Artykuły w czasopismach: „Mechanical property”

1

Schelleng, Robert D. "Mechanical Property Control of Mechanically Alloyed Aluminum". JOM 41, nr 1 (styczeń 1989): 32–35. http://dx.doi.org/10.1007/bf03220800.

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Nakazono, Kazuko, i Toshikazu Takata. "Mechanical Chirality of Rotaxanes: Synthesis and Function". Symmetry 12, nr 1 (10.01.2020): 144. http://dx.doi.org/10.3390/sym12010144.

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Mechanically chiral molecules have attracted considerable attention due to their property and function based on its unique interlocked structure. This review covers the recent advances in the synthesis and function of interlocked rotaxanes with mechanical chirality along with their dynamic and complex stereochemistry. The application of mechanically chiral rotaxanes to control the polymer helical structure is also introduced, where amplification of mechanical chirality appears to cause the macroscopic polymer property change, suggesting the potential applicability of mechanical chirality in polymer systems.

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Liu, Peng, Zhi Wu Yu, Ling Kun Chen i Zhu Ding. "Mechanical Property of Phosphoaluminate Cement". Advanced Materials Research 150-151 (październik 2010): 1754–57. http://dx.doi.org/10.4028/www.scientific.net/amr.150-151.1754.

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The influence of curing time on the mechanical property of the phosphoaluminate cement (PAC) was investigated, and the mechanism was discussed as well. The phase composition and morphology of hydration products, electrical properties, porosity and pore size distribution of PAC cured different age were analyzed with XRD, EIS and MIP. The results showed PAC has the property of early-high strength, and the compressive strength of PAC cured for 1 day was about 70% of 28 days’. The main hydration products of PAC are micro-crystal phase and gel of phosphate and phosphoaluminate which formed compacter microstructure. In addition, there are no calcium hydroxide (CH) and ettringite (AFt) produced during the process of hydration. The compressive strength of PAC increased with age, which was due to more products continuously produced. The ac resistance analysis manifested as the change of the nyquist pattern and resistance value.

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WAKI, Hiroyuki. "Testing Method for Mechanical Property :". Journal of The Surface Finishing Society of Japan 64, nr 5 (2013): 280–84. http://dx.doi.org/10.4139/sfj.64.280.

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Steen, M., i C. Filiou. "Mechanical Property Scatter in CFCCs". Journal of Engineering for Gas Turbines and Power 122, nr 1 (20.10.1999): 69–72. http://dx.doi.org/10.1115/1.483177.

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The tensile response of continuous fibre reinforced ceramic matrix composites (CFCCs) is not expected to show the large variation in strength properties commonly observed for monolithic ceramics. Results of recent investigations on a number of two-dimensional reinforced CFCCs have nevertheless revealed a considerable scatter in the initial elastic modulus, in the first matrix cracking stress and in the failure stress. One school of thought considers that the observed variability is caused by experimental factors. Elaborate testing programmes have been set up to clarify the origins of this scatter by investigation of the effects of control mode, loading rate, specimen shape, etc. Another school explains the scatter by the presence of (axial) residual stresses in the fibres and in the matrix. Although plausible, this hypothesis is difficult to verify because experimental determination of the residual stress state in CFCCs is not straightforward. In addition, with the available methods it is impractical to determine the residual stresses in every test specimen. This approach is indeed required for establishing the relationship between the magnitude of the residual stresses and the experimentally observed scatter. At IAM a method has been developed and validated which allows to quantify the axial residual stress state in individual CFCC specimens by subjecting them to intermittent unloading-reloading cycles. The method as well as the derived relationship between residual stress state and scatter in mechanical response will be presented. [S0742-4795(00)01101-7]

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6

Yang, Wei, Liang Lifu i Liang Zhongwei. "On mechanical property of constraint". Applied Mathematics and Mechanics 16, nr 11 (listopad 1995): 1095–103. http://dx.doi.org/10.1007/bf02484376.

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Tao, Jun Lin, Wei Fang Xu, Gang Cheng, Xi Cheng Huang, Fang Ju Zhang i Xiao Xia Pan. "Dynamic Mechanical Property of a Steel". Advanced Materials Research 197-198 (luty 2011): 1681–85. http://dx.doi.org/10.4028/www.scientific.net/amr.197-198.1681.

