INTRODUCTION: A robust, versatile and compact microreactor has been designed, fabricated and tested for the labeling of bifunctional chelate conjugated biomolecules (BFC-BM) with PET radiometals. METHODS: The developed microreactor was used to radiolabel a chelate, either 1,4,7,10-tetraazacyclododecane-1,4,7,10-tetraacetic acid (DOTA) or 1,4,7-triazacyclononane-1,4,7-triacetic acid (NOTA) that had been conjugated to cyclo(Arg-Gly-Asp-DPhe-Lys) peptide, with both ⁶⁴Cu and ⁶⁸Ga respectively. The microreactor radiolabeling conditions were optimized by varying temperature, concentration and residence time. RESULTS: Direct comparisons between the microreactor approach and conventional methods showed improved labeling yields and increased reproducibility with the microreactor under identical labeling conditions, due to enhanced mass and heat transfer at the microscale. More importantly, over 90% radiolabeling yields (incorporation of radiometal) were achieved with a 1:1 stoichiometry of bifunctional chelate biomolecule conjugate (BFC-BM) to radiometal in the microreactor, which potentially obviates extensive chromatographic purification that is typically required to remove the large excess of unlabeled biomolecule in radioligands prepared using conventional methods. Moreover, higher yields for radiolabeling of DOTA-functionalized BSA protein (Bovine Serum Albumin) were observed with ⁶⁴Cu/⁶⁸Ga using the microreactor, which demonstrates the ability to label both small and large molecules. CONCLUSIONS: A robust, reliable, compact microreactor capable of chelating radiometals with common chelates has been developed and validated. Based on our radiolabeling results, the reported microfluidic approach overall outperforms conventional radiosynthetic methods, and is a promising technology for the radiometal labeling of commonly utilized BFC-BM in aqueous solutions.
INTRODUCTION: A robust, versatile and compact microreactor has been designed, fabricated and tested for the labeling of bifunctional chelate conjugated biomolecules (BFC-BM) with PET radiometals. METHODS: The developed microreactor was used to radiolabel a chelate, either 1,4,7,10-tetraazacyclododecane-1,4,7,10-tetraacetic acid (DOTA) or 1,4,7-triazacyclononane-1,4,7-triacetic acid (NOTA) that had been conjugated to cyclo(Arg-Gly-Asp-DPhe-Lys) peptide, with both ⁶⁴Cu and ⁶⁸Ga respectively. The microreactor radiolabeling conditions were optimized by varying temperature, concentration and residence time. RESULTS: Direct comparisons between the microreactor approach and conventional methods showed improved labeling yields and increased reproducibility with the microreactor under identical labeling conditions, due to enhanced mass and heat transfer at the microscale. More importantly, over 90% radiolabeling yields (incorporation of radiometal) were achieved with a 1:1 stoichiometry of bifunctional chelate biomolecule conjugate (BFC-BM) to radiometal in the microreactor, which potentially obviates extensive chromatographic purification that is typically required to remove the large excess of unlabeled biomolecule in radioligands prepared using conventional methods. Moreover, higher yields for radiolabeling of DOTA-functionalized BSA protein (Bovine Serum Albumin) were observed with ⁶⁴Cu/⁶⁸Ga using the microreactor, which demonstrates the ability to label both small and large molecules. CONCLUSIONS: A robust, reliable, compact microreactor capable of chelating radiometals with common chelates has been developed and validated. Based on our radiolabeling results, the reported microfluidic approach overall outperforms conventional radiosynthetic methods, and is a promising technology for the radiometal labeling of commonly utilized BFC-BM in aqueous solutions.
Authors: Abraham D Stroock; Stephan K W Dertinger; Armand Ajdari; Igor Mezic; Howard A Stone; George M Whitesides Journal: Science Date: 2002-01-25 Impact factor: 47.728
Authors: Kan Liu; Eric J Lepin; Ming-Wei Wang; Feng Guo; Wei-Yu Lin; Yi-Chun Chen; Shannon J Sirk; Sebastian Olma; Michael E Phelps; Xing-Zhong Zhao; Hsian-Rong Tseng; R Michael van Dam; Anna M Wu; Clifton K-F Shen Journal: Mol Imaging Date: 2011-06 Impact factor: 4.488
Authors: Xiaobing Tian; Atis Chakrabarti; Nariman V Amirkhanov; Mohan R Aruva; Kaijun Zhang; Boby Mathew; Christopher Cardi; Wenyi Qin; Edward R Sauter; Mathew L Thakur; Eric Wickstrom Journal: Ann N Y Acad Sci Date: 2005-11 Impact factor: 5.691
Authors: Tobias D Wheeler; Dexing Zeng; Amit V Desai; Birce Önal; David E Reichert; Paul J A Kenis Journal: Lab Chip Date: 2010-10-12 Impact factor: 6.799
Authors: Min Hwan Kim; Sang-Keun Woo; Kwang Il Kim; Tae Sup Lee; Chan Wha Kim; Joo Hyun Kang; Byung Il Kim; Sang Moo Lim; Kyo Chul Lee; Yong Jin Lee Journal: ACS Med Chem Lett Date: 2015-04-07 Impact factor: 4.345
Authors: Philip H Chao; Jeffery Collins; Joseph P Argus; Wei-Yu Tseng; Jason T Lee; R Michael van Dam Journal: Lab Chip Date: 2017-05-16 Impact factor: 6.799
Authors: Joseph M Castellano; Kira I Mosher; Rachelle J Abbey; Alisha A McBride; Michelle L James; Daniela Berdnik; Jadon C Shen; Bende Zou; Xinmin S Xie; Martha Tingle; Izumi V Hinkson; Martin S Angst; Tony Wyss-Coray Journal: Nature Date: 2017-04-19 Impact factor: 49.962
Authors: Hairong Li; Haiying Zhou; Stephanie Krieger; Jesse J Parry; Joseph J Whittenberg; Amit V Desai; Buck E Rogers; Paul J A Kenis; David E Reichert Journal: Bioconjug Chem Date: 2014-04-04 Impact factor: 4.774
Authors: Christopher Frank; Georg Winter; Fredrik Rensei; Victor Samper; Allen F Brooks; Brian G Hockley; Bradford D Henderson; Christian Rensch; Peter J H Scott Journal: EJNMMI Radiopharm Chem Date: 2019-09-18