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1. Hydrogel-based microfluidic device with multiplexed 3D in vitro cell culture

   https://doi.org/10.1038/s41598-022-22439-y  

   Clancy, Allison; Chen, Dayi; Bruns, Joseph; Nadella, Jahnavi; Stealey, Samuel; Zhang, Yanjia; Timperman, Aaron; Zustiak, Silviya P. (December 2022, Scientific Reports)

   Abstract Microfluidic devices that combine an extracellular matrix environment, cells, and physiologically relevant perfusion, are advantageous as cell culture platforms. We developed a hydrogel-based, microfluidic cell culture platform by loading polyethylene glycol (PEG) hydrogel-encapsulated U87 glioblastoma cells into membrane-capped wells in polydimethyl siloxane (PDMS). The multilayer microfluidic cell culture system combines previously reported design features in a configuration that loads and biomimetically perfuses a 2D array of cell culture chambers. One dimension of the array is fed by a microfluidic concentration gradient generator (MCGG) while the orthogonal dimension provides loading channels that fill rows of cell culture chambers in a separate layer. In contrast to typical tree-like MCGG mixers, a fractional serial dilution of 1, ½, ¼, and 0 of the initial solute concentration is achieved by tailoring the input microchannel widths. Hydrogels are efficiently and reproducibly loaded in all wells and cells are evenly distributed throughout the hydrogel, maintaining > 90% viability for up to 4 days. In a drug screening assay, diffusion of temozolomide and carmustine to hydrogel-encapsulated U87 cells from the perfusion solution is measured, and dose–response curves are generated, demonstrating utility as an in vitro mimic of the glioblastoma microenvironment. 

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2. Fatty Acid Induction of Lipid Droplets in Cancer Cells

   Jacob Adler (April 2023, CourseSource)

   Stanley Lo, University of (Ed.)

   There is a growing need for the development and communication of cell culture-based laboratory activities specifically designed for undergraduate students. This multi-week laboratory activity allows students to take part in the planning, experimentation, data analysis, and communication of the results of their cell culture-based research project. The laboratory activity specifically uses fatty acid induction of lipid droplets in cancer HeLa cells followed by a novel live-cell staining protocol developed specifically to allow undergraduate students the opportunity to complete a cell culture-based fluorescence microscopy project. This laboratory activity incorporates multiple levels of assessment and allows students to explore the responses of HeLa cancer cells to their environment. 

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3. Continuous Viscoelasticity Measurement of Cell Spheroids via Microfluidic Electrical Aspiration

   https://doi.org/10.1021/acssensors.4c01405  

   Chen, Heyi; Brown, Jacob; Urban, Aaron; Zhang, Ge; Zhe, Jiang (November 2024, ACS Sensors)

   Measurement of viscoelastic characteristics of cells cultured in 3D is critical to study many biological processes including tissue and organ growth. In this article, we present a unique electrical aspiration method to measure the viscoelastic properties of cell spheroids. A microfluidic sensor was created to demonstrate this method. Unlike the traditional optical aspiration method, the aspiration of the cell spheroids is monitored via monitoring the dynamic electrical resistance change of a symmetrical microfluidic aspiration channel. We first used the microfluidic device to measure the viscoelastic properties of two types of biological tissues derived from calfskin and porcine left ventricular myocardium. The equilibrium elastic modulus and creep time con-stants were measured to be 148.1±24.1 kPa and 76.7±3.5seconds and 64.5±7.7 kPa and 31.4±2.7 seconds respectively, which matched well with reported data. The test validated the principle of the electrical aspiration method. Next, we applied the method for measuring cell spheroids made of human mesenchymal stem cells at different culture stages. The equilibrium elastic modulus and apparent viscosity decreased with increasing culture time. Compared to optical aspiration methods, this microfluidic electrical aspiration method has no reliance on transparent materials and image processing, which thus allows simple set-up, fast data acquisition and analysis. The use of a symmetric aspiration channel and the linear half-space model enable measurements of a large number of viscoelastic properties via a single measurement with higher accuracy. This method will enable high throughput, continuous viscoelastic measurement of cell spheroids as well as other 3D cell culture models in flow conditions without the need for any optical measurements 

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4. Engineering anisotropic human stem cell-derived three-dimensional cardiac tissue on-a-chip

   https://doi.org/doi: 10.1016/j.biomaterials.2020.120195  

   Veldhuizen, Jaimeson; Cutts, Joshua; Brafman, David; Migrino, Raymond Q.; Nikkhah, Mehdi (October 2020, Biomaterials)

   Despite significant efforts in the study of cardiovascular diseases (CVDs), they persist as the leading cause of mortality worldwide. Considerable research into human pluripotent stem cell-derived cardiomyocytes (hPSC-CMs) has highlighted their immense potential in the development of in vitro human cardiac tissues for broad mechanistic, therapeutic, and patient-specific disease modeling studies in the pursuit of CVD research. However, the relatively immature state of hPSC-CMs remains an obstacle in enhancing clinical relevance ofengineered cardiac tissue models. In this study, we describe development of a microfluidic platform for 3D modeling of cardiac tissues, derived from both rat cells and hPSC-CMs, to better recapitulate the native myocardium through co-culture with interstitial cells (specifically cardiac fibroblasts), biomimetic collagen hydrogel encapsulation, and induction of highly anisotropic tissue architecture. The presented platform is precisely engineered through incorporation of surface topography in the form of staggered microposts to enable long-term culture and maturation of cardiac cells, resulting in formation of physiologically relevant cardiac tissues with anisotropy that mimics native myocardium. After two weeks of culture, hPSC-derived cardiac tissues exhibited well-defined sarcomeric striations, highly synchronous contractions, and upregulation of several maturation genes, including HCN1, KCNQ1, CAV1.2, CAV3.1, PLN, and RYR2. These findings demonstrate the ability of the proposed engineered platform to mature animal- as well as human stem cell-derived cardiac tissues over an extended period of culture, providing a novel microfluidic chip with the capability for cardiac disease modeling and therapeutic testing. 

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5. High‐Throughput Magnetic Actuation Platform for Evaluating the Effect of Mechanical Force on 3D Tumor Microenvironment

   https://doi.org/10.1002/adfm.202005021  

   Enríquez, Ángel; Libring, Sarah; Field, Tyler C.; Jimenez, Julian; Lee, Taeksang; Park, Hyunsu; Satoski, Douglas; Wendt, Michael K.; Calve, Sarah; Tepole, Adrian Buganza; et al (September 2020, Advanced Functional Materials)

   Abstract Accurately replicating and analyzing cellular responses to mechanical cues is vital for exploring metastatic disease progression. However, many of the existing in vitro platforms for applying mechanical stimulation seed cells on synthetic substrates. To better recapitulate physiological conditions, a novel actuating platform is developed with the ability to apply tensile strain on cells at various amplitudes and frequencies in a high‐throughput multi‐well culture plate using a physiologically relevant substrate. Suspending fibrillar fibronectin across the body of the magnetic actuator provides a matrix representative of early metastasis for 3D cell culture that is not reliant on a synthetic substrate. This platform enables the culturing and analysis of various cell types in an environment that mimics the dynamic stretching of lung tissue during normal respiration. Metabolic activity, YAP activation, and morphology of breast cancer cells are analyzed within one week of cyclic stretching or static culture. Further, matrix degradation is significantly reduced in breast cancer cell lines with metastatic potential after actuation. These new findings demonstrate a clear suppressive cellular response due to cyclic stretching that has implications for a mechanical role in the dormancy and reactivation of disseminated breast cancer cells to macrometastases. 

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