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In order to realize the dynamic mechanical property of a steel, the quasic-static and dynamic compressive and tensile mechanical tests of a steel are carried out. Based on the stress-strain curves of the steel, the constitutive relation is presented and it can be used to describe compressive and tensile mechanical property correspondently. The stress-strain curves at different strain rate and the obtained dynamic constitutive relationship show that the flow stress of the steel is increased with strain rate increased. The dynamic tension experimental results show that failure strain and stress of the steel are increased small with strain rate increased, and the fracture of tension sample is ductile fracture.

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ONITA, Takafumi, Tsuyoshi NISHIWAKI, Zen-ichiro MAEKAWA i Hiroyuki HAMADA. "Mechanical Property of Matrix Hybrid Laminates." Journal of the Society of Materials Science, Japan 50, nr 10 (2001): 1146–51. http://dx.doi.org/10.2472/jsms.50.1146.

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Nakagawa, Yuji. "MECHANICAL PROPERTY OF THE HUMAN URETER". Japanese Journal of Urology 80, nr 10 (1989): 1481–88. http://dx.doi.org/10.5980/jpnjurol1989.80.1481.

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NAGASHIMA, Nobuo. "Multi-scale Mechanical Property Strength Analysis". Transactions of Japan Society of Spring Engineers 2021, nr 66 (31.03.2021): 13–21. http://dx.doi.org/10.5346/trbane.2021.13.

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Hashimoto, Shunichi. "Mechanical Property of Interstitial-Free Steel." Materia Japan 33, nr 1 (1994): 41–43. http://dx.doi.org/10.2320/materia.33.41.

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12

Petersen, DR, DL McLellan i MM McLellan. "Establishing Mechanical Property Allowables for Metals". Journal of Testing and Evaluation 26, nr 3 (1998): 293. http://dx.doi.org/10.1520/jte12004j.

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13

Smith, J. F., i S. Zheng. "High temperature nanoscale mechanical property measurements". Surface Engineering 16, nr 2 (kwiecień 2000): 143–46. http://dx.doi.org/10.1179/026708400101517044.

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14

Tan, Yunliang, Dongmei Huang i Ze Zhang. "Rock Mechanical Property Influenced by Inhomogeneity". Advances in Materials Science and Engineering 2012 (2012): 1–9. http://dx.doi.org/10.1155/2012/418729.

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In order to identify the microstructure inhomogeneity influence on rock mechanical property, SEM scanning test and fractal dimension estimation were adopted. The investigations showed that the self-similarity of rock microstructure markedly changes with the scanned microscale. Different rocks behave in different fractal dimension variation patterns with the scanned magnification, so it is conditional to adopt fractal dimension to describe rock material. Grey diabase and black diabase have high suitability; red sandstone has low suitability. The suitability of fractal-dimension-describing method for rocks depends on both investigating scale and rock type. The homogeneities of grey diabase, black diabase, grey sandstone, and red sandstone are 7.8, 5.7, 4.4, and 3.4, separately; their average fractal dimensions of microstructure are 2.06, 2.03, 1.72, and 1.40 correspondingly, so the homogeneity is well consistent with fractal dimension. For rock material, the stronger brittleness is, the less profile fractal dimension is. In a sense, brittleness is an image of rock inhomogeneity in macroscale, while profile fractal dimension is an image of rock inhomogeneity in microscale. To combine the test of brittleness with the estimation of fractal dimension with condition will be an effective approach for understanding rock failure mechanism, patterns, and behaviours.

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15

Mishra, Manish Kumar, Upadrasta Ramamurty i Gautam R. Desiraju. "Mechanical property design of molecular solids". Current Opinion in Solid State and Materials Science 20, nr 6 (grudzień 2016): 361–70. http://dx.doi.org/10.1016/j.cossms.2016.05.011.

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16

Ma, Hang-Shing, Anthony P. Roberts, Jean-H. Prévost, Rémi Jullien i George W. Scherer. "Mechanical structure–property relationship of aerogels". Journal of Non-Crystalline Solids 277, nr 2-3 (listopad 2000): 127–41. http://dx.doi.org/10.1016/s0022-3093(00)00288-x.

