15 research outputs found
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Deterministic Separation of Cancer Cells from Blood at 10 mL/min
Circulating tumor cells (CTCs) and circulating clusters of cancer and stromal cells have been identified in the blood of patients with malignant cancer and can be used as a diagnostic for disease severity, assess the efficacy of different treatment strategies and possibly determine the eventual location of metastatic invasions for possible treatment. There is thus a critical need to isolate, propagate and characterize viable CTCs and clusters. Here, we present a microfluidic device for mL/min flow rate, continuous-flow capture of viable CTCs from blood using deterministic lateral displacement arrays. We show here that a deterministic bump array can be designed such that it will isolate with efficiency greater than 85% CTCs over a large range in sizes from millimeter volume clinical blood samples in minutes, with no effect on cell vitality so that further culturing and analysis of the cells can be carried out
Anisotropic permeability in deterministic lateral displacement arrays
We uncover anisotropic permeability in microfluidic deterministic lateral
displacement (DLD) arrays. A DLD array can achieve high-resolution bimodal
size-based separation of microparticles, including bioparticles, such as cells.
For an application with a given separation size, correct device operation
requires that the flow remains at a fixed angle to the obstacle array. We
demonstrate via experiments and lattice-Boltzmann simulations that subtle array
design features cause anisotropic permeability. Anisotropic permeability
indicates the microfluidic array's intrinsic tendency to induce an undesired
lateral pressure gradient. This can cause an inclined flow and therefore local
changes in the critical separation size. Thus, particle trajectories can become
unpredictable and the device useless for the desired separation task.
Anisotropy becomes severe for arrays with unequal axial and lateral gaps
between obstacle posts and highly asymmetric post shapes. Furthermore, of the
two equivalent array layouts employed with the DLD, the rotated-square layout
does not display intrinsic anisotropy. We therefore recommend this layout over
the easier-to-implement parallelogram layout. We provide additional guidelines
for avoiding adverse effects of anisotropy on the DLD.Comment: 13 pages, 10 figures, 1 table, DLD, particle separation,
microfluidics, anisotropic permeabilit
Microfluidic Devices for High Throughput Cell Sorting and Chemical Treatment
Separation by size is a fundamental analytical and preparative technique in biology, medicine, and chemistry. Deterministic lateral displacement (DLD) arrays are microfluidic devices capable of high-precision particle sorting based on size. In this thesis, we will discuss improvements in the functionality of DLD arrays and several new applications. We'll rst discuss a methodology for performing sequential on-chip chemical treatment by using the DLD array to direct particles in the "bumping" trajectory across co-flowing reagent streams and demonstrates this technique with platelet labeling and washing and E. Coli lysis and chromosomal separation. We then discuss a deterministic microfluidic ratchet that could separate particles in an intermediate size range using a DLD array with triangular posts in an oscillating flow. We then extended this idea of using triangular posts in DLD arrays to continuous-flow operation and showed signicant performance enhancements over arrays with circular posts when the triangle vertex is used as the displacement edge. Taking this idea of increasing device throughput to the next step, we developed a highly parallelized DLD array architecture for processing macroscopic fluid volumes by operating many arrays in parallel and showed flow rates on the order of 10 mL/min with a single-layer device and applied these high throughput DLD arrays to isolating viable circulating tumor cells from blood and dewatering algae for biofuel production
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Microfluidic approaches to synchrotron radiation-based Fourier transform infrared (SR-FTIR) spectral microscopy of living biosystems.
