4 research outputs found
Open-Top Patterned Hydrogel-Laden 3D Glioma Cell Cultures for Creation of Dynamic Chemotactic Gradients to Direct Cell Migration
The laminar flow profiles in microfluidic systems coupled
to rapid
diffusion at flow streamlines have been widely utilized to create
well-controlled chemical gradients in cell cultures for spatially
directing cell migration. However, within hydrogel-based closed microfluidic
systems of limited depth (≤0.1 mm), the biomechanical cues
for the cell culture are dominated by cell interactions with channel
surfaces rather than with the hydrogel microenvironment. Also, leaching
of poly(dimethylsiloxane) (PDMS) constituents in closed systems and
the adsorption of small molecules to PDMS alter chemotactic profiles.
To address these limitations, we present the patterning and integration
of a PDMS-free open fluidic system, wherein the cell-laden hydrogel
directly adjoins longitudinal channels that are designed to create
chemotactic gradients across the 3D culture width, while maintaining
uniformity across its ∼1 mm depth to enhance cell–biomaterial
interactions. This hydrogel-based open fluidic system is assessed
for its ability to direct migration of U87 glioma cells using a hybrid
hydrogel that includes hyaluronic acid (HA) to mimic the brain tumor
microenvironment and gelatin methacrylate (GelMA) to offer the adhesion
motifs for promoting cell migration. Chemotactic gradients to induce
cell migration across the hydrogel width are assessed using the chemokine
CXCL12, and its inhibition by AMD3100 is validated. This open-top
hydrogel-based fluidic system to deliver chemoattractant cues over
square-centimeter-scale areas and millimeter-scale depths can potentially
serve as a robust screening platform to assess emerging glioma models
and chemotherapeutic agents to eradicate them
Open-Top Patterned Hydrogel-Laden 3D Glioma Cell Cultures for Creation of Dynamic Chemotactic Gradients to Direct Cell Migration
The laminar flow profiles in microfluidic systems coupled
to rapid
diffusion at flow streamlines have been widely utilized to create
well-controlled chemical gradients in cell cultures for spatially
directing cell migration. However, within hydrogel-based closed microfluidic
systems of limited depth (≤0.1 mm), the biomechanical cues
for the cell culture are dominated by cell interactions with channel
surfaces rather than with the hydrogel microenvironment. Also, leaching
of poly(dimethylsiloxane) (PDMS) constituents in closed systems and
the adsorption of small molecules to PDMS alter chemotactic profiles.
To address these limitations, we present the patterning and integration
of a PDMS-free open fluidic system, wherein the cell-laden hydrogel
directly adjoins longitudinal channels that are designed to create
chemotactic gradients across the 3D culture width, while maintaining
uniformity across its ∼1 mm depth to enhance cell–biomaterial
interactions. This hydrogel-based open fluidic system is assessed
for its ability to direct migration of U87 glioma cells using a hybrid
hydrogel that includes hyaluronic acid (HA) to mimic the brain tumor
microenvironment and gelatin methacrylate (GelMA) to offer the adhesion
motifs for promoting cell migration. Chemotactic gradients to induce
cell migration across the hydrogel width are assessed using the chemokine
CXCL12, and its inhibition by AMD3100 is validated. This open-top
hydrogel-based fluidic system to deliver chemoattractant cues over
square-centimeter-scale areas and millimeter-scale depths can potentially
serve as a robust screening platform to assess emerging glioma models
and chemotherapeutic agents to eradicate them
Open-Top Patterned Hydrogel-Laden 3D Glioma Cell Cultures for Creation of Dynamic Chemotactic Gradients to Direct Cell Migration
The laminar flow profiles in microfluidic systems coupled
to rapid
diffusion at flow streamlines have been widely utilized to create
well-controlled chemical gradients in cell cultures for spatially
directing cell migration. However, within hydrogel-based closed microfluidic
systems of limited depth (≤0.1 mm), the biomechanical cues
for the cell culture are dominated by cell interactions with channel
surfaces rather than with the hydrogel microenvironment. Also, leaching
of poly(dimethylsiloxane) (PDMS) constituents in closed systems and
the adsorption of small molecules to PDMS alter chemotactic profiles.
To address these limitations, we present the patterning and integration
of a PDMS-free open fluidic system, wherein the cell-laden hydrogel
directly adjoins longitudinal channels that are designed to create
chemotactic gradients across the 3D culture width, while maintaining
uniformity across its ∼1 mm depth to enhance cell–biomaterial
interactions. This hydrogel-based open fluidic system is assessed
for its ability to direct migration of U87 glioma cells using a hybrid
hydrogel that includes hyaluronic acid (HA) to mimic the brain tumor
microenvironment and gelatin methacrylate (GelMA) to offer the adhesion
motifs for promoting cell migration. Chemotactic gradients to induce
cell migration across the hydrogel width are assessed using the chemokine
CXCL12, and its inhibition by AMD3100 is validated. This open-top
hydrogel-based fluidic system to deliver chemoattractant cues over
square-centimeter-scale areas and millimeter-scale depths can potentially
serve as a robust screening platform to assess emerging glioma models
and chemotherapeutic agents to eradicate them
Correlating Antibiotic-Induced Dysbiosis to <i>Clostridioides difficile</i> Spore Germination and Host Susceptibility to Infection Using an <i>Ex Vivo</i> Assay
Antibiotic-induced microbiota disruption and its persistence
create
conditions for dysbiosis and colonization by opportunistic pathogens,
such as those causing Clostridioides difficile (C. difficile) infection (CDI), which is the most severe
hospital-acquired intestinal infection. Given the wide differences
in microbiota across hosts and in their recovery after antibiotic
treatments, there is a need for assays to assess the influence of
dysbiosis and its recovery dynamics on the susceptibility of the host
to CDI. Germination of C. difficile spores is a key
virulence trait for the onset of CDI, which is influenced by the level
of primary vs secondary bile acids in the intestinal milieu that is
regulated by the microbiota composition. Herein, the germination of C. difficile spores in fecal supernatant from mice that
are subject to varying degrees of antibiotic treatment is utilized
as an ex vivo assay to predict intestinal dysbiosis
in the host based on their susceptibility to CDI, as determined by in vivo CDI metrics in the same mouse model. Quantification
of spore germination down to lower detection limits than the colony-forming
assay is achieved by using impedance cytometry to count single vegetative
bacteria that are identified based on their characteristic electrical
physiology for distinction vs aggregated spores and cell debris in
the media. As a result, germination can be quantified at earlier time
points and with fewer spores for correlation to CDI outcomes. This
sets the groundwork for a point-of-care tool to gauge the susceptibility
of human microbiota to CDI after antibiotic treatments