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17

Huang, Zhong Hua, Shao Jun Liu, Ying Guang Xu i Wang Hu. "Seafloor Polymetallic Sulfides Mechanical Property Test". Advanced Materials Research 1015 (sierpień 2014): 316–19. http://dx.doi.org/10.4028/www.scientific.net/amr.1015.316.

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Seafloor polymetallic sulfide specimens were developed according to engineering rock test method standard (GB/T 50266-2013). Seafloor polymetallic sulfide wet density and dry density were tested. Uniaxial compressive strength and triaxial compression strength of seafloor polymetallic sulfide were tested using rock mechanics test system MTS 815. Elasticity modulus and Poisson's ratio of seafloor polymetallic sulfide were calculated based on specimens stress-strain curves. Cohesion and internal friction angle were calculated based on specimens triaxial test Mohr stress circle. Test results show that seafloor polymetallic sulfide dry density average value is 2.6 g/cm3, wet density average value is 2.94 g/cm3. Uniaxial compressive strength and triaxial compression strength of seafloor polymetallic sulfide are unstable. Average value of the uniaxial compressive strength is 10.243MPa. Average value of triaxial compression strength test peak load is 47.166KN. Cohesion is 2.447MPa and internal friction angle is 38.04o.

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18

Fu, Chengjie, David Porter i Zhengzhong Shao. "Moisture Effects onAntheraea pernyiSilk’s Mechanical Property". Macromolecules 42, nr 20 (27.10.2009): 7877–80. http://dx.doi.org/10.1021/ma901321k.

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19

TAKEDA, Yoshihiro, Michihito AOKI, Hajime FUKUNAGA, Takuji KOIKE, Sayuri MURAKAMI i Kyoji HOMMA. "1020 Mechanical Property of Mussel Byssus". Proceedings of the JSME annual meeting 2007.5 (2007): 241–42. http://dx.doi.org/10.1299/jsmemecjo.2007.5.0_241.

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20

Stranne, Steven K., Franklin H. Cocks i Roland Gettliffe. "Mechanical property studies of human gallstones". Journal of Biomedical Materials Research 24, nr 8 (sierpień 1990): 1049–57. http://dx.doi.org/10.1002/jbm.820240807.

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21

Douglas, Nicholas. "Mechanical Timepieces & Intellectual Property Protection". Pace Intellectual Property, Sports & Entertainment Law Forum 8, nr 1 (17.01.2018): 29. http://dx.doi.org/10.58948/2329-9894.1069.

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Kędzierski, Przemysław. "Mechanical Spark Electrostatic Property Testing Method". Management Systems in Production Engineering 31, nr 2 (3.05.2023): 216–22. http://dx.doi.org/10.2478/mspe-2023-0023.

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Abstract The article describes an attempt to assess the electrostatic properties of mechanical friction-induced sparking. Such sparks are the cause of numerous accidents in hard coal mines. The article summarizes accidents in hard coal mining in Poland in recent years. In most cases, the initials were mechanical sparks. Mechanical sparks contain energy, a part of which is related to their excess electrostatic charge, whereas the other part is of a different origin (kinetic or thermal energy, for example). The article tries to estimate how much of this energy is energy impact generated by electrostatics impact. It is hard to measure the dynamic electrostatic parameters like electric charge. Authors select four measuring methods. This test methods are prepared based on authors knowledge of electrostatic parameters and European standards dedicated to measure the electrostatics parameters. These circuits were prepared for four different spark parameters. Measurement methods of electrostatic field of sparks stream are not able to measure field potential of sparks. The measuring instruments do not have such a fast response time, adequate to the speed of the sparks. Spark generation and parameter measurement experiments were performed. The only method to determine the amount of electrostatic charge on sparks is to measure the entire charge by collecting sparks at the measuring electrode. The measuring system requires that the entire stream of sparks falls on the electrode. Tested transferred electrostatic charge of stream of sparks is about 10 nC. It means that this charge can be an effective ignition source for some explosive atmospheres. Electrostatic charge with Certain methods were rejected as inadequate following result analysis. A claim for one of the methods was submitted to the Patent Office of the Republic of Poland.

