Introduction to BioMEMS

Introduction to BioMEMS

Volumn , Issue , 2016, Pages 1-487

  Folch, Albert ^a  

^a UNIVERSITY OF BARCELONA   (Spain)

Author keywords

[No Author keywords available]

Indexed keywords

EID: 85129644660     PISSN: None     EISSN: None     Source Type: Book    
DOI: None     Document Type: Book

References (83)

1. Abgrall, P., Conedera, V., Camon, H., Gue, A.M., and Nguyen, N.T. "SU-8 as a structural material for labs-on-chips and microelectromechanical systems," Electrophoresis 28, 4539-4551 (2007).
2. Ariga, K., Hill, J.P., Lee, M.V., Vinu, A., Charvet, R., and Acharya, S. "Challenges and breakthroughs in recent research on self-assembly," Science and Technology of Advanced Materials 9, 1-96 (2008).
3. Banta, S., Wheeldon, I.R., and Blenner, M. "Protein engineering in the development of functional hydrogels," Annual Review of Biomedical Engineering 12, 167-186 (2010).
4. Bishop, K.J.M., Wilmer, C.E., Soh, S., and Grzybowski, B.A. "Nanoscale forces and their uses in self-assembly," Small 5, 1600-1630 (2009).
5. Del Campo, A., and Greiner, C. "SU-8: a photoresist for high-aspect-ratio and 3D submicron lithography," Journal of Micromechanics and Microengineering 17, R81-R95 (2007).
6. Madou, M. Fundamentals of Microfabrication, 752 pp. CRC Press (2002).
7. Maruo, S., and Fourkas, J.T. "Recent progress in multiphoton microfabrication," Laser & Photonics Reviews 2, 100-111 (2008).
8. Qin, D., Xia, Y., and Whitesides, G.M. "Sot lithography for micro- and nanoscale patterning," Nature Protocols 5, 491-502 (2010).
9. Wang, W., and Soper, S.A. (editors), Bio-MEMS: Technologies and Applications, 477 pp. CRC Press (2007).
10. Weibel, D.B., DiLuzio, W.R., and Whitesides, G.M. "Microfabrication meets microbiology," Nature Reviews Microbiology 5, 209-218 (2007).
11. Wikipedia article on etching, "Etching (microfabrication)," see http://en.wikipedia.org/wiki/Etching_(microfabrication).
12. Xia, Y., and Whitesides, G. "Sot lithography," Angewandte Chemie (Int. Ed.) 37, 550-575 (1998).
13. Baneyx, F., and Schwartz, D.T. "Selection and analysis of solid-binding peptides," Current Opinion in Biotechnology 18, 312-317 (2007).
14. Falconnet, D., Csucs, G., Michelle Grandin, H., and Textor, M. "Surface engineering approaches to micropattern surfaces for cell-based assays," Biomaterials 27, 3044-3063 (2006).
15. Folch, A., and Toner, M. "Microengineering of Cellular Interactions," Annual Review of Biomedical Engineering 2, 227-256 (2000).
16. Lim, J.Y., and Donahue, H.J. "Cell sensing and response to micro- and nanostructured surfaces produced by chemical and topographic patterning," Tissue Engineering 13, 1879-1891 (2007).
17. Madou, M. Fundamentals of Microfabrication. CRC Press (2002).
18. Mrksich, M. "Using self-assembled monolayers to model the extracellular matrix," Acta Biomaterialia 5, 832-841 (2009).
19. Nie, Z., and Kumacheva, E. "Patterning surfaces with functional polymers," Nature Materials 7, 277-290 (2008).
20. Smith, R.K., Lewis, P.A., and Weiss, P.S. "Patterning self-assembled monolayers," Progress in Surface Science 75, 1-68 (2004).
21. Stevens, M.M., and George, J.H. "Exploring and engineering the cell surface interface," Science 310, 1135-1138 (2005).
22. Atencia, J., and Beebe, D.J. "Controlled microluidic interfaces," Nature 437, 648-655 (2005).
23. Brody, J., Yager, P., Goldstein, R., and Austin, R. "Biotechnology at low Reynolds numbers," Biophysical Journal 71, 3430-3441 (1996).
24. Dufy, D.C., McDonald, J.C., Schueller, O.J.A., and Whitesides, G.M. "Rapid prototyping of microluidic systems in poly(dimethylsiloxane)," Analytical Chemistry 70, 4974-4984 (1998).
25. Nguyen, N.-T., and Wereley, S.T. "Fundamentals and Applications of Microluidics," Artech House (2002).
26. Purcell, E.M. "Life at low Reynolds number," American Journal of Physics 45, 3-11 (1977).
27. Santiago, J. G., Wereley, S., Meinhart, C.D., Beebe, D.J., and Adrian, R.J. "A particle image velocimetry system for microluidics," Experiments in Fluids 25, 316-319 (1998).
