Experimental study on high throughput vitrification by micro-droplet spray method_Journal of Biomedical Engineering

Authors：

YU Zixuan , ZHANG Xiaomin ,  ZHOU Xinli

School of Medical Instrument and Food Engineering, University of Shanghai for Science and Technology, Shanghai 200093, P.R.China;

Corresponding author：

ZHOU Xinli, Email: zjulily@163.com

Keywords：

micro-droplet spray; high throughput; vitrification

DOI：

10.7507/1001-5515.201812017

Video：

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Abstract Full text Figures/Tables Video References Cited by

There is a great demand for blood and stem cells in clinic. It is difficult to achieve high throughput and to increase the cooling rate at the same time during vitrification. In this paper, a micro-droplet spray system with a container collection device was fabricated, and HepG2 cells were sprayed by this system for high-throughput vitrification. First, the container collection device and a cryo-paper were used to receive micro-droplets in the spray vitrification system. The results showed that the cell survival rate and 24h adhesion rate in container collection vitrification group were significantly higher than those in cryo-paper collection group. Second, HepG2 cells were sprayed and vitrified at increased cell density, and it was found that the results of micro-droplet spray vitrification did not change significantly. Finally, micro-droplet spray vitrification is compared with slow freezing. Cell processing capacity in the vitrification group increased, meanwhile, the cell survival rate and 24h adhesion rate in the vitrification group were significantly higher than those in slow freezing group. The results indicated that the micro-droplet spray vitrification system with container collection device designed in this paper can achieve high-throughput cell vitrification, which is of great significance for mass preservation of small cells.

Citation： YU Zixuan, ZHANG Xiaomin, ZHOU Xinli. Experimental study on high throughput vitrification by micro-droplet spray method. Journal of Biomedical Engineering, 2019, 36(5): 850-855, 861. doi: 10.7507/1001-5515.201812017 Copy

1.	Patil V, Shetmahajan M. Massive transfusion and massive transfusion protocol. Indian J Anaesth, 2014, 58(5): 590-595.
2.	Copelan E A. Hematopoietic stem-cell transplantation. N Engl J Med, 2006, 354(17): 1813-1826.
3.	Chang A, Kim Y, Hoehn R, et al. Cryopreserved packed red blood cells in surgical patients: past, present, and future. Blood Transfusion, 2017, 15(4): 341-347.
4.	Berz D, Mccormack E M, Winer E S, et al. Cryopreservation of hematopoietic stem cells. Am J Hematol, 2007, 82(6): 463-472.
5.	Dhali A, Anchamparuthy V M, Butler S P, et al. Gene expression and development of mouse zygotes following droplet vitrification. Theriogenology, 2007, 68(9): 1292-1298.
6.	Song Y S, Adler D, Xu Feng, et al. Vitrification and levitation of a liquid droplet on liquid Nitrogen. Proc Natl Acad Sci U S A, 2010, 107(10): 4596-4600.
7.	Zhang X, Catalano P N, Gurkan U A, et al. Emerging technologies in medical applications of minimum volume vitrification. Nanomedicine, 2011, 6(6): 1115-1129.
8.	Xu F, Moon S J, Emre A E, et al. A droplet-based building block approach for bladder smooth muscle cell (SMC) proliferation. Biofabrication, 2010, 2(1): 014105.
9.	Martinez-Burgos M, Herrero L, Megias D A, et al. Vitrification versus slow freezing of oocytes: effects on morphologic appearance, meiotic spindle configuration, and DNA damage. Fertil Steril, 2011, 95(1): 374-377.
10.	Demirci U, Yaralioglu G G, Haeggstrom E, et al. 2D acoustically actuated micromachined droplet ejector array//2003 IEEE Ultrasonics Symposium Proceedings, Honolulu, 2003: 1983-1986.
11.	Demirci U, Yaralioglu G G, Haeggstrom E, et al. Femtoliter to picoliter droplet Generation for organic polymer deposition using single reservoir ejector arrays. IEEE Transactions on Semiconductor Manufacturing, 2005, 18(4): 709-715.
12.	Demirci U. Acoustic picoliter droplets for emerging applications in semiconductor industry and biotechnology. Journal of Microelectromechanical Systems, 2006, 15(4): 957-966.
13.	Demirci U. Droplet-based photoresist deposition. Appl Phys Lett, 2006, 88(14): 144104.
14.	Rami E A, Sinan G, Atakan G U, et al. Bio-inspired cryo-ink preserves red blood cell phenotype and function during nanoliter vitrification. Advanced Materials, 2014, 26(33): 5815-5822.
15.	Samot J, Moon S, Shao Lei, et al. Blood banking in living droplets. PLoS One, 2011, 6(3): e17530.
16.	Zhang Xiaohui, Khimji I, Shao Lei, et al. Nanoliter droplet vitrification for oocyte cryopreservation. Nanomedicine, 2012, 7(4): 553-564.
17.	张宵敏. 微滴喷射玻璃化保存的实验研究. 上海: 上海理工大学医疗器械与食品学院, 2018.
18.	Nakashima A, Ino N, Kusumi M, et al. Optimization of a novel nylon mesh container for human embryo ultrarapid vitrification. Fertil Steril, 2010, 93(7): 2405-2410.
19.	Yamanaka T, Goto T, Hirabayashi M, et al. Nylon mesh device for vitrification of large quantities of rat pancreatic islets. Biopreserv Biobank, 2017, 15(5): 457-462.

