Title :
Quantifying viscoelastic behavior of DNA-laden flows in microfluidic systems
Author :
Gulati, Shelly ; Muller, Susan ; Liepmann, Dorian
Author_Institution :
Joint Graduate Group in Bioeng., California Univ., Berkeley, CA, USA
Abstract :
Fully integrated lab-on-a-chip systems for applications such as DNA sequencing and pathogen detection will incorporate significant microfluidic components. These systems will necessarily require the flow of large molecules such as DNA, which give the bulk fluid viscoelastic behavior. Additionally, the contour lengths of these molecules L, will approach those of the fluid channel h (L/h∼0.25) presenting a unique flow situation that is not well understood. Flow visualization of dilute and semi-dilute lambda-DNA solution flows through a gradual contraction device is used to characterize the viscoelastic behavior. Deviations from Newtonian flow fields brought about by the viscoelastic fluid rheology and concentration effects are assessed.
Keywords :
DNA; biological techniques; flow visualisation; microfluidics; microorganisms; molecular biophysics; non-Newtonian flow; DNA sequencing; DNA-laden flow; Newtonian flow field; concentration effect; flow visualization; fluid channel; lab-on-a-chip system; lambda-DNA solution flow; microfluidic component; microfluidic system; pathogen detection; planar contraction device; viscoelastic behavior; viscoelastic fluid rheology; Biomedical engineering; DNA; Elasticity; Geometry; Lab-on-a-chip; Microfluidics; Polymers; Rheology; Viscosity; Visualization; DPIV; lab-on-a-chip; microfluidics; planar contractions; viscoelasticity;
Conference_Titel :
Microtechnology in Medicine and Biology, 2005. 3rd IEEE/EMBS Special Topic Conference on
Print_ISBN :
0-7803-8711-2
DOI :
10.1109/MMB.2005.1548449
