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51. Microfluidic-enabled bottom-up hydrogels from annealable naturally-derived protein microbeads

Author

Sheikhi, Amir, de Rutte, Joseph, Haghniaz, Reihaneh, Akouissi, Outman, Sohrabi, Alireza, Di Carlo, Dino, and Khademhosseini, Ali

Subjects
Bioengineering, Regenerative Medicine, Biotechnology, Biocompatible Materials, Equipment Design, Gelatin, Human Umbilical Vein Endothelial Cells, Humans, Hydrogels, Microfluidic Analytical Techniques, Porosity, Proteins, Gelatin methacryloyl, Modular hydrogels, Microporous scaffolds, Microbeads, 3D cell seeding, Particle gels
Abstract

Naturally-derived proteins, such as collagen, elastin, fibroin, and gelatin (denatured collagen) hold a remarkable promise for tissue engineering and regenerative medicine. Gelatin methacryloyl (GelMA), synthesized from the methacryloyl modification of gelatin, mimicking the structure of extracellular matrix, has widely been used as a universal multi-responsive scaffold for a broad spectrum of applications, spanning from cell therapy to bioprinting and organoid development. Despite the widespread applications of GelMA, coupled stiffness and porosity has inhibited its applications in 3D cellular engineering wherein a stiff scaffold with large pores is demanded (e.g., at concentrations >10 wt%). Taking advantage of the orthogonal thermo-chemical responsivity of GelMA, we have developed microfluidic-assisted annealable GelMA beads, that are first stabilized by temperature-mediated physical crosslinking, flowed to form a scaffold structure, and then chemically annealed using light to fabricate novel bead-based 3D GelMA scaffolds with high mechanical resilience. We show how beaded GelMA (B-GelMA) provides a self-standing microporous environment with an orthogonal void fraction and stiffness, promoting cell adhesion, proliferation, and rapid 3D seeding at a high polymer concentration (∼20 wt%) that would otherwise be impossible for bulk GelMA. B-GelMA, decorated with methacryloyl and arginylglycylaspartic acid (RGD) peptide motifs, does not require additional functionalization for annealing and cell adhesion, providing a versatile biorthogonal platform with orthogonal stiffness and porosity for a myriad of biomedical applications. This technology provides a universal method to convert polymeric materials with orthogonal physico-chemical responsivity to modular platforms, opening a new horizon for converting bulk hydrogels to beaded hydrogels (B-hydrogels) with decoupled porosity and stiffness.

Published
2019

52. Modular microporous hydrogels formed from microgel beads with orthogonal thermo-chemical responsivity: Microfluidic fabrication and characterization

Author

Sheikhi, Amir, de Rutte, Joseph, Haghniaz, Reihaneh, Akouissi, Outman, Sohrabi, Alireza, Di Carlo, Dino, and Khademhosseini, Ali

Subjects
Biotechnology, Bioengineering, Modular hydrogels, Microporous scaffolds, Microbeads, Particle gels, Tissue engineering, 3D cell seeding, Gelatin methacryloyl, GelMA, Microfluidic thermo-chemical fabrication of hydrogel beads for microporous scaffold assembly, Materials Engineering
Abstract

Despite the significant advances in designing injectable bulk hydrogels, the inability to control the pore interconnectivity and decoupling it from the matrix stiffness has tremendously limited the applicability of stiff, flowable hydrogels for 3D cellular engineering, e.g., in hard tissue engineering. To overcome this persistent challenge, here, we introduce a universal method to convert thermosensitive macromolecules with chemically-crosslinkable moieties into annealable building blocks, forming 3D microporous beaded scaffolds in a bottom-up approach. In particular, we show gelatin methacryloyl (GelMA), a widely used biomaterial in tissue engineering, may be converted into physically-crosslinked microbeads using a facile microfluidic approach, followed by flow of the microbead suspension and chemical crosslinking in situ to fabricate microporous beaded GelMA (B-GelMA) scaffolds with interconnected pores, promoting cell functionality and rapid (within minutes) 3D seeding in stiff scaffolds, which are otherwise impossible in the bulk gel counterparts. This novel approach may set the stage for the next generation modular hydrogels with orthogonal porosity and stiffness made up of a broad range of natural and synthetic biomaterials. •This method combines well-known flow focusing microfluidic devices with facile post-processing steps to fabricate microporous scaffolds.•Temperature-driven physical crosslinking of the microbeads enables the facile purification of gel building blocks without further chemical reactions.•This method provides a simple approach to fabricate microporous scaffolds, which overcomes some of the challenges of newly emerging beaded scaffolds, including oxygen-mediated impaired crosslinking.

