Search research articles
Contact Us
Filters
Showing results (1-10 of 31) with videos related to
Page
of 4
Sort By:
Lab on a Chip
|
May 7, 2013
Programmable and automated bead-based microfluidics for versatile DNA microarrays under isothermal conditions
Robert Penchovsky
ACS Synthetic Biology
|
May 10, 2013
Engineering integrated digital circuits with allosteric ribozymes for scaling up molecular computation and diagnostics
Robert Penchovsky
Biomacromolecules
|
March 5, 2013
Computational design and biosensor applications of small molecule-sensing allosteric ribozymes
Robert Penchovsky
Biosensors & Bioelectronics
|
April 17, 2019
Automated DNA hybridization transfer with movable super-paramagnetic microbeads in a microflow reactor
Robert Penchovsky
Biotechnology Advances
|
June 1, 2014
Computational design of allosteric ribozymes as molecular biosensors
Robert Penchovsky
Antibiotics (Basel, Switzerland)
|
September 23, 2022
Bioinformatics and Genomic Analyses of the Suitability of Eight Riboswitches for Antibacterial Drug Targets
Nikolet Pavlova, Robert Penchovsky
Antibiotics (Basel, Switzerland)
|
November 24, 2022
Targeting SAM-I Riboswitch Using Antisense Oligonucleotide Technology for Inhibiting the Growth of <i>Staphylococcus aureus</i> and <i>Listeria monocytogenes</i>
Martina Traykovska, Robert Penchovsky
Expert Opinion on Therapeutic Targets
|
May 14, 2019
Genome-wide bioinformatics analysis of FMN, SAM-I, glmS, TPP, lysine, purine, cobalamin, and SAH riboswitches for their applications as allosteric antibacterial drug targets in human pathogenic bacteria
Nikolet Pavlova, Robert Penchovsky
Journal of Computational Biology : a Journal of Computational Molecular Cell Biology
|
June 14, 2003
DNA library design for molecular computation
Robert Penchovsky, Jörg Ackermann
ACS Synthetic Biology
|
April 20, 2022
Engineering Antisense Oligonucleotides as Antibacterial Agents That Target FMN Riboswitches and Inhibit the Growth of <i>Staphylococcus aureus</i>, <i>Listeria monocytogenes</i>, and <i>Escherichia coli</i>
Martina Traykovska, Robert Penchovsky
Page
of 4
Search research articles
Search
Showing results (1-10 of 31) with videos related to
Sort By:
Page
of 4
Lab on a Chip
|
May 7, 2013
Programmable and automated bead-based microfluidics for versatile DNA microarrays under isothermal conditions
Robert Penchovsky
ACS Synthetic Biology
|
May 10, 2013
Engineering integrated digital circuits with allosteric ribozymes for scaling up molecular computation and diagnostics
Robert Penchovsky
Biomacromolecules
|
March 5, 2013
Computational design and biosensor applications of small molecule-sensing allosteric ribozymes
Robert Penchovsky
Biosensors & Bioelectronics
|
April 17, 2019
Automated DNA hybridization transfer with movable super-paramagnetic microbeads in a microflow reactor
Robert Penchovsky
Biotechnology Advances
|
June 1, 2014
Computational design of allosteric ribozymes as molecular biosensors
Robert Penchovsky
Antibiotics (Basel, Switzerland)
|
September 23, 2022
Bioinformatics and Genomic Analyses of the Suitability of Eight Riboswitches for Antibacterial Drug Targets
Nikolet Pavlova, Robert Penchovsky
Antibiotics (Basel, Switzerland)
|
November 24, 2022
Targeting SAM-I Riboswitch Using Antisense Oligonucleotide Technology for Inhibiting the Growth of <i>Staphylococcus aureus</i> and <i>Listeria monocytogenes</i>
Martina Traykovska, Robert Penchovsky
Expert Opinion on Therapeutic Targets
|
May 14, 2019
Genome-wide bioinformatics analysis of FMN, SAM-I, glmS, TPP, lysine, purine, cobalamin, and SAH riboswitches for their applications as allosteric antibacterial drug targets in human pathogenic bacteria
Nikolet Pavlova, Robert Penchovsky
Journal of Computational Biology : a Journal of Computational Molecular Cell Biology
|
June 14, 2003
DNA library design for molecular computation
Robert Penchovsky, Jörg Ackermann
ACS Synthetic Biology
|
April 20, 2022
Engineering Antisense Oligonucleotides as Antibacterial Agents That Target FMN Riboswitches and Inhibit the Growth of <i>Staphylococcus aureus</i>, <i>Listeria monocytogenes</i>, and <i>Escherichia coli</i>
Martina Traykovska, Robert Penchovsky
Page
of 4