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23

Chenbo, Ma. "Experimental study on tribological property of mechanical seals with changeable pore diameter". Functional Materials 23, nr 4 (20.12.2016): 587–91. http://dx.doi.org/10.15407/fm23.04.408.

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Zhang, Qing-Hua, Wei-Qiang Luo, Lian-Xun Gao, Da-Jun Chen i Meng-Xian Ding. "Thermal mechanical and dynamic mechanical property of biphenyl polyimide fibers". Journal of Applied Polymer Science 92, nr 3 (2004): 1653–57. http://dx.doi.org/10.1002/app.20110.

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Bookoff, Leslie I., i Dinesh N. Melwani. "Property Values". Mechanical Engineering 133, nr 03 (1.03.2011): 32–34. http://dx.doi.org/10.1115/1.2011-mar-2.

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This article focuses on the importance of intellectual property (IP) in startup companies to attract investment. Various examples of startup companies dealing with medical devices were also discussed. Much of a medical device startup’s assets, however, lie in ideas or concepts it hopes to develop into a commercial product. Patent protection often is considered a critical component of corporate transactions involving medical technologies because it can protect the significant upfront investments required for R'D and regulatory activities. Investors evaluating the IP of a target medical device company are attracted to a demonstrated awareness of IP and to a clean house as it relates to administrative issues potentially affecting the company’s intellectual property. A target company also may make investment more attractive by minimizing or eliminating contractual restrictions on the transfer of its IP. A startup company seeking its portion of investment dollars must pay attention to its IP: it must ensure that its technology is freely marketable without infringing third-party rights and that its IP portfolio is free of encumbrances and has the necessary protection.

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26

KONDO, Hideo, Kenichi YAMASAKI, Shigehiro HASHIMOTO i Yusuke MORITA. "A122 Relation between passive electric property and mechanical property for articular cartilage". Proceedings of the JSME Conference on Frontiers in Bioengineering 2005.16 (2005): 43–44. http://dx.doi.org/10.1299/jsmebiofro.2005.16.43.

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Hatano, Ryo, Masanori Fujita i Kota Imazu. "Mechanical Property of Glass Wool Reinforced Plastic". Seikei-Kakou 31, nr 6 (20.05.2019): 234–36. http://dx.doi.org/10.4325/seikeikakou.31.234.

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Tsukamoto, Yuji. "Mechanical Property Measuring Technique for Thin Films." HYBRIDS 8, nr 1 (1992): 27–33. http://dx.doi.org/10.5104/jiep1985.8.27.

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29

Huang, L., Y. L. Jiang i Y. Wang. "Mechanical Property of Internal Meshing Rotary Compressor". Applied Mechanics and Materials 799-800 (październik 2015): 760–64. http://dx.doi.org/10.4028/www.scientific.net/amm.799-800.760.

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The internal-meshing rotary mechanism is widely used in the oil pumps and cyclonical pin wheels application. The working principle of the internal meshing rotary compressor is very different with the current institutions applications. while, the mechanical property method of the internal meshing rotary pump can’t be entirely and directly used in the rotary compressor because of the different working principles. In order to simplify the study of the internal-meshing rotary compressors, the forces acted on the inner and outer gears are computed. The gas force and torque related to the rotating angle are derived, and then compared with other rotary compressors. The result shows that the internal meshing rotary compressor’s mechanical parameters vary periodically and the period is 2π/Z2and this type of compressor has perfect mechanical property compared with other compressors.

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Gong, Jian Hua, Dan Dan Li, Xiao Yan Li, Mang Zheng, Ya Juan Zhao i Bao Dong Ren. "Synthesis and Mechanical Property of Magnetic Polyurethane". Advanced Materials Research 512-515 (maj 2012): 2023–27. http://dx.doi.org/10.4028/www.scientific.net/amr.512-515.2023.

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Magnetic Polyurethane is synthesized by prepolymerization body method using PBA 2000, MDI, 1-4 butyl glycol and magnetic chain extender, which is synthesized by a method involving the use of dimethylol propionic acid (DMPA) and ferrous powder in dimethylformamide as solvent conditions. The mechanical property of magnetic polyurethane is measured by servo control computer system tension tester,Shore hardness of magnetic polyurethane is measured by LX-A type Shore rubber hardness tester.