Published
2019

53. Computational cytometer based on magnetically modulated coherent imaging and deep learning.

Author

Zhang, Yibo, Ouyang, Mengxing, Ray, Aniruddha, Liu, Tairan, Kong, Janay, Bai, Bijie, Kim, Donghyuk, Guziak, Alexander, Luo, Yi, Feizi, Alborz, Tsai, Katherine, Duan, Zhuoran, Liu, Xuewei, Kim, Danny, Cheung, Chloe, Yalcin, Sener, Ceylan Koydemir, Hatice, Garner, Omai B, Di Carlo, Dino, and Ozcan, Aydogan

Subjects
Biophotonics, Imaging and sensing, Interference microscopy, Cancer, Prevention, Bioengineering, 4.1 Discovery and preclinical testing of markers and technologies, Detection, screening and diagnosis, Optical Physics
Abstract

Detecting rare cells within blood has numerous applications in disease diagnostics. Existing rare cell detection techniques are typically hindered by their high cost and low throughput. Here, we present a computational cytometer based on magnetically modulated lensless speckle imaging, which introduces oscillatory motion to the magnetic-bead-conjugated rare cells of interest through a periodic magnetic force and uses lensless time-resolved holographic speckle imaging to rapidly detect the target cells in three dimensions (3D). In addition to using cell-specific antibodies to magnetically label target cells, detection specificity is further enhanced through a deep-learning-based classifier that is based on a densely connected pseudo-3D convolutional neural network (P3D CNN), which automatically detects rare cells of interest based on their spatio-temporal features under a controlled magnetic force. To demonstrate the performance of this technique, we built a high-throughput, compact and cost-effective prototype for detecting MCF7 cancer cells spiked in whole blood samples. Through serial dilution experiments, we quantified the limit of detection (LoD) as 10 cells per millilitre of whole blood, which could be further improved through multiplexing parallel imaging channels within the same instrument. This compact, cost-effective and high-throughput computational cytometer can potentially be used for rare cell detection and quantification in bodily fluids for a variety of biomedical applications.

Published
2019

56. Spectro-temporal encoded Multiphoton Microscopy

Author

Karpf, Sebastian, Riche, Carson, di Carlo, Dino, Goel, Anubhuti, Zeiger, William A., Suresh, Anand, Portera-Cailliau, Carlos, and Jalali, Bahram

Subjects
Physics - Instrumentation and Detectors, Physics - Biological Physics, Physics - Optics
Abstract

Two-Photon Microscopy has become an invaluable tool for biological and medical research, providing high sensitivity, molecular specificity, inherent three-dimensional sub-cellular resolution and deep tissue penetration. In terms of imaging speeds, however, mechanical scanners still limit the acquisition rates to typically 10-100 frames per second. Here we present a high-speed non-linear microscope achieving kilohertz frame rates by employing pulse-modulated, rapidly wavelength-swept lasers and inertia-free beam steering through angular dispersion. In combination with a high bandwidth, single-photon sensitive detector, we achieve recording of fluorescent lifetimes at unprecedented speeds of 88 million pixels per second. We show diffraction-limited, multi-modal, Two-Photon fluorescence and fluorescence lifetime (FLIM), microscopy and imaging flow cytometry with a digitally reconfigurable laser, imaging system and data acquisition system. These unprecedented speeds should enable high-speed and high-throughput image-assisted cell sorting.

