New Type Mechanical Overload Protection Devices Design by Patent Design Around and Biomimetic Concepts

Lee, Dau

11 February 2011

Patent information can provide up-to-date technological data that accelerate the development of new products and the improvement of technology. They also can provide a most useful survey of known solution possibilities, which avoid duplication and the resources wasting. Therefore, this study focuses on the patent searching and analysis of the mechanical overload protection devices. Patent information are fed into computer databases and stored for design around activities. The connections between biology and technology be called as bionics or biomimetics can lead to very useful and novel technical solution. This study introduced special underwater creatures ¡§snapping shrimp¡¨ which have a large claw can generate the snapping action. This action inspires us to find a new technical solution that using the liquid cohesion to store and release the energy. In the end, using the patent information and the new solution to achieve the new design of mechanical overload protection devices, include ¡§Force-Type¡¨ and ¡§Torque-Type¡¨.

Patent Design Around

Snapping Shrimp

Biomimetics

Mechanical Overload Protection Device

Patent Analysis

Regulation of the Myostatin Protein in Overload-Induced Hypertrophied Rat Skeletal Muscle

Affleck, Paige Abriel

01 December 2013

Myostatin (GDF-8) is the chief chalone in skeletal muscle and negatively controls adult skeletal muscle growth. The role of myostatin during overload-induced hypertrophy of adult muscle is unclear. We tested the hypothesis that overloaded adult rodent skeletal muscle would result in reduced myostatin protein levels. Overload-induced hypertrophy was accomplished by unilateral tenotomy of the gastrocnemius tendon in male adult Sprague-Dawley rats followed by a two-week period of compensatory overload of the plantaris and soleus muscles. Western blot analysis was performed to evaluate changes in active, latent and precursor myostatin protein levels. Significant hypertrophy was noted in the plantaris (494 ± 29 vs. 405 ± 15 mg, p < 0.05) and soleus (289 ± 12 vs. 179 ± 37 mg, p < 0.05) muscles following overload. Overloaded soleus muscle decreased the concentration of active myostatin protein by 32.7 ± 9.4% (p < 0.01) while the myostatin precursor protein was unchanged. Overloaded plantaris muscle decreased the concentration of active myostatin protein by 28.5 ± 8.5% (p < 0.01) while myostatin precursor levels were reduced by 17.5 ± 5.9% (p < 0.05). Myostatin latent complex concentration decreased in the overloaded soleus and plantaris muscle by 15.0 ± 5.9% and 70.0 ± 2.3% (p < 0.05), respectively. These data support the hypothesis that the myostatin signaling pathway in overloaded muscles is generally downregulated and contributes to muscle hypertrophy. Plasma concentrations of total and active myostatin proteins were similar in overloaded and control animals and averaged 8865 ± 526 pg/ml and 569 ± 28 pg/ml, respectively. Tissue levels of BMP-1, an extracellular proteinase that converts myostatin to its active form, also decreased in overloaded soleus and plantaris muscles by 40.4 ± 12.9% and 32.9 ± 6.9% (p < 0.01), respectively. These data support the hypothesis that local, rather than systemic, regulation of myostatin contributes to the growth of individual muscles, and that an association exists between the extracellular matrix proteinase BMP-1 and the amount of active myostatin in overloaded muscles.

myostatin

GDF-8

TGF-beta superfamily

BMP-1/tolloid proteinases

BMP-1

mechanical overload

muscle growth

hypertrophy

Exercise Science