28. Stewart, R.J., Ransom, T.C., and Hlady, V. "Natural underwater adhesives," Polymer Physics 49, 757-771 (2011).
29. Stone, H.A., Stroock, A.D., and Ajdari, A. "Engineering lows in small devices: microluidics toward a Lab-on-a-chip," Annual Review of Fluid Mechanics 36, 381-411 (2004).
30. Teh, S.-Y., Lin, R., Hung, L.-H., and Lee, A.P. "Droplet microluidics," Lab on a Chip 8, 198-220 (2008).
31. White, F.M. Fluid Mechanics, McGraw-Hill (1979).
32. Bashir, R., and Wereley, S. (editors). "Biomolecular sensing, processing and analysis," Vol. IV of BioMEMS and Biomedical Nanotechnology Series. Springer (2006).
33. Berthier, J., and Silberzan, P. Microluidics for Biotechnology, 2nd ed. Artech House (2010).
34. Hardt, S., and Schönfeld, F. (editors). Microluidic Technologies for Miniaturized Analysis Systems. Springer (2007).
35. Ozkan, M., and Heller, M. J. (editors). "Micro/nano technology for genomics and proteomics" Vol. II of BioMEMS and Biomedical Nanotechnology Series. Springer (2006).
36. Pamme, N. "Continuous low separations in microluidic devices," Lab on a Chip 7, 1644-1659 (2007).
37. Saliterman, S.S. Fundamentals of BioMEMS and Medical Microdevices. SPIE Press (2006).
38. Chen P., X. Feng, W. Du, and B. Liu. "Microluidic chips for cell sorting," Frontiers in Bioscience 13, 2464-2483 (2008).
39. Chung, T. D. and H. C. Kim. "Recent advances in miniaturized microluidic low cytometry for clinical use," Electrophoresis 28, 4511-4520 (2007).
40. Dittrich, P. S. and A. Manz. "Lab-on-a-chip: microluidics in drug discovery," Nature Reviews Drug Discovery 5, 210-218 (2006).
41. Godin, J., C. H. Chen, S. H. Cho, W. Qiao, F. Tsai, and Y. H. Lo. "Microluidics and photonics for Bio-System-on-a-Chip: a review of advancements in technology towards a microluidic low cytometry chip," Journal of Biophotonics 1, 355-376 (2008).
42. Mairhofer, J., K. Roppert, and P. Ertl. "Microluidic systems for pathogen sensing: a review," Sensors 9, 4804-4823 (2009).
43. Meyvantsson, I., and D. J. Beebe. "Cell culture models in microluidic systems," Annual Review of Analytical Chemistry 1, 423-449 (2008).
44. Nilsson, J., M. Evander, B. Hammarstrom, and T. Laurell. "Review of cell and particle trapping in microluidic systems," Analytica Chimica Acta 649, 141-157 (2009).
45. Verpoorte, E. "Microluidic chips for clinical and forensic analysis," Electrophoresis 23, 677-712 (2002).
46. Walker, G. M., H. Zeringue, and D. J. Beebe. "Microenvironment design considerations for cellular scale studies," Lab on a Chip 4, 91-97 (2004).
47. Wang, W. and S. A. Soper (editors). Bio-MEMS: Technologies and Applications. CRC Press (2007).
48. Wu, M.-H., S.-B. Huang, and G.-B. Lee. "Microluidic cell culture systems for drug research," Lab on a Chip 10, 939-956 (2010).
49. Xu, Y., X. Yang, and E. Wang. "Review: aptamers in microluidic chips," Analytica Chimica Acta 1, 12-20 (2010).
50. Yan H., B. Zhang, and H. Wu. "Chemical cytometry on microluidic chips," Electrophoresis 29, 1775-1786 (2008).
51. Zhang, C., D. Xing, and Y. Li. "Micropumps, microvalves, and micromixers within PCR microluidic chips: advances and trends," Biotechnology Advances 25, 483-514 (2007).
52. Ahmed, T., T. S. Shimizu, and R. Stocker. "Microluidics for bacterial chemotaxis," Integrated Biology 2, 604-629 (2010).
53. Choi, C. K., M. T. Breckenridge, and C. S. Chen. "Engineered materials and the cellular microenvironment: a strengthening interface between cell biology and bioengineering," Trends in Cell Biology 20, 705-714 (2010).
54. Desai, T., and S. Bhatia (editors). "herapeutic micro/nanotechnology," vol. III, BioMEMS and Biomedical Nanotechnology Series. Springer (2006).
55. Irimia, D. "Microluidic technologies for temporal perturbations of chemotaxis," Annual Review of Biomedical Engineering 12, 259-284 (2010).
56. Kaji, H., G. Camci-Unal, R. Langer, and A. Khademhosseini. "Engineering systems for the generation of patterned co-cultures for controlling cell-cell interactions," Biochimica et Biophysica Acta 1810, 239-250 (2011).
57. Keenan, T. M., and A. Folch. "Biomolecular gradients in cell culture systems," Lab on a Chip 8, 34-57 (2008).