Published
2017
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58. A Gelatin Microdroplet Platform for High‐Throughput Sorting of Hyperproducing Single‐Cell‐Derived Microalgal Clones

Author

Li, Ming, van Zee, Mark, Riche, Carson T, Tofig, Bobby, Gallaher, Sean D, Merchant, Sabeeha S, Damoiseaux, Robert, Goda, Keisuke, and Di Carlo, Dino

Subjects
Biological Sciences, Biomedical Engineering, Engineering, Industrial Biotechnology, Bioengineering, Biotechnology, Generic health relevance, Responsible Consumption and Production, Biofuels, Biomass, Gelatin, Microalgae, Microfluidics, droplet microfluidics, high-throughput screening and sorting, microalgal biomass and biofuels, single-cell analysis, Nanoscience & Nanotechnology
Abstract

Microalgae are an attractive feedstock organism for sustainable production of biofuels, chemicals, and biomaterials, but the ability to rationally engineer microalgae to enhance production has been limited. To enable the evolution-based selection of new hyperproducing variants of microalgae, a method is developed that combines phase-transitioning monodisperse gelatin hydrogel droplets with commercial flow cytometric instruments for high-throughput screening and selection of clonal populations of cells with desirable properties, such as high lipid productivity per time traced over multiple cell cycles. It is found that gelatin microgels enable i) the growth and metabolite (e.g., chlorophyll and lipids) production of single microalgal cells within the compartments, ii) infusion of fluorescent reporter molecules into the hydrogel matrices following a sol-gel transition, iii) selection of high-producing clonal populations of cells using flow cytometry, and iv) cell recovery under mild conditions, enabling regrowth after sorting. This user-friendly method is easily integratable into directed cellular evolution pipelines for strain improvement and can be adopted for other applications that require high-throughput processing, e.g., cellular secretion phenotypes and intercellular interactions.

Published
2018

59. Functional profiling of circulating tumor cells with an integrated vortex capture and single-cell protease activity assay

Author

Dhar, Manjima, Lam, Jeffrey Nam, Walser, Tonya, Dubinett, Steven M, Rettig, Matthew B, and Di Carlo, Dino

Subjects
Biological Sciences, Biomedical and Clinical Sciences, Oncology and Carcinogenesis, Clinical Research, Prostate Cancer, Urologic Diseases, Biotechnology, Cancer, 2.1 Biological and endogenous factors, Aetiology, A549 Cells, Cell Separation, Collagenases, Humans, Lab-On-A-Chip Devices, Microfluidic Analytical Techniques, Neoplasm Proteins, Neoplastic Cells, Circulating, protease, circulating tumor cells, cell secretion, microfluidics, liquid biopsy
Abstract

Tumor cells are hypothesized to use proteolytic enzymes to facilitate invasion. Whether circulating tumor cells (CTCs) secrete these enzymes to aid metastasis is unknown. A quantitative and high-throughput approach to assay CTC secretion is needed to address this question. We developed an integrated microfluidic system that concentrates rare cancer cells >100,000-fold from 1 mL of whole blood into ∼50,000 2-nL drops composed of assay reagents within 15 min. The system isolates CTCs by size, exchanges fluid around CTCs to remove contaminants, introduces a matrix metalloprotease (MMP) substrate, and encapsulates CTCs into microdroplets. We found CTCs from prostate cancer patients possessed above baseline levels of MMP activity (1.7- to 200-fold). Activity of CTCs was generally higher than leukocytes from the same patient (average CTC/leukocyte MMP activity ratio, 2.6 ± 1.5). Higher MMP activity of CTCs suggests active proteolytic processes that may facilitate invasion or immune evasion and be relevant phenotypic biomarkers enabling companion diagnostics for anti-MMP therapies.

