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Materials and Methods Materials Extracted bovine Bone Morphogenetic Proteins mixture(BMPs)was a kind gift of Tianjin Zhongjin Biological Development Co., Ltd.
Acknowledgements This project is financially supported by the National Science Foundation of Tianjin, China (09JCYBJC14100); and the National Natural Science Foundation of China (NSFC11072266).
References [1] EH Groeneveld, EH Burger: European Journal of Endocrinology Vol. 142(2000),p.9 [2] GB Wei, QM Jin, WV Giannobile, PX Ma: Biomaterials Vol. 28 (2007),p.2087 [3] Gautschi OP, Frey SP, Zellweger R.
Release, Vol. 92(2003),p.173 [26] J Braunecker, M Baba, GE Milroy, et al: International Journal of Pharmaceutics, Vol. 282(2004),p.19 [27] R Jalil, JR Nixon: J.

Relationships between δ→γ phase transformation and the crack formation in continuous casting slabs Guowei Chang1, a, Qingchun Li1,b , Shuying Chen1,c, Xudong Yue1,d, Yan Yu2,e and Chengquan Wang2,f 1School of Materials Science and Engineering, Liaoning University of Technology, Jinzhou 121001, Liaoning, China 2Forward by Baosteel Research Institute, Beijing 100083, China ag.w.chang@hotmail.com, b lqcsusan@126.com, ccsy740608@foxmail.com, dx.d.yue@163.com, eyuyan@baosteel.com, fwcq231@yeah.net Keywords: Continuous Casting, Crack Formation, δ→γ Phase Transformation, Peritectic Reaction.
Experimental Researches The non-peritectic steel with the composition (wt%) of 0.06C and 0.28Si was prepared by using industrial pure iron, graphite and 75＃Si-Fe as raw materials.
The authors acknowledge the financial support provide by National Natual Science Foundation of China No.50874060.
Cai: Continuous Casting Steel (Science Press, Shanghai, 1990) (In Chinese)
Chiba: Journal of the Iron and Steel Institute of Japan Vol. 84(1998), p. 43 (In Japanese) [13] G.W.

Quantitative structure-activity analyses of nitrobenzene toxicity to Paramecium caudatum Jingbo Xu1, a, Nan Jing2,b 1Department of Environmental Science and Engineering, Northeast Normal University, Changchun 130024, China. 2Department of Logistics Engineering, South China University of Technology, Guangzhou 510641, China.
Materials and Methods Exposure organism and test chemicals.
Acknowledgements This study was financially supported by the National Natural Science Foundation of China (No. 21247001), the grant from the Subject Construction of Doctoral Degree by the Ministry of Education of PR China (No. 20100043110010).
Jing: Journal of Hazardous Materials Vol. 203-204 (2012) , p. 299 [4] T.
Li: Semi-empirical molecular orbital theory and practice (Beijing Science Publishers, Beijing 1981) [8] J.

Technical Application Process for Eco- Friendly Cotton by Antimicrobial Ching-Wen Lou1, Ching-Wen Lin2,b*, Chao-Chiung Huang3,c*, Shih-Yu Huang1, Ping-Jung Chan4 and Jia-Horng Lin1,4,a* 1Institute of Biomedical Engineering and Material Science, Central Taiwan University of Science and Technology, Taichung 406, Taiwan, R.O.C. 2Department of Fashion Design, Asia University, Taichung 41354, Taiwan, R.O.C. 3Department of Textiles & Clothing, Fu Jen Catholic University, Taipei County 242, Taiwan, R.O.C. 4Laboratory of Fiber Application and Manufacturing, Department of Fiber and Composite Materials, Feng Chia University, Taichung City 407, Taiwan, R.O.C. 5School of Chinese Medicine, China Medical University, Taichung 40402, Taiwan, R.O.C.
The experimental material we used grows in nature whose ingredient was influenced by origin, collecting time, water and geography, so it is difficult to achieve uniformity of extract rate.
Acknowledgement This work would especially like to thank National Science Council of the Republic of China, Taiwan, for financially supporting this research under Contract 98-2221-E-275-001.
Xiao: Chinese journal of hospital pharmacy, Vol. 28 (2008).