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31

Jeong, Jae-Yeon, Kyeong-Sik Woo, Dong-Ju Lee, Soon-Hyung Hong i Yun-Chul Kim. "Prediction of Mechanical Property of Biomorphic Composites". Journal of the Korean Society for Aeronautical & Space Sciences 40, nr 8 (1.08.2012): 670–77. http://dx.doi.org/10.5139/jksas.2012.40.8.670.

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Ren, Facai, Xiaoying Tang, Jun Si i Jinsha Xu. "Mechanical property analysis of stainless steel bolt". Journal of Physics: Conference Series 1885, nr 2 (1.04.2021): 022032. http://dx.doi.org/10.1088/1742-6596/1885/2/022032.

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SASAKI, Ren, Arif Md Rashedul KABIR i Akira KAKUGO. "Biomolecular Motor Modulates Mechanical Property of Microtubules". Seibutsu Butsuri 55, nr 5 (2015): 259–61. http://dx.doi.org/10.2142/biophys.55.259.

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34

Reddy, B. R., Ashok K. Santra, David E. McMechan, Dennis W. Gray, Chad Brenneis i Rick Dunn. "Cement Mechanical Property Measurements Under Wellbore Conditions". SPE Drilling & Completion 22, nr 01 (1.03.2007): 33–38. http://dx.doi.org/10.2118/95921-pa.

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35

Yu Sun, Kai-Tak Wan, K. P. Roberts, J. C. Bischof i B. J. Nelson. "Mechanical property characterization of mouse zona pellucida". IEEE Transactions on Nanobioscience 2, nr 4 (grudzień 2003): 279–86. http://dx.doi.org/10.1109/tnb.2003.820273.

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MIYATA, Shogo, Takashi USHIDA, Guoping CHEN, Yasuo NITTA i Tetsuya TATEISHI. "Mechanical Property of in Vitro Regenerated Cartilage." Transactions of the Japan Society of Mechanical Engineers Series A 69, nr 677 (2003): 90–94. http://dx.doi.org/10.1299/kikaia.69.90.

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37

Navi, Parviz, i Antonio Pizzi. "Property changes in thermo-hydro-mechanical processing". Holzforschung 69, nr 7 (1.09.2015): 863–73. http://dx.doi.org/10.1515/hf-2014-0198.

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Abstract Thermo-hydro-mechanical (THM) treatment is a combined action of temperature, moisture, and mechanical force, which leads to modified wood (THMW). Various types of eco-friendly THM processes have been developed to enhance wood properties and generate new materials, such as welding, densification, molding, bending, profiling, artificial aging, panel manufacture, and surface densification. The various transformation processes in the course of THM bring about positive effects in terms of the mechanical and physical properties as well as the biological durability. To the negative effects belong the loss in strength and fracture toughness, and one of the challenges is to minimize these negative aspects. The present paper reviews the chemical transformations processes during THM treatment in a closed processing system and presents the relationship between processing parameters and THMW properties. The discussion includes the problems associated with eliminating the set recovery of densified wood by THM posttreatments and the chemical origin of the relaxation of internal stresses induced by densification.

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38

Yang, Qing Bin. "The Mechanical Property of Milk Protein Fiber". Advanced Materials Research 496 (marzec 2012): 431–34. http://dx.doi.org/10.4028/www.scientific.net/amr.496.431.

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To research basic property of milk protein fibre, basic property of milk protein fiber and wool were tested and analysed. Through analysing and contrasting each property it is considered that in dry state the strength of milk protein fiber is close to the soybean protein fiber and bigger than wool, the dynamic and static friction coefficient of milk protein fiber is bigger than that of soybean protein fiber. Crimpability of milk protein fiber is worse than that of wool.

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Pan, Xuan Sabrina, Jiewen Li, Edward B. Brown i Catherine K. Kuo. "Embryo movements regulate tendon mechanical property development". Philosophical Transactions of the Royal Society B: Biological Sciences 373, nr 1759 (24.09.2018): 20170325. http://dx.doi.org/10.1098/rstb.2017.0325.