Published
2018

60. High-Throughput Microfluidic Sorting of Live Magnetotactic Bacteria

Author

Tay, Andy, Pfeiffer, Daniel, Rowe, Kathryn, Tannenbaum, Aaron, Popp, Felix, Strangeway, Robert, Schüler, Dirk, and Di Carlo, Dino

Subjects
Biological Sciences, Industrial Biotechnology, Bioengineering, Generic health relevance, High-Throughput Screening Assays, Magnetite Nanoparticles, Magnetosomes, Magnetospirillum, Microfluidic Analytical Techniques, Microfluidics, magnetotactic bacteria, microfluidic, enrichment, magnetic nanoparticles, Microbiology, Medical microbiology
Abstract

Magnetic nanoparticles (MNPs) are useful for many biomedical applications, but it is challenging to synthetically produce them in large numbers with uniform properties and surface functionalization. Magnetotactic bacteria (MTB) produce magnetosomes with homogenous sizes, shapes, and magnetic properties. Consequently, there is interest in using MTB as biological factories for MNP production. Nonetheless, MTB can only be grown to low yields, and wild-type strains produce low numbers of MNPs/bacterium. There are also limited technologies to facilitate the selection of MTB with different magnetic contents, such as MTB with compromised and enhanced biomineralization ability. Here, we describe a magnetic microfluidic platform combined with transient cold/alkaline treatment to temporarily reduce the rapid flagellar motion of MTB without compromising their long-term proliferation and biomineralization ability for separating MTB on the basis of their magnetic contents. This strategy enables live MTB to be enriched, which, to the best of our knowledge, has not been achieved with another previously described magnetic microfluidic device that makes use of ferrofluid and heat. Our device also facilitates the high-throughput (25,000 cells/min) separation of wild-type Magnetospirillum gryphiswaldense (MSR-1) from nonmagnetic ΔmamAB MSR-1 mutants with a sensitivity of up to 80% and isolation purity of up to 95%, as confirmed with a gold-standard fluorescent-activated cell sorter (FACS) technique. This offers a 25-fold higher throughput than other previously described magnetic microfluidic platforms (1,000 cells/min). The device can also be used to isolate Magnetospirillum magneticum (AMB-1) mutants with different ranges of magnetosome numbers with efficiencies close to theoretical estimates. We believe this technology will facilitate the magnetic characterization of genetically engineered MTB for a variety of applications, including using MTB for large-scale, controlled MNP production.IMPORTANCE Our magnetic microfluidic technology can greatly facilitate biological applications with magnetotactic bacteria, from selection and screening to analysis. This technology will be of interest to microbiologists, chemists, and bioengineers who are interested in the biomineralization and selection of magnetotactic bacteria (MTB) for applications such as directed evolution and magnetogenetics.

Published
2018

61. Unsupervised capture and profiling of rare immune cells using multi-directional magnetic ratcheting

Author

Murray, Coleman, Miwa, Hiromi, Dhar, Manjima, Park, Da Eun, Pao, Edward, Martinez, Jessica, Kaanumale, Sireesha, Loghin, Evelina, Graf, John, Rhaddassi, Khadir, Kwok, William W, Hafler, David, Puleo, Chris, and Di Carlo, Dino

Subjects
Biotechnology, Inflammatory and immune system, Cell Separation, Cytokines, Humans, Immune System, Magnetic Fields, Chemical Sciences, Engineering, Analytical Chemistry
Abstract

