Development of a programmable magnetic agitation device to maintain colloidal suspension of cells during microfluidic syringe pump perfusion.

Droplet-based microfluidic devices have been used to achieve homogeneous cell encapsulation, but cells sediment in a solution, leading to heterogeneous products. In this technical note, we describe automated and programmable agitation device to maintain colloidal suspensions of cells. We demonstrate that the agitation device can be interfaced with a syringe pump for microfluidic applications. Agitation profiles of the device were predictable and corresponded to device settings. The device maintains the concentration of cells in an alginate solution over time without implicating cell viability. This device replaces manual agitation, and hence is suitable for applications that require slow perfusion for a longer period of time in a scalable manner.

Manipulation of the nucleoscaffold potentiates cellular reprogramming kinetics.

Somatic cell fate is an outcome set by the activities of specific transcription factors and the chromatin landscape and is maintained by gene silencing of alternate cell fates through physical interactions with the nuclear scaffold. Here, we evaluate the role of the nuclear scaffold as a guardian of cell fate in human fibroblasts by comparing the effects of transient loss (knockdown) and mutation (progeria) of functional Lamin A/C, a core component of the nuclear scaffold. We observed that Lamin A/C deficiency or mutation disrupts nuclear morphology, heterochromatin levels, and increases access to DNA in lamina-associated domains. Changes in Lamin A/C were also found to impact the mechanical properties of the nucleus when measured by a microfluidic cellular squeezing device. We also show that transient loss of Lamin A/C accelerates the kinetics of cellular reprogramming to pluripotency through opening of previously silenced heterochromatin domains while genetic mutation of Lamin A/C into progerin induces a senescent phenotype that inhibits the induction of reprogramming genes. Our results highlight the physical role of the nuclear scaffold in safeguarding cellular fate.

Programmable microencapsulation for enhanced mesenchymal stem cell persistence and immunomodulation.

Mesenchymal stem cell (MSC) therapies demonstrate particular promise in ameliorating diseases of immune dysregulation but are hampered by short in vivo cell persistence and inconsistencies in phenotype. Here, we demonstrate that biomaterial encapsulation into alginate using a microfluidic device could substantially increase in vivo MSC persistence after intravenous (i.v.) injection. A combination of cell cluster formation and subsequent cross-linking with polylysine led to an increase in injected MSC half-life by more than an order of magnitude. These modifications extended persistence even in the presence of innate and adaptive immunity-mediated clearance. Licensing of encapsulated MSCs with inflammatory cytokine pretransplantation increased expression of immunomodulatory-associated genes, and licensed encapsulates promoted repopulation of recipient blood and bone marrow with allogeneic donor cells after sublethal irradiation by a ∼2-fold increase. The ability of microgel encapsulation to sustain MSC survival and increase overall immunomodulatory capacity may be applicable for improving MSC therapies in general.

Change in viability of C2C12 myoblasts under compression, shear and oxidative challenges.

Skeletal and epidermal loadings can damage muscle cells and contribute to the development of deep tissue injury (DTI) - a severe kind of pressure ulcers affecting many people with disability. Important predisposing factors include the multiaxial stress and strain fields in the internal tissues, particularly the vulnerable muscles around bony prominences. A careful study of the mechanical damage thresholds for muscle cell death is critical not only to the understanding of the formation of DTI, but also to the design of various body support surfaces for prevention. In this paper, we measured the mechanical damage thresholds of C2C12 myoblasts under prescribed compressive strains (15% and 30%) and shear strains (from 0% to 100%), and studied how oxidative stress, as caused potentially by reperfusion or inflammation, may affect such damage thresholds. A flat plate was used to apply a uniform compressive strain and a radially increasing shear strain on disks of Gelatin-methacrylate (GelMA) hydrogel with myoblasts encapsulated within. The percentages of cell death were estimated with propidium iodide (PI) and calcein AM staining. Results suggested that cell death depended on both the level and duration of the applied strain. There seemed to be a non-linear coupling between compression and shear. Muscle cells often need to function biomechanically in challenging oxidative environments. To study how oxidative stress may affect the mechanical damage thresholds of myoblasts, cell viability under compressive and shear strains was also studied after the cells were pre-treated for different durations (1h and 20h) with different concentrations (0.1mM and 0.5mM) of hydrogen peroxide (H2O2). Oxidative stress can either compromise or enhance the cellular resistance to shear damage, depending on the level and duration of the oxidative exposure.

The effects of oxidative stress on the compressive damage thresholds of C2C12 mouse myoblasts: implications for deep tissue injury.

Deep tissue injury (DTI) is a severe kind of pressure ulcers formed by sustained deformation of muscle tissues over bony prominences. As a major clinical issue, DTI affects people with physical disabilities, and is obviously related to the load-bearing capacity of muscle cells in various in vivo conditions. It has been hypothesized that oxidative stress, either induced by reperfusion immediately following tissue unloading or in chronic inflammatory conditions, may affect the cellular capacity against subsequent mechanical damages. In this study, we measured the compressive damage threshold of C2C12 mouse myoblasts with or without pre-treatment of hydrogen peroxide as an oxidative agent to understand how changes in the oxidative environment may contribute to the development of DTI. Spherical indentation was applied onto a layer of agarose gel (3 mm thick) covering a monolayer of C2C12 myoblasts. Cell damage was recognized by using a cell membrane damage assay, propidium iodide. The spatial profile of the measured percentage cell damage was correlated with the radially varying stress field as determined by finite element analysis to estimate the compressive stress threshold for cell damage. Results supported the hypothesis that chronic exposure to high-dosage oxidative stress could compromise the capability of muscle cells to withstand compressive damages, while short exposure to low-dosage oxidative stress could enhance such capability.

Impact of oxidative stress on cellular biomechanics and rho signaling in C2C12 myoblasts.

Although cells often can tolerate oxidative environments, abnormal oxidative stress has been identified in inflammation, cardiovascular and neurodegenerative diseases, and aging. The impact of oxidative stress on the cellular biomechanics is poorly understood, however. In this study, we used C2C12 myoblasts to investigate the effect of oxidative stress, mimicked by hydrogen peroxide (H2O2), on the cell elasticity (i.e., Young׳s modulus), viability, and production of intracellular reactive oxygen species (ROS). To better understand the mechanisms underlying the impact of H2O2, we examined various effectors of the Rho signaling pathway, which has been shown to play a key role in the control of cell mechanics. H2O2 decreased the cell stiffness in a dose-dependent manner, caused cell death, and reduced the RhoA expression that was accompanied by down-regulation of α-actin, cytoskeleton-membrane linker proteins (ezrin-radixin-moesion proteins), and focal adhesion. Modulating the Rho signaling by using a Rho activator partially restored the cell stiffness, enhanced the cell viability, and decreased the intracellular ROS level, suggesting a potential intervention strategy to maintain the cellular biomechanical homeostasis and rescue cell damage in the threat of oxidative stresses.