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Tendons transmit forces from muscles to bones to enable skeletal motility. During development, tendons begin to bear load at the onset of embryo movements. Using the chick embryo model, this study showed that altered embryo movement frequency led to changes in elastic modulus of calcaneal tendon. In particular, paralysis led to decreased modulus, whereas hypermotility led to increased modulus. Paralysis also led to reductions in activity levels of lysyl oxidase (LOX), an enzyme that we previously showed is required for cross-linking-mediated elaboration of tendon mechanical properties. Additionally, inhibition of LOX activity abrogated hypermotility-induced increases in modulus. Taken together, our findings suggest embryo movements are critical for tendon mechanical property development and implicate LOX in this process. These exciting findings expand current knowledge of how functional tendons form during development and could guide future clinical approaches to treat tendon defects associated with abnormal mechanical loading in utero . This article is part of the Theo Murphy meeting issue ‘Mechanics of development’.

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40

Ge, Liqin, Helmuth Möhwald i Junbai Li. "Mechanical Property of Lipid-Coated Polyelectrolyte Microcapsules". Journal of Nanoscience and Nanotechnology 6, nr 8 (1.08.2006): 2489–93. http://dx.doi.org/10.1166/jnn.2006.541.

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YAMAMOTO, Takayuki, Yutaka ABE, Hideki NARIAI, Kenji YAMANE, Ryuji KOJIMA i Izuo AYA. "Estimation of mechanical property of CO_2 hydrate". Proceedings of the JSME annual meeting 2003.3 (2003): 367–68. http://dx.doi.org/10.1299/jsmemecjo.2003.3.0_367.

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MUTOH, Yoshiharu, Sirirat RATTANACHAN i Yukio MIYASHITA. "Mechanical Property of Al_2O_3/BaTiO_3 Ceramics Composite". Proceedings of the 1992 Annual Meeting of JSME/MMD 2002 (2002): 745–46. http://dx.doi.org/10.1299/jsmezairiki.2002.0_745.

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Kabir, Arif Md Rashedul, Daisuke Inoue, Yoshimi Hamano, Hiroyuki Mayama, Kazuki Sada i Akira Kakugo. "Biomolecular Motor Modulates Mechanical Property of Microtubule". Biomacromolecules 15, nr 5 (23.04.2014): 1797–805. http://dx.doi.org/10.1021/bm5001789.

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Shibayama, Mitsuhiro. "Structure-mechanical property relationship of tough hydrogels". Soft Matter 8, nr 31 (2012): 8030. http://dx.doi.org/10.1039/c2sm25325a.

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Stevens, Malcolm P. "Polymer additives: Part I. Mechanical property modifiers". Journal of Chemical Education 70, nr 6 (czerwiec 1993): 444. http://dx.doi.org/10.1021/ed070p444.

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Racek, O., i C. C. Berndt. "Mechanical property variations within thermal barrier coatings". Surface and Coatings Technology 202, nr 2 (listopad 2007): 362–69. http://dx.doi.org/10.1016/j.surfcoat.2007.05.091.

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47

Hashemi, S., M. T. Gilbride i J. Hodgkinson. "Mechanical property relationships in glass-filled polyoxymethylene". Journal of Materials Science 31, nr 19 (październik 1996): 5017–25. http://dx.doi.org/10.1007/bf00355900.

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48

Hirakuri, K. K., H. Tanabe i T. Nakano. "Superconducting property of YBa2Cu3O7 for mechanical stress". Journal of Materials Science Letters 14, nr 4 (1995): 294–96. http://dx.doi.org/10.1007/bf00275628.

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Mullarney, Matthew P., i Bruno C. Hancock. "Mechanical property anisotropy of pharmaceutical excipient compacts". International Journal of Pharmaceutics 314, nr 1 (maj 2006): 9–14. http://dx.doi.org/10.1016/j.ijpharm.2005.12.052.

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Wang, Fu-sheng, Pei-yan Wang, Yao-yao Ji, Zhi-qiang Liu i Zhu-feng Yue. "Mechanical property of single-bolted composite laminates". Journal of Central South University 21, nr 2 (luty 2014): 466–71. http://dx.doi.org/10.1007/s11771-014-1961-0.

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Artykuły w czasopismach na temat „Mechanical property”

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