研究者業績

Yuichi Yamasaki

  (山崎 裕一)

Profile Information

Affiliation
Faculty of Pharmacy, Musashino University
Degree
Ph.D.(Mar, 2000, Nagoya University)

Researcher number
00322678
ORCID ID
 https://orcid.org/0000-0001-8358-6550
J-GLOBAL ID
202301013217394042
researchmap Member ID
R000050076

Major Papers

 69
  • Yuichi Yamasaki, Daiki Kumekawa, Satoshi Yamauchi, Hodaka Omuro
    ACS OMEGA, 7(18) 15478-15487, May, 2022  
    We previously synthesized cysteine-installed C-terminally PEGylated oligolysines with 20 amino acid residues to form cross-linked polymeric micelles (PMs) with luciferase-coding plasmid DNA as a candidate for artificial gene vectors. Luciferase gene expression in HeLa cells mediated by PEG-CK18C, PEG-CK9CK9, and PEG-K9CK9C was reported to be 35-, 5.4-, and 1.3-fold higher than that mediated by cysteine-uninstalled PEGylated oligolysine PEG-K-20, respectively. However, after the publication, the survival rate of HeLa cells used in the previous study was found to be lower than usual when subcutaneously implanted into mice to create a xenograft model. In this study, to re-examine the peptide sequence-dependent gene expression, gene expression efficacy mediated by PEG-peptide PMs was compared with the PM cellular uptake results using newly obtained HeLa cell lines and the additional cell lines Huh-7, PANC-1, and BxPC3. As a result, PEG-K9CK9C PMs mediated the maximum gene expression in all cell lines, and the corresponding cellular uptake was also obtained. Therefore, we concluded that our previous results were erroneously obtained due to normality-depleted HeLa cells. A comparison of physicochemical characterizations, gene expression efficacy, and cellular uptake of PEG-peptide PMs is discussed in detail.

Misc.

 2
  • Hidehiro Oana, Akihiro Kishimura, Yuichi Yamasaki, Masao Washizu, Kazunori Kataoka
    20th Anniversary MHS 2009 and Micro-Nano Global COE - 2009 International Symposium on Micro-NanoMechatronics and Human Science, 155-160, 2009  
    Spontaneous formation of a giant polymer vesicle from a single micrometer-sized droplet of polyion complex (PIC) of diblock copolymers and its derivative by thermal perturbation, which is achieved by irradiation with a focused infrared laser is presented. The thermal perturbation induces a microphase separation inside of the PIC droplet and the generated water rich phase in the PIC droplet becomes a content of the vesicle and the PIC is deformed into a self-assembled membrane of the vesicle. The size of the giant unilamellar vesicles formed is determined on the basis of the initial size of the PIC droplets. ©2009 IEEE.
  • H. Oana, K. Yonehara, A. Kishimura, Y. Yamasaki, K. Kataoka, M. Washizu
    12th International Conference on Miniaturized Systems for Chemistry and Life Sciences - The Proceedings of MicroTAS 2008 Conference, 631-633, Oct, 2008  
    This paper presents a new method for the formation of giant polymer vesicles, which utilizes a microphase separation occurring in microdroplets of polyion complex (PIC), and continuous production of the giant polymer vesicles is demonstrated using a microfluidic channel. © 2008 CBMS.

Research Projects

 7