Study of Catalytic Pyrolysis of Chlorella with γ-Al2O3 Catalyst Juan Liu 1,a, Xia Li *2,b, QingJie Guo 3,c 1,2,3College of Materials Science and Technology, Qingdao University of Science & Technology, Qingdao 266042, PR China aLJqust@126.com, bLixqust@163.com, cqjguo@qust.edu.cn Keywords: chlorella, bio-oil, catalytic pyrolysis, γ-Al2O3.
Experimental Materials.
Journal of Analytical and Applied Pyrolysis, Vol.51(1999), p.3-22
Elsevier Applied Science, Vol. 35(2011), p.3199-3201

Analytical modeling and numerical simulations on the scaling of biomicrofluidic droplets Peiyuan He1,*, Liguo Zhang2 1School of life science, Zhengzhou University, Zhengzhou 450001, P.R.China Email: hepeiyuan@live.com 2 Henan research institute of pharmaceutical science, Zhengzhou University, Zhengzhou 450052, P.R.China Keywords: Analytical simulation, data analysis, numerical modeling, intelligent control, scaling Abstract Biomicrofluidic silhouettes brought about scientific challenges merited to be investigated through explicit florescence observation, implicit physical-chemical analysis and intermediate conductive level manipulation.
In biomicrofluidics, significant theories on the micrometer scale have been applied across several science fields, such as biomicrofluidic principles, chip technology, microreactors, etc.[1-4].
L.Yumin, Intelligent numerical manipulation of micrometer-scale emulsions using polymer confinement, Advanced Materials Research, 813 (2013) 431-434
Stone, Dip coating for the alignment of carbon nanotubes on curved surfaces, Journal of Materials Chemistry, 14 (2004) 1299-1302

Now the types of heat transfer structures applied in heat exchanger are scarce, so it is very necessary to further explore the best material, structure and preparation process of heat exchanger.
In the present experiments, four kinds of porous structures were tested: copper wire mesh with 200 mesh and 300 mesh, porosity 90%; metal foam with materials of brass and copper, and porosity 85%; copper fiber sintered felts with porosity of 70%, 80% and 90%; cross-connected micro-channel plate with the channel width of 2mm, the channel depth of 1.2mm and 1.4mm, and channel spacing 0.5mm and 0.8mm [2].
It is indicated that the material of the heat transfer structure is not the main factor of influencing the heat transfer performance.
Experimental Thermal and Fluid Science. 2010, 34: 1398-1402
International Journal of Thermal Sciences, 2010, 49: 2289-2298

According to the own characteristics and influence factors of shale gas, the main methods of shale gas resources potential include volume method, causes method (material balance method, Tissot method), geological analogy method (area/volume abundance method), statistics method (monte carlo method, FORSPAN model method), and dynamic method (diminishing curve method, numerical simulation method).
Acknowledgements This work was financially supported by the Chongqing Natural Science Foundation（cstc2012jjB9007） References [1] Jinchuan Zhang, Xue Hui and Yanfang Wang, et al.
Gas shale and CBM development in North America[J].Oil and Gas Financial Journal, 2008, 3(11),p.1-5
Engineering Sciences,2010,12(5),p.25-29
Natural gas and earth science, 2009. 20(3),p.466-470.

Acknowledgements This paper is supported by the natural science foundation of Gansu (No.0809RJZA010) Corresponding Author Long Yu, yangwl@lut.cn, 13099229434 References [1] Wang.Z.H, Chen G.H.: Chemical Eng.
Science.
[5] Guo.Z.Y.: Chinese Science Bulletin.
[16] Qin M.H.: Construction and Building Materials.
R.: Ciesc Journal.

Synthesis of Coal Fly Ash Zeolite with Copper Oxide Load for Acid Red GR wastewater Treatment BoQuan Jiang1,a , ZhengQiang Xiao 2,b 1Nanchang University College of Science and Technology, Nanchang, Jiangxi, 330029, P.R.China 2Jiangxi Academy of Sciences, Nanchang, Jiangxi, 330029, P.R.
Introduction Most of Chinese power plants use coal as raw materials.
XRD pattern of synthesized zeolite Conclusions The optimum technical conditions for the synthesis of zeolite using waste coal fly ash as raw material were determined by orthogonal test to be: m (ash)/m (alkaline)= 1.2:1, m(water)/m(ash)=9:1, calcining temperature 700˚C and crystallization time 10 h.
Fuel Vol.78(1999), p.1225 [5] Shiyong Zhao:Coal Science and Technology Vol.36 (2008)，p.106
[6] Querol X, Plana F and Alastuey A: Fuel Vol.76(1997),p.793 [7]Chunfeng Wang and Jiansheng Li: Journal of the Chinese Ceramic Society Vol.36(2008),p.1638 [8] Inada M, and Tsujimoto H:.Fuel Vol.84(2005), p.1482