Dmitry Bandura

From Wikitia
Jump to navigation Jump to search
Dmitry Bandura
Add a Photo
NationalityCanadian
CitizenshipCanada
OccupationScientist

Dmitry Bandura is a Soviet born Canadian scientist and is one of the original co-inventors of mass cytometry technology[1]. Dr. Bandura co-founded DVS Sciences[2] in 2004 (acquired by Fluidigm in 2014 and then renamed to Standard BioTools in 2022[3]) along with ,Vladimir Baranov Scott D. Tanner and Olga Ornatsky.

Biography

At the end of 1992 Dmitry emigrated to Australia[4] and worked as a Research Physicist at GBC Scientific Equipment in Melbourne until 1998, carrying out research and development in Inductively Coupled Plasma Mass Spectrometry. The product of the research was introduced in March 1998 as Optimass 8000 ICP-TOF_MS, which won the R&D 100 new product award in Analytical instrumentation for 1998.

In 1998 Dmitry moved to Canada to join MDS SCIEX, where he worked as a Senior Research Scientist in research and development of new ICP-MS instrumentation (1998-2005) and lead the ICP-MS research (2004-2005)

In 2005, together with Scott D. Tanner and Vladimir Baranov, Dmitry left MDS SCIEX to pursue independent development of ICP-TOF-MS based Cytometer and became a Research Associate at IBBME,[4] at the University of Toronto, with recent reappointment in the Department of Chemistry (2008). Dmitry has a special interest in plasma dynamics, gas-phase ion-molecule chemistry, ion generation and detection process, and time-of-flight mass spectrometry. His objectives are to initiate, develop and implement new approaches and technologies in analytical instrumentation.

At Standard BioTools (formerly Fluidigm, formerly DVS Sciences), he oversaw the research and development of all mass cytometry products and intellectual property assets.[4]

Education

  • M.Sc. In Engineering in Physics at Moscow Engineering Physics Institute - 1985.[4]
  • PH.D in Technical Sciences at the Department of Physics - 1992.[4]
  • Thesis work related to the development of instruments and methods of elememtal analysis of hypervelocity micro-particles via mas spectrometry of impact-induced plasma (Sup .Prof A.A. Sysoev)[4]

Career

  • Senior Research Scientist at MDS Sciex Canada - 1998.[4]
  • Vice President, Research and Development at DVS Sciences[5] - 2005
    (acquired by Fluidigm in 2014 and then Standard BioTools in 2022)

Research

  • Development of the DRC Collision/reaction cell
  • Mass cytometry (CyTOF)[6]

Book

Awards and honors

  • 2019 HUPO Award (Human Proteome Organization)[7]
  • 1998 R&D World 100 Winners[8] in Analytical instrumentation for the GBC Optimass 8000.

