鼠的肌肉表现出明显的无力,每个年龄的特定P(o)值和归一化功率值比对照小鼠低约20%。对于两个品系的肌肉,归一化力和功率随年龄下降约28%,因此老年mdx小鼠肌肉的无力比老年对照小鼠的更严重。
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