METU-gene/ References

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Acknowledgement

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Firstly, we special thanks to Prof Dr Vasıf HASIRCI and Nesrin HASIRCI for their help in preperation of biomaterial-grade Wound Dressing layers.


At the design of ABC transporter domin plasmid and signal tag plasmids for EGF, we appretiate very much to Jung Hoon Ahn from Institute for Gifted Students, Korea Advanced Institute of Science and Technology.


At the design of oxygen promoter and its usage techniques, thank you very much to Hikmet Geckil, Fulbright Postdoctoral Researcher at Harvard-MIT Health Sciences and Technology and his assistant Emel Aytan.



At the lab works, because of their vital helps, we want to say that we owe to Prof.Dr. Nilüfer CIHANGIR from Hacettepe University ,Serpil TAKAC from Chemical Engineering at Ankara University, and Aysel UGUR from Mugla University.

REFERENCES


1. Ulubayram K., Cakar A.N., Korkusuz P., Ertan C. and Hasirci N. “EGF containing gelatin-based wound dressings.” Biomaterials, accepted 22 September 2000.

2. Samuel E. Lynch, Robert B. Colvin, and Harry N. Antoniades. (1989) “Growth Factors in Wound Healing: Single and Synergistic Effects on Partial Thickness Porcine Skin Wounds.” Institute of Molecular Biology, Boston, Massachusetts. The American Society for Clinical Investigation, Inc. 0021-9738/89/08/0640/07 Volume 84, p. 640-646


3. A-H. Salmanian, A. Gushchin, T. Medvedeva, M. R. Noori-Daloii and N. Domansky. “Synthesis and expression of the gene for human epidermal growth factor in transgenic potato plants.” Biotechnology Letters (September 1996), Volume 18 No. 9 pp.1095-1098.

4. Reshma P Shetty, Drew Endy and Thomas F Knight Jr. “Engineering BioBrick vectors from BioBrick parts.” Journal of Biological Engineering, published April 14, 2008.

5. Knight, T. (2009) “Idempotent Vector Design for Standard Assembly of Biobricks.” MIT Artificial Intelligence Laboratory.

6. Sambrook J. & Russell D. W. “Molecular Cloning: A Laboratory Manual”. Cold Spring Harbor Laboratory Press, Third Edition.

7. Shiraha H., Gupta K., Drabik K. and Wells A. (2000) “Aging Fibroblasts Present Reduced Epidermal Growth Factor (EGF) Responsiveness Due to Preferential Loss of EGF Receptors.” The Journal of Biological Chemistry, revised form March 16, 2000.

8. Nanney B. L. (1990) “ Epidermal and Dermal Effects of Epidermal Growth Factor During Wound Repair.” Departments of Plastic Surgery and Cell Biology, Vanderbilt University School of Medicine.

9. Güler F., Kologlu M., Yagmurlu A., Guven C., Hasirc i N., Aytac S., and Dindar H. (2004). “The Effects of Local and Sustained Release of Fibroblast Growth Factor on Testicular Blood Flow and Morphology in Spermatic Artery– and Vein-Ligated Rats.” J Pediatr Surg 39:709-716.

10. Barbara A. Wenczak,John B. Lynch, and Lillian B. Nanney. “Epidermal Growth Factor Receptor Distribution in Burn Wounds Implications for Growth Factor-mediated Repair.” Departments of Plastic Surgery and Cell Biology, Vanderbilt University School ofMedicine.

11. Glenn F. Pierce, Ph.D., M.D. And Thomas A. Mustoe, M.D. (1995) “Pharmacologic Enhancement of Wound Healing.” Annual. Reviews. Med. 46:467–81

12. Chung C, You J, Kim K. and Ahn J.H. “Export of recombinant proteins in Escherichia coli using ABC transporter with an attached lipase ABC transporter recognition domain (LARD).” Microbial Cell Factories, Published: 29 January 2009.

13. Shadel G. , Young R. & Thomas. “Use of Regulated Cell Lysis in a Lethal Genetic Selection in Escherichia coli: Identification of the Autoinducer-Binding Region of the LuxR Protein from Vibrio fischeri ATCC 7744.” .Journal of Bacteriology, July 1990. p. 3980-3987. Vol.172,No.7

14. Oka T., Sakamoto S. , Miyoshi K., Fuwa T. , and Miyake T . (1985) “Synthesis and secretion of human epidermal growth factor by Escherichia coli.” Biochemistry, Vol. 82, pp. 7212-7216.

15. Ernst W., Thoma-Uszynski S., Teitelbaum R., Hanson D.A., Clayberger C.et al. (2000) “Granulysin, a T Cell Product, Kills Bacteria by Altering Membrane Permeability”. The Journal of Immunology, 165: 7102–7108

16. Andree C., Swain W., Page C. et al. (1994) “In vivo transfer and expression of a human epidermal growth actor gene accelerates wound repair”. MedicalSciences, Proc. Nati. Acad. Sci. USA Vol. 91, pp. 12188-12192.

17. Okay S., Tefon B.E. , Özkan, M. a nd Özcengiz G. (2008) “Expression of chitinase A (chiA) gene from a local isolate of Serratia marcescens in Coleoptera-specific Bacillus thuringiensis.” Journal of Applied Microbiology,104,161-170.

18. Caetano L., Antunes M., & Ferreira R.B.R. (2009). “Intercellular communication in bacteria.” Critical Reviews in Microbiology. 35, 69-80.

19. Miller M.B., Bassler B.L. (2001). “Quorum Sensing in Bacteria”. Annual Reviews of Microbiology. 55: 165-199. Department of Molecular Biology, Princeton University.

20. Stenger S., Hanson D. A., Teitelbaum R. et al. (1998). “An antimicrobial activity of cytolytic T cells mediated by granulysin”. Science Vol. 282. no. 5386, pp. 121 – 125.

21. Jimenez P.A. & Rampy M.A (1999). “Kerotinocyte Growth Factor-2 accelerates wound healing in incisional wounds. Journal of Surgical Research, Vol.81, pp 238-242.

22. Karvinen S. Pasonen-Seppänen S. , Hyttinen J. et al. (2003) “Keratinocyte Growth Factor Stimulates Migration and Hyaluronan Synthesis in the Epidermis by Activation of Keratinocyte Hyaluronan Synthases 2 and 3.” J. Biol. Chem., Vol. 278, Issue 49, 49495-49504.

23. Snowman, J.W.& Menyhart L. (1988) “Lyophilization: Freeze-Drying a downstream process”. Downstream Processes: Equipment and Techniques, pp 315-351.

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