A long-standing desire in biological and biomedical sciences is to be able to probe cellular chemistry as biological processes are happening inside living cells. Synchrotron radiation-based Fourier transform infrared (SR-FTIR) spectral microscopy is a label-free and nondestructive analytical technique that can provide spatiotemporal distributions and relative abundances of biomolecules of a specimen by their characteristic vibrational modes. Despite great progress in recent years, SR-FTIR imaging of living biological systems remains challenging because of the demanding requirements on environmental control and strong infrared absorption of water. To meet this challenge, microfluidic devices have emerged as a method to control the water thickness while providing a hospitable environment to measure cellular processes and responses over many hours or days. This paper will provide an overview of microfluidic device development for SR-FTIR imaging of living biological systems, provide contrast between the various techniques including closed and open-channel designs, and discuss future directions of development within this area. Even as the fundamental science and technological demonstrations develop, other ongoing issues must be addressed; for example, choosing applications whose experimental requirements closely match device capabilities, and developing strategies to efficiently complete the cycle of development. These will require imagination, ingenuity and collaboration
Microfluidic approaches to synchrotron radiation-based Fourier transform infrared (SR-FTIR) spectral microscopy of living biosystems
A long-standing desire in biological and biomedical sciences is to be able to probe cellular chemistry as biological processes are happening inside living cells. Synchrotron radiation-based Fourier transform infrared (SR-FTIR) spectral microscopy is a label-free and nondestructive analytical technique that can provide spatiotemporal distributions and relative abundances of biomolecules of a specimen by their characteristic vibrational modes. Despite great progress in recent years, SR-FTIR imaging of living biological systems remains challenging because of the demanding requirements on environmental control and strong infrared absorption of water. To meet this challenge, microfluidic devices have emerged as a method to control the water thickness while providing a hospitable environment to measure cellular processes and responses over many hours or days. This paper will provide an overview of microfluidic device development for SR-FTIR imaging of living biological systems, provide contrast between the various techniques including closed and open-channel designs, and discuss future directions of development within this area. Even as the fundamental science and technological demonstrations develop, other ongoing issues must be addressed; for example, choosing applications whose experimental requirements closely match device capabilities, and developing strategies to efficiently complete the cycle of development. These will require imagination, ingenuity and collaboration
Open-Channel Microfluidic Membrane Device for Long-Term FT-IR Spectromicroscopy of Live Adherent Cells
Spatially resolved infrared spectroscopy
is a label-free and nondestructive
analytical technique that can provide spatiotemporal information on
functional groups in biomolecules of a sample by their characteristic
vibrational modes. One difficulty in performing long-term FT-IR measurements
on live cells is the competition between the strong IR absorption
from water and the need to supply nutrients and remove waste. In this
proof of principle study, we developed an open-channel membrane device
that allows long-term continuous IR measurement of live, adherent
mammalian cells. Composed of a gold-coated porous membrane between
a feeding channel and a viewing chamber, it allows cells to be maintained
on the upper membrane surface in a thin layer of fluid while media
is replenished from the feeding channel below. Using this device,
we monitored the spatiotemporal chemical changes in living colonies
of PC12 cells under nerve growth factor (NGF) stimulation for up to
7 days using both conventional globar and high-resolution synchrotron
radiation-based IR sources. We identified the primary chemical change
cells undergo is an increase in glycogen that may be associated with
secretion of glycoprotein to protect the cells from evaporative stress
at the air–liquid interface. Analyzing the spectral maps with
multivariate methods of hierarchical cluster analysis (HCA) and principal
component analysis (PCA), we found that the cells at the boundary
of the colony and in a localized region in the center of the colony
tend to produce more glycogen and glycoprotein than cells located
elsewhere in the colony and that the degree of spatial heterogeneity
decreases with time. This method provides a promising approach for
long-term live-cell spectromicroscopy on mammalian cell systems
Cell motility and drug gradients in the emergence of resistance to chemotherapy.
The emergence of resistance to chemotherapy by cancer cells, when combined with metastasis, is the primary driver of mortality in cancer and has proven to be refractory to many efforts. Theory and computer modeling suggest that the rate of emergence of resistance is driven by the strong selective pressure of mutagenic chemotherapy and enhanced by the motility of mutant cells in a chemotherapy gradient to areas of higher drug concentration and lower population competition. To test these models, we constructed a synthetic microecology which superposed a mutagenic doxorubicin gradient across a population of motile, metastatic breast cancer cells (MDA-MB-231). We observed the emergence of MDA-MB-231 cancer cells capable of proliferation at 200 nM doxorubicin in this complex microecology. Individual cell tracking showed both movement of the MDA-MB-231 cancer cells toward higher drug concentrations and proliferation of the cells at the highest doxorubicin concentrations within 72 h, showing the importance of both motility and drug gradients in the emergence of resistance