Sort by
Refine Your Search
-
Listed
-
Category
-
Country
-
Program
-
Field
-
, and Jason Widegren https://www.nist.gov/programs-projects/electric-acoustic-spectroscopy-intermolecular-interactions-solution#OnChip NIST’s Material Measurement Laboratory (MML) and Communications
-
antimicrobial strategies, lipid membrane platforms, membrane-active compounds, antibacterial and antiviral applications, plant-based bio-material applications, etc. For more details, please view https
-
and compartmentalization. ESPCI will contribute to the in vitro compartmentalization of autocatalytic and metabolic system in emulsion droplets and coacervate droplets using microfluidic systems
-
vitro and in vivo using methods such as fluorescence microscopy and microfluidic sorting systems. Apply these RNA devices to control gene expression of metabolic pathways and determine improvements in
-
-PCR/RT-qPCR, and general bacterial genetics techniques. The use of microfluidic devices to analyze gene expression in in vitro grown biofilm communities. Identifying components of innate immunity and
-
of gels with different swelling responses. Specific tasks include: - Perform experimental work on microfluidics and soft condensed matter. - Analysize data. - Use theoretical models to rationalize data
-
vitro and in vivo using methods such as fluorescence microscopy and microfluidic sorting systems. Apply these RNA devices to control gene expression of metabolic pathways and determine improvements in
-
vitro and in vivo using methods such as fluorescence microscopy and microfluidic sorting systems. Apply these RNA devices to control gene expression of metabolic pathways and determine improvements in
-
. More information can be found on this website: http://nanobio.tamu.edu Responsibilities: Perform research in microfluidics, lab-on-a-chip, and organ-on-a-chip systems in the NanoBio Systems Laboratory
-
hydrogel-based biomimetic matrices (notably GelMA) to support the generation, maturation and functional optimization of multicellular adipose organoids, and integrate them into microfluidic platforms