Publications

  • Aug 2014 Metal-chelating polymers developed for mass cytometry as a potential route to high activity radioimmunotherapeutic agents[9]
  • April 2013 An introduction to mass cytometry: Fundamentals and applications[10]
  • Nov 2011 MASSIVELY MULTIPARAMETER SINGLE CELL ANALYSIS BY MASS CYTOMETRY[11]
  • Sept 2010 Highly multiparametric analysis by mass cytometry[12]
  • Feb 2010 Metal-Containing Polystyrene Beads as Standards for Mass Cytometry[13]
  • Feb 2010 Bio-Functional, Lanthanide-Labeled Polymer Particles by Seeded Emulsion Polymerization and their Characterization by Novel ICP-MS Detection[14]
  • Feb 2010 Lanthanide-Containing Polymer Microspheres by Multiple-Stage Dispersion Polymerization for Highly Multiplexed Bioassays[15]
  • July 2009 Mass Cytometry: Technique for Real Time Single Cell Multitarget Immunoassay Based on Inductively Coupled Plasma Time-of-Flight Mass Spectrometry
  • Mar 2009 Collision and Reaction Cells
  • Dec 2008 Flow cytometer with mass spectrometer detection for massively multiplexed single-cell biomarker assay
  • May 2008 Study of Cell Antigens and Intracellular DNA by Identification of Element-Containing Labels and Metallointercalators Using Inductively Coupled Plasma Mass Spectrometry
  • Feb 2008 Development of analytical methods for multiplex bio-assay with inductively coupled plasma mass spectrometry
  • Oct 2007 Determination of Fe, Ni, Co, Cu and Zn in high-Ca samples using methane as a reaction cell gas
  • Mar 2007 Multiplex bio-assay with inductively coupled plasma mass spectrometry: Towards a massively multivariate single-cell technology
  • Jan 2007 New challenges for ICP-MS instrumentation and data acquisition. Solving problems of real life biology
  • Jan 2007 Quantitation of phosphorus in biologically active materials by ICP-MS detection of P and S with chemical resolution
  • Sept 2006 Messenger RNA Detection in Leukemia Cell lines by Novel Metal-Tagged in situ Hybridization using Inductively Coupled Plasma Mass Spectrometry
  • Sept 2006 Gas-phase ion–molecule reactions for resolution of atomic isobars: AMS and ICP-MS perspectives
  • Mar 2006 Multiplex Biomarker Detection by ICP‐MS
  • Feb 2006 Multiple cellular antigen detection by ICP-MS
  • Dec 2005 Limitations of the effective potential for the evaluation of the ion energy in the RF-driven quadrupole field
  • Jul 2004 Chemical Resolution of Pu + from U + and Am + Using a Band-Pass Reaction Cell Inductively Coupled Plasma Mass Spectrometer
  • Jan 2004 Characterization of phosphorus content of biological samples by ICP-DRC-MS: Potential tool for cancer research
  • Jan 2003 New challenges for ICP-MS instrumentation and data acquisition. Solving problems of real life biology
  • Oct 2002 Inductively coupled plasma mass spectrometer with axial field in a quadrupole reaction cell
  • Sept 2002 The potential for elemental analysis in biotechnology
  • Sept 2002 Reaction cells and collision cells for ICP-MS: A tutorial review
  • May 2002 Detection of Ultratrace Phosphorus and Sulfur by Quadrupole ICPMS with Dynamic Reaction Cell
  • May 2002 A Sensitive and Quantitative Element-Tagged Immunoassay with ICPMS Detection
  • Sept 2001 Elimination of isobaric interferences in ICP-MS, using ion?molecule reaction chemistry: Rb/Sr age determination of magmatic rocks, a case study
  • July 2001 Reaction chemistry and collisional processes in multiple devices for resolving isobaric interferences in ICP-MS
  • Jan 2001 Ion-molecule chemistry solutions to the ICP-MS analytical challenges
  • Jan 2000 A novel inductively coupled plasma/selected-ion flow tube mass spectrometer for the study of reactions of atomic and atomic oxide ions
  • Jan 2000 Effect of collisional damping and reactions in a dynamic reaction cell on the precision of isotope ratio measurements
  • Mar 1999 Effect of Collisional Damping in the Dynamic Reaction Cell on the Precision of Isotope Ratio Measurements
  • Aug 1993 Time-of-flight mass reflection with a large area of collision
  • July 1993 A transit-time analyzer for determining the elemental composition of space dust particles
  • Mar 1991 Energy and angular characteristics of ions emitted as a result of the impact of accelerated particles against a target
  • Systems immunology (WS-086) WS/PP-086-01 What is “Systems Immunology” for? WS/PP-086-02 Cholinergic stimulation modulates T cell-independent humoral immune responses in the spleenWS/PP-086-03 Next-generation 31-parameter flow cytometry reveals systems-level relationships in human bone marrow signaling and homeostasisWS/PP-086-04 Organization of the autoantibody repertoire in healthy newborns and adults revealed by system level informatics of antigen microarray dataWS/PP-086-05 Methods for develo
  • Systems immunology (WS-086) WS/PP-086-01 What is “Systems Immunology” for? WS/PP-086-02 Cholinergic stimulation modulates T cell-independent humoral immune responses in the spleenWS/PP-086-03 Next-generation 31-parameter flow cytometry reveals systems-level relationships in human bone marrow signaling and homeostasisWS/PP-086-04 Organization of the autoantibody repertoire in healthy newborns and adults revealed by system level informatics of antigen microarray dataWS/PP-086-05 Methods for de

References

  1. "US Patent 7,135,296". Google Patents. Google. 2000-12-28. Retrieved 6 December 2022.
  2. "Co-Founder of DVS Sciences". MaRSdd.com. 2011.
  3. "Fluidigm Renamed to Stanard BioTools". Globenewswirel. 2022-04-04. Retrieved 9 December 2022.
  4. 4.0 4.1 4.2 4.3 4.4 4.5 4.6 4.7 "Dmitry Bandura Biography". Archive.org. 2009.
  5. "Vice President, Research and Development". Archive.org. 2014.
  6. Dmitry Bandura; Vladimir Baranov; Olga Ornatsky; Scott D. Tanner; Antonov A; Kinach R; Lou X; Pavlov S; Vorobiev S; Dick JE (August 2009). "Mass cytometry: technique for real time single cell multitarget immunoassay based on inductively coupled plasma time-of-flight mass spectrometry". Analytical Chemistry. 81 (16): 6813–22. doi:10.1021/ac901049w. PMID 19601617.
  7. "HUPO Awards - 2019 RECIPIENTS". HUPO. 2019.
  8. "R&D World 100 Winners - GBC Optimass 8000". 1998.
  9. "Metal-chelating polymers developed for mass cytometry as a potential route to high activity radioimmunotherapeutic agents". ReserchGate.net. 2014.
  10. "An introduction to mass cytometry: Fundamentals and applications". NIH.gov. 2013.
  11. "MASSIVELY MULTIPARAMETER SINGLE CELL ANALYSIS BY MASS CYTOMETRY". ResearchGate.net. 2011.
  12. "Highly multiparametric analysis by mass cytometry". NIH.gov. 2010.
  13. "Metal-Containing Polystyrene Beads as Standards for Mass Cytometry". NIH.gov. 2010.
  14. "Bio-Functional, Lanthanide-Labeled Polymer Particles by Seeded Emulsion Polymerization and their Characterization by Novel ICP-MS Detection". NIH.gov. 2010.
  15. "Lanthanide-Containing Polymer Microspheres by Multiple-Stage Dispersion Polymerization for Highly Multiplexed Bioassays". NIH.gov. 2010.

External links

Add External links

This article "Dmitry Bandura" is from Wikipedia. The list of its authors can be seen in its historical. Articles taken from Draft Namespace on Wikipedia could be accessed on Wikipedia's Draft Namespace.

Retrieved from "https://wikitia.com/index.php?title=Dmitry_Bandura&oldid=163629"