Immunotherapies (IT) require induction, expansion, and maintenance of specific changes to a patient's immune cell repertoire which yield a therapeutic benefit. Recently, mechanistic understanding of these changes at the cellular level has revealed that IT results in complex phenotypic transitions in target cells, and that therapeutic effectiveness may be predicted by monitoring these transitions during therapy. However, monitoring will require unique tools that enable capture, manipulation, and profiling of rare immune cell populations. In this study, we introduce a method of automated and unsupervised separation and processing of rare immune cells, using high-force and multidimensional magnetic ratcheting (MR). We demonstrate capture of target immune cells using samples with up to 1 : 10 000 target cell to background cell ratios from input volumes as small as 25 microliters (i.e. a low volume and low cell frequency sample sparing assay interface). Cell capture is shown to achieve up to 90% capture efficiency and purity, and captured cell analysis is shown using both on-chip culture/activity assays and off-chip ejection and nucleic acid analysis. These results demonstrate that multi-directional magnetic ratcheting offers a unique separation system for dealing with blood cell samples that contain either rare cells or significantly small volumes, and the "sample sparing" capability leads to an expanded spectrum of parameters that can be measured. These tools will be paramount to advancing techniques for immune monitoring under conditions in which both the sample volume and number of antigen-specific target cells are often exceedingly small, including during IT and treatment of allergy, asthma, autoimmunity, immunodeficiency, cell based therapy, transplantation, and infection.

Published
2018

62. Continuous and Quantitative Purification of T-Cell Subsets for Cell Therapy Manufacturing Using Magnetic Ratcheting Cytometry

Author

Murray, Coleman, Pao, Edward, Jann, Andrew, Park, Da Eun, and Di Carlo, Dino

Subjects
Engineering, Biomedical and Clinical Sciences, Immunology, Cancer, Biotechnology, Automation, CD3 Complex, Cell Separation, Cell- and Tissue-Based Therapy, Flow Cytometry, HL-60 Cells, Humans, Jurkat Cells, Magnetic Phenomena, T-Lymphocyte Subsets, ratcheting cytometry, cell therapy manufacturing, immunotherapy, Medical biotechnology, Biomedical engineering
Abstract

T-cell-based immunotherapies represent a growing medical paradigm that has the potential to revolutionize contemporary cancer treatments. However, manufacturing bottlenecks related to the enrichment of therapeutically optimal T-cell subpopulations from leukopak samples impede scale-up and scale-out efforts. This is mainly attributed to the challenges that current cell purification platforms face in balancing the quantitative sorting capacity needed to isolate specific T-cell subsets with the scalability to meet manufacturing throughputs. In this work, we report a continuous-flow, quantitative cell enrichment platform based on a technique known as ratcheting cytometry that can perform complex, multicomponent purification targeting various subpopulations of magnetically labeled T cells directly from apheresis or peripheral blood mononuclear cell (PBMC) samples. The integrated ratcheting cytometry instrument and cartridge demonstrated enrichment of T cells directly from concentrated apheresis samples with a 97% purity and an 85% recovery of magnetically tagged cells. Magnetic sorting of different T-cell subpopulations was also accomplished on chip by multiplexing cell surface targets onto particles with differing magnetic strengths. We believe that ratcheting cytometry's quantitative capacity and throughput scalability represents an excellent technology candidate to alleviate cell therapy manufacturing bottlenecks.

Published
2018

63. A 3D Magnetic Hyaluronic Acid Hydrogel for Magnetomechanical Neuromodulation of Primary Dorsal Root Ganglion Neurons

Author

Tay, Andy, Sohrabi, Alireza, Poole, Kate, Seidlits, Stephanie, and Di Carlo, Dino

Subjects
Engineering, Biomedical Engineering, Neurosciences, Chronic Pain, Pain Research, Bioengineering, Neurological, biomaterials, hyaluronic acid, hydrogels, magnetic materials, neural modulation, Physical Sciences, Chemical Sciences, Nanoscience & Nanotechnology, Chemical sciences, Physical sciences
Abstract