1. Patil V, Shetmahajan M. Massive transfusion and massive transfusion protocol. Indian J Anaesth, 2014, 58(5): 590-595.
2. Copelan E A. Hematopoietic stem-cell transplantation. N Engl J Med, 2006, 354(17): 1813-1826.
3. Chang A, Kim Y, Hoehn R, et al. Cryopreserved packed red blood cells in surgical patients: past, present, and future. Blood Transfusion, 2017, 15(4): 341-347.
4. Berz D, Mccormack E M, Winer E S, et al. Cryopreservation of hematopoietic stem cells. Am J Hematol, 2007, 82(6): 463-472.
5. Dhali A, Anchamparuthy V M, Butler S P, et al. Gene expression and development of mouse zygotes following droplet vitrification. Theriogenology, 2007, 68(9): 1292-1298.
6. Song Y S, Adler D, Xu Feng, et al. Vitrification and levitation of a liquid droplet on liquid Nitrogen. Proc Natl Acad Sci U S A, 2010, 107(10): 4596-4600.
7. Zhang X, Catalano P N, Gurkan U A, et al. Emerging technologies in medical applications of minimum volume vitrification. Nanomedicine, 2011, 6(6): 1115-1129.
8. Xu F, Moon S J, Emre A E, et al. A droplet-based building block approach for bladder smooth muscle cell (SMC) proliferation. Biofabrication, 2010, 2(1): 014105.
9. Martinez-Burgos M, Herrero L, Megias D A, et al. Vitrification versus slow freezing of oocytes: effects on morphologic appearance, meiotic spindle configuration, and DNA damage. Fertil Steril, 2011, 95(1): 374-377.
10. Demirci U, Yaralioglu G G, Haeggstrom E, et al. 2D acoustically actuated micromachined droplet ejector array//2003 IEEE Ultrasonics Symposium Proceedings, Honolulu, 2003: 1983-1986.
11. Demirci U, Yaralioglu G G, Haeggstrom E, et al. Femtoliter to picoliter droplet Generation for organic polymer deposition using single reservoir ejector arrays. IEEE Transactions on Semiconductor Manufacturing, 2005, 18(4): 709-715.
12. Demirci U. Acoustic picoliter droplets for emerging applications in semiconductor industry and biotechnology. Journal of Microelectromechanical Systems, 2006, 15(4): 957-966.
13. Demirci U. Droplet-based photoresist deposition. Appl Phys Lett, 2006, 88(14): 144104.
14. Rami E A, Sinan G, Atakan G U, et al. Bio-inspired cryo-ink preserves red blood cell phenotype and function during nanoliter vitrification. Advanced Materials, 2014, 26(33): 5815-5822.
15. Samot J, Moon S, Shao Lei, et al. Blood banking in living droplets. PLoS One, 2011, 6(3): e17530.
16. Zhang Xiaohui, Khimji I, Shao Lei, et al. Nanoliter droplet vitrification for oocyte cryopreservation. Nanomedicine, 2012, 7(4): 553-564.
17. 张宵敏. 微滴喷射玻璃化保存的实验研究. 上海: 上海理工大学医疗器械与食品学院, 2018.
18. Nakashima A, Ino N, Kusumi M, et al. Optimization of a novel nylon mesh container for human embryo ultrarapid vitrification. Fertil Steril, 2010, 93(7): 2405-2410.
19. Yamanaka T, Goto T, Hirabayashi M, et al. Nylon mesh device for vitrification of large quantities of rat pancreatic islets. Biopreserv Biobank, 2017, 15(5): 457-462.

Journal of Biomedical Engineering

Experimental study on high throughput vitrification by micro-droplet spray method

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