58. Kim, D.-H., P. K. Wong, J. Park, A. Levchenko, and Y. Sun. "Microengineered platforms for cell mechanobiology," Annual Review of Biomedical Engineering 11, 203-233 (2009).
59. Raghavan, S., and C. S. Chen. "Micropatterned environments in cell biology," Advanced Materials 16, 1303-1313 (2004).
60. Taylor, A. M., and N. L. Jeon. "Micro-scale and microluidic devices for neurobiology," Current Opinion in Neurobiology 20, 640-647 (2010).
61. Velve-Casquillas, G., M. Le Berre, M. Piel, and P. T. Tran. "Microluidic tools for cell biological research," Nano Today 5, 28-47 (2010).
62. Wang, J., L. Ren, L. Li, W. Liu, J. Zhou, W. Yu, D. Tong, and S. Chen. "Microluidics: a new cosset for neurobiology," Lab on a Chip, 9, 644-652 (2009).
63. Weibel, D. B., W. R. DiLuzio, and G. M. Whitesides. "Microfabrication meets microbiology," Nature Reviews Microbiology 5, 209-218 (2007).
64. Ashton, R.S., A.J. Keung, J. Peltier, and D.V. Schafer. "Progress and prospects for stem cell engineering," Annual Review of Chemical and Biomolecular Engineering 2, 479-502 (2011).
65. Berthiaume, F., T.J. Maguire, and M.L. Yarmush. "Tissue engineering and regenerative medicine: history, progress and challenges," Annual Review of Chemical and Biomolecular Engineering 2, 403-30 (2011).
66. Coutinho, D., P. Costa, N. Neves, M.E. Gomes, and R.L. Reis. "Micro- and nanotechnology in tissue engineering," Tissue Engineering Part 1, 3-29 (2011).
67. Desai, T., and S. Bhatia (editors). "herapeutic micro/nanotechnology," in BioMEMS and Biomedical Nanotechnology Series (Vol. III), Springer (2006).
68. Drury, J.L., and D.J. Mooney. "Hydrogels for tissue engineering: scafold design variables and applications," Biomaterials 24, 4337-4351 (2003).
69. Gupta, K., D.-H. Kim, D. Ellison, C. Smith, and A. Levchenko. "Using lab-on-a-chip technologies for stem cell biology," Stem Cell Biology and Regenerative Medicine 5, 483-498 (2011).
70. Khademhosseini, A., R. Langer, J. Borenstein, and J.P. Vacanti. "Microscale technologies for tissue engineering and biology," Proceedings of the National Academy of Sciences of the United States of America 103, 2480-2487 (2006).
71. Lanza R., R. Langer, and J. Vacanti (editors). Principles of Tissue Engineering (3rd ed.), Academic Press (2007).
72. Palsson, B., and S. Bhatia. Tissue Engineering, Prentice Hall (2003).
73. Shan, J., K.R. Stevens, K. Trehan, G.H. Underhill, A.A. Chen, and S.N. Bhatia. "Hepatic tissue engineering," in Molecular Pathology of Liver Diseases, S.P.S. Monga (ed.), Springer Science, 321-342 (2011).
74. Toh, Y.-C., K. Blagovic, and J. Voldman. "Advancing stem cell research with microtechnologies: opportunities and challenges," Integrative Biology 2, 305-325 (2010).
75. Ainslie, Kristy M., and Desai, Tejal A. "Microfabricated implants for applications in therapeutic delivery, tissue engineering, and biosensing," Lab on a Chip 8, 1864-1878 (2008).
76. Cheung, K. C. "Implantable microscale neural interfaces," Biomedical Microdevices, 9, 923-938 (2007).
77. Desai, Tejal and Bhatia, Sangeeta (editors). "herapeutic micro/nanotechnology," in BioMEMS and Biomedical Nanotechnology Series (Vol. III), Springer (2006).
78. Kipke, D. R., W. Shain, G. Buzsaki, E. Fetz, J. M. Henderson, J. F. Hetke, and G. Schalk. "Advanced neurotechnologies for chronic neural interfaces: new horizons and clinical opportunities," Journal of Neuroscience 28, 11830-11838 (2008).
79. Vandervoort, J., and A. Ludwig. "Micro-needles for transdermal drug delivery: a minireview," Frontiers in Bioscience 13, 1711-1715 (2008).
80. Wang, Wanjun, and Soper, Steven A. (editors). Bio-MEMS: Technologies and Applications, CRC Press (2007).
81. Wise, K. "Integrated sensors, MEMS and microsystems: relections on a fantastic voyage," Sensors and Actuators. A, Physical 36, 39-50 (2007).
82. Zhou, David, and Greenbaum, Elias (editors). Implantable Neural Prosthesis 1: Devices and Applications," Springer (2009).
83. Zhou, David, and Greenbaum, Elias (editors). Implantable Neural Prosthesis 2: Techniques and Engineering Approaches, Springer (2009).