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PUBLICATIONS

1.    Kim YG, Jeong HJ, Jang KS, Yang YH, Song YS, Chung J, and Kim BG.

       Rapid and high-throughput analysis of N-glycans from ovarian cancer serum using 96-well plate platform.

       Anal Biochem, 2009; 391:151-3. 2.

 

2.    Jeong HJ, Kim YG, Yang YH, and Kim BG.

       High-throughput quantitative analysis of total N-glycans by matrix-assisted laser desorption/ionization time-of-

       flight mass spectrometry.

       Anal Chem, 2012; 84:3453-60. 

 

3.    Choi SY, Jeong HJ, Lim HG, Park SS, Kim SH, and Kim YJ.

       Elimination of α-Gal xenoreactive epitope: α-galactosidase treatment of porcine heart valves.

       J Heart Valve Dis, 2012; 21:387-97. 

 

4.    Park JH, Wang Z, Jeong HJ, Park HH, Kim BG, Tan WS, Choi SS, and Park TH.

       Enhancement of recombinant human EPO production and glycosylation in serum-free suspension culture of

       CHO cells through expression and supplementation of 30Kc19.

       Appl Microbiol Biotechnol, 2012; 96:671-83. 
 
5.    Jeong HJ, Ohmuro-Matsuyama Y, Ohashi H, Ohsawa F, Tatsu Y, Inagaki M, and Ueda H.

       Detection of vimentin serine phosphorylation by multicolor Quenchbodies.

       Biosens Bioelectron, 2013; 40:17-23. 

 

6.    Ueda H and Jeong HJ.

       Detection of cell cycle-dependent protein phosphorylation by Quenchbody: an antibody fragment that

       fluoresces upon antigen binding.

       Experimental Medicine, 2013; 31:194-200.  ISBN: 978-4-7581-0328-2.

 

7.    Jeong HJ, Adhya M, Park HM, Kim YG, and Kim BG.

       Detection of hanganutziu-deicher antigens in O-glycans from pig heart tissues by matrix-assisted laser

       desorption/ionization time-of-flight mass spectrometry.

       Xenotransplantation, 2013; 20:407-17. 

 

8.    Park HM, Park JK, Kim YW, Kim KJ, Jeong HJ, Jang KS, Kim BG, and Kim YG.

       The xeno-glycomics database (XDB): a relational database of qualitative and quantitative pig glycome repertoire.

       Bioinformatics, 2013; 29:2950-2. 

 

9.    Abe R, Jeong HJ, Arakawa D, Dong J, Ohashi H, Kaigome R, Saiki F, Yamane K, Takagi H, and Ueda H.

       Ultra Q-bodies: quench-based antibody probes that utilize dye-dye interactions with enhanced antigen-

       dependent fluorescence.

       Sci Rep, 2014; 4:4640. 

 

10.   Jeong HJ, Park HM, Kim KJ, Kim YW, Bhatia SK, Lee YK, Yang YH, Kim BG, and Kim YG.

        Highly sensitive glycosylation analysis of membrane glycoproteins avoiding polymeric contaminants.

        Biotechnol Bioproc Eng, 2014; 19:545-50. 

 

11.   Jeong HJ and Ueda H.

        Strategy for making a superior Quenchbody to proteins: effect of the position of fluorophore.

        Sensors, 2014; 14:13285-97. 

 

12.   Jeong HJ, Itayama S, and Ueda H.

        A signal-on fluorosensor based on quench-release principle for sensitive detection of antibiotic rapamycin.

        Biosensors, 2015; 5:131-40. 

 

13.   Jeong HJ.

        Recent trends in antibody engineering.

        BRIC View 2015-T018, Non-peer reviewed scientific report.

 

14.   Dong J, Jeong HJ, and Ueda H.

        Preparation of Quenchbodies by protein transamination reaction.

        J Biosci Bioeng, 2016; 122: 125-30. 

 

15.   Jeong HJ, Kawamura T, Dong J, and Ueda H.

        Q-bodies from recombinant single chain Fv fragment with better yield and expanded palette of fluorophores.

        ACS Sens, 2016; 1: 88-94. 

 

16.   Jeong HJ.

        Innovative genome editing using CRIPSPR/Cas9 and its ethical consideration.

        BRIC View 2016-T02, Non-peer reviewed scientific report.

 

17.   Ohashi H, Matsumoto T, Jeong HJ, Dong J, Abe R, and Ueda H.

        Insight into the working mechanism of Quenchbody: Transition of the dye around antibody variable regions that

        fluoresces upon antigen binding.

        Bioconj Chem, 2016; 27: 2248-53.

 

18.   Ueda H, Dong J, Jeong HJ, Abe R.

        Q-body as a neobiomolecule.

        Seibutsu-Kogaku Kaishi, 2016; 94: 488-91.

 

19.   Jeong HJ.

        English-Korean translation "CRISPR-Based Technologies for the Maniplation of Eukaryotic Genomes".

        BRIC View 2017-R13.

 

20.   Jeong HJ, Kojima T, Dong J, and Ueda H.

        One-pot construction of Quenchbodies using antibody binding proteins.

        Anal Methods, 2016; 8: 7774-9.

 

21.   Jeong HJ, Matsumoto K, Itayama S, Abe R, Dong J, Shindo M, and Ueda H.

        Construction of dye stapled Quenchbody by photochemical crosslinking to antibody nucleotide-binding site. 

        Chem Comm, 2017; 53: 10200-3.

 

22.   Jeong HJ, Kawamura T, Iida M, Kawahigashi Y, Takigawa M, Chung CI, Dong J, Kondoh M, and Ueda H.

        Development of a Quenchbody for the detection and imaging of the cancer-related tight-junction associated

        membrane protein claudin.

        Anal Chem, 2017; 89: 10783-9.

 

23.   Jeong HJ, Abhiraman G, Craig S, Ingram J, and Dougan S.

        Generation of Ca2+-independent SortaseA mutants with enhanced activity for protein and cell surface labeling.

        PLoS One, 2017; 12: e0189068.


24.   Jeong HJ.

        The pros and cons of genome editing.

        BRIC View 2018-RXX, Non-peer reviewed scientific report.

 

25.   Dougan M, Ingram J, Jeong HJ, Mosaheb M, Bruck P, Ali L, Pishesha N, Blomberg O, Tyler P, Servos M,

        Rashidian M, Nguyen QD, Andrian U, Ploegh H, and Dougan S.

        Targeting cytokine therapy to the pancreatic tumor microenvironment using PD-L1 specific VHHs.

        Cancer Immunology Research, 2018.

 

 

 

 

 

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