Neuromodulation tools are useful to decipher and modulate neural circuitries implicated in functions and diseases. Existing electrical and chemical tools cannot offer specific neural modulation while optogenetics has limitations for deep tissue interfaces, which might be overcome by miniaturized optoelectronic devices in the future. Here, a 3D magnetic hyaluronic hydrogel is described that offers noninvasive neuromodulation via magnetomechanical stimulation of primary dorsal root ganglion (DRG) neurons. The hydrogel shares similar biochemical and biophysical properties as the extracellular matrix of spinal cord, facilitating healthy growth of functional neurites and expression of excitatory and inhibitory ion channels. By testing with different neurotoxins, and micropillar substrate deflections with electrophysical recordings, it is found that acute magnetomechanical stimulation induces calcium influx in DRG neurons primarily via endogenous, mechanosensitive TRPV4 and PIEZO2 channels. Next, capitalizing on the receptor adaptation characteristic of DRG neurons, chronic magnetomechanical stimulation is performed and found that it reduces the expression of PIEZO2 channels, which can be useful for modulating pain where mechanosensitive channels are typically overexpressed. A general strategy is thus offered for neuroscientists and material scientists to fabricate 3D magnetic biomaterials tailored to different types of excitable cells for remote magnetomechanical modulation.

Published
2018

64. Topological Arrangement of Cardiac Fibroblasts Regulates Cellular Plasticity

Author

Yu, Jingyi, Seldin, Marcus M, Fu, Kai, Li, Shen, Lam, Larry, Wang, Ping, Wang, Yijie, Huang, Dian, Nguyen, Thang L, Wei, Bowen, Kulkarni, Rajan P, Di Carlo, Dino, Teitell, Michael, Pellegrini, Matteo, Lusis, Aldons J, and Deb, Arjun

Subjects
Biomedical and Clinical Sciences, Cardiovascular Medicine and Haematology, Clinical Sciences, Heart Disease, Genetics, Cardiovascular, 2.1 Biological and endogenous factors, Animals, Cell Aggregation, Cell Culture Techniques, Cell Plasticity, Chromatin Assembly and Disassembly, Culture Media, Conditioned, Female, Fibroblasts, Gene Expression, Male, Mice, Myocardial Infarction, Myocardium, Myocytes, Cardiac, Phenotype, cell biology, fibroblasts, fibrosis, hypertrophy, interferometry, Cardiorespiratory Medicine and Haematology, Cardiovascular System & Hematology, Cardiovascular medicine and haematology, Clinical sciences
Abstract

RationaleCardiac fibroblasts do not form a syncytium but reside in the interstitium between myocytes. This topological relationship between fibroblasts and myocytes is maintained throughout postnatal life until an acute myocardial injury occurs, when fibroblasts are recruited to, proliferate and aggregate in the region of myocyte necrosis. The accumulation or aggregation of fibroblasts in the area of injury thus represents a unique event in the life cycle of the fibroblast, but little is known about how changes in the topological arrangement of fibroblasts after cardiac injury affect fibroblast function.ObjectiveThe objective of the study was to investigate how changes in topological states of cardiac fibroblasts (such as after cardiac injury) affect cellular phenotype.Methods and resultsUsing 2 and 3-dimensional (2D versus 3D) culture conditions, we show that simple aggregation of cardiac fibroblasts is sufficient by itself to induce genome-wide changes in gene expression and chromatin remodeling. Remarkably, gene expression changes are reversible after the transition from a 3D back to 2D state demonstrating a topological regulation of cellular plasticity. Genes induced by fibroblast aggregation are strongly associated and predictive of adverse cardiac outcomes and remodeling in mouse models of cardiac hypertrophy and failure. Using solvent-based tissue clearing techniques to create optically transparent cardiac scar tissue, we show that fibroblasts in the region of dense scar tissue express markers that are induced by fibroblasts in the 3D conformation. Finally, using live cell interferometry, a quantitative phase microscopy technique to detect absolute changes in single cell biomass, we demonstrate that conditioned medium collected from fibroblasts in 3D conformation compared with that from a 2D state significantly increases cardiomyocyte cell hypertrophy.ConclusionsTaken together, these findings demonstrate that simple topological changes in cardiac fibroblast organization are sufficient to induce chromatin remodeling and global changes in gene expression with potential functional consequences for the healing heart.

Published
2018

65. Publisher Correction: Elastomeric sensor surfaces for high-throughput single-cell force cytometry.

Author

Pushkarsky, Ivan, Tseng, Peter, Black, Dylan, France, Bryan, Warfe, Lyndon, Koziol-White, Cynthia J, Jester, William F, Trinh, Ryan K, Lin, Jonathan, Scumpia, Philip O, Morrison, Sherie L, Panettieri, Reynold A, Damoiseaux, Robert, and Di Carlo, Dino

Abstract

In the version of this Article originally published, in Fig. 1a, all cells in the top schematic were missing, and in the bottom-left schematic showing multiple pattern shapes, two cells were missing in the bottom-right corner. This figure has now been updated in all versions of the Article.

Published
2018

66. Evaluation of PD-L1 expression on vortex-isolated circulating tumor cells in metastatic lung cancer.

Author

Dhar, Manjima, Wong, Jessica, Che, James, Matsumoto, Melissa, Grogan, Tristan, Elashoff, David, Garon, Edward B, Goldman, Jonathan W, Sollier Christen, Elodie, Di Carlo, Dino, and Kulkarni, Rajan P

Subjects
Hela Cells, Humans, Carcinoma, Non-Small-Cell Lung, Lung Neoplasms, Biopsy, Immunotherapy, Adult, Aged, Aged, 80 and over, Middle Aged, Female, Male, Neoplastic Cells, Circulating, Biomarkers, Tumor, A549 Cells, B7-H1 Antigen, HeLa Cells, Carcinoma, Non-Small-Cell Lung, and over, Neoplastic Cells, Circulating, Biomarkers, Tumor
Abstract

Metastatic non-small cell lung cancer (NSCLC) is a highly fatal and immunogenic malignancy. Although the immune system is known to recognize these tumor cells, one mechanism by which NSCLC can evade the immune system is via overexpression of programmed cell death ligand 1 (PD-L1). Recent clinical trials of PD-1 and PD-L1 inhibitors have returned promising clinical responses. Important for personalizing therapy, patients with higher intensity staining for PD-L1 on tumor biopsies responded better. Thus, there has been interest in using PD-L1 tumor expression as a criterion for patient selection. Currently available methods of screening involve invasive tumor biopsy, followed by histological grading of PD-L1 levels. Biopsies have a high risk of complications, and only allow sampling from limited tumor sections, which may not reflect overall tumor heterogeneity. Circulating tumor cell (CTC) PD-L1 levels could aid in screening patients, and could supplement tissue PD-L1 biopsy results by testing PD-L1 expression from disseminated tumor sites. Towards establishing CTCs as a screening tool, we developed a protocol to isolate CTCs at high purity and immunostain for PD-L1. Monitoring of PD-L1 expression on CTCs could be an additional biomarker for precision medicine that may help in determining response to immunotherapies.

Published
2018

67. Elastomeric sensor surfaces for high-throughput single-cell force cytometry.

Author

Pushkarsky, Ivan, Tseng, Peter, Black, Dylan, France, Bryan, Warfe, Lyndon, Koziol-White, Cynthia J, Jester, William F, Trinh, Ryan K, Lin, Jonathan, Scumpia, Philip O, Morrison, Sherie L, Panettieri, Reynold A, Damoiseaux, Robert, and Di Carlo, Dino

Subjects
Cells, Cultured, Macrophages, Myocytes, Smooth Muscle, Mesenchymal Stem Cells, Humans, Asthma, Elastomers, Fluorescent Dyes, Microscopy, Fluorescence, Cell Differentiation, Phagocytosis, Myocardial Contraction, Single-Cell Analysis, Formoterol Fumarate, Heterocyclic Compounds, 4 or More Rings, Biotechnology, Bioengineering, 2.1 Biological and endogenous factors, Aetiology, Generic health relevance
Abstract

As cells with aberrant force-generating phenotypes can directly lead to disease, cellular force-generation mechanisms are high-value targets for new therapies. Here, we show that single-cell force sensors embedded in elastomers enable single-cell force measurements with ~100-fold improvement in throughput than was previously possible. The microtechnology is scalable and seamlessly integrates with the multi-well plate format, enabling highly parallelized time-course studies. In this regard, we show that airway smooth muscle cells isolated from fatally asthmatic patients have innately greater and faster force-generation capacity in response to stimulation than healthy control cells. By simultaneously tracing agonist-induced calcium flux and contractility in the same cell, we show that the calcium level is ultimately a poor quantitative predictor of cellular force generation. Finally, by quantifying phagocytic forces in thousands of individual human macrophages, we show that force initiation is a digital response (rather than a proportional one) to the proper immunogen. By combining mechanobiology at the single-cell level with high-throughput capabilities, this microtechnology can support drug-discovery efforts for clinical conditions associated with aberrant cellular force generation.

Published
2018

68. Separation of cancer cells using vortical microfluidic flows.

Author

Haddadi, Hamed, Naghsh-Nilchi, Hamed, and Di Carlo, Dino

Subjects
Cancer, Classical Physics, Interdisciplinary Engineering, Nanotechnology, Nanoscience & Nanotechnology
Abstract

Label-free separation of viable cancer cells using vortical microfluidic flows has been introduced as a feasible cell collection method in oncological studies. Besides the clinical importance, the physics of particle interactions with the vortex that forms in a wall-confined geometry of a microchannel is a relatively new area of fluid dynamics. In our previous work [Haddadi and Di Carlo, J. Fluid. Mech. 811, 436-467 (2017)], we have introduced distinct aspects of inertial flow of dilute suspensions over cavities in a microchannel such as breakdown of the separatrix and formation of stable limit cycle orbits for finite size polystyrene particles. In this work, we extend our experiments to address the engineering-physics of cancer cell entrapment in microfluidic cavities. We begin by studying the effects of the channel width and device height on the morphology of the vortex, which has not been discussed in our previous work. The stable limit cycle orbits of finite size cancer cells are then presented. We demonstrate effects of the separatrix breakdown and the limit cycle formation on the operation of the cancer cell separation platform. By studying the flow of dilute cell suspensions over the cavities, we further develop the notion of the cavity capacity and the relative rate of cell accumulation as optimization criteria which connect the device geometry with the flow. Finally, we discuss the proper placement of multiple cavities inside a microchannel for improved cell entrapment.

Published
2018

69. Shaped 3D microcarriers for adherent cell culture and analysis

Author

Wu, Chueh-Yu, Stoecklein, Daniel, Kommajosula, Aditya, Lin, Jonathan, Owsley, Keegan, Ganapathysubramanian, Baskar, and Di Carlo, Dino

Subjects
Engineering, Biomedical Engineering, Biotechnology, Bioengineering, 1.1 Normal biological development and functioning, Underpinning research, 1.3 Chemical and physical sciences, Nanotechnology
Abstract

Standard tissue culture of adherent cells is known to poorly replicate physiology and often entails suspending cells in solution for analysis and sorting, which modulates protein expression and eliminates intercellular connections. To allow adherent culture and processing in flow, we present 3D-shaped hydrogel cell microcarriers, which are designed with a recessed nook in a first dimension to provide a tunable shear-stress shelter for cell growth, and a dumbbell shape in an orthogonal direction to allow for self-alignment in a confined flow, important for processing in flow and imaging flow cytometry. We designed a method to rapidly design, using the genetic algorithm, and manufacture the microcarriers at scale using a transient liquid molding optofluidic approach. The ability to precisely engineer the microcarriers solves fundamental challenges with shear-stress-induced cell damage during liquid-handling, and is poised to enable adherent cell culture, in-flow analysis, and sorting in a single format.

Published
2018

70. Gα12 facilitates shortening in human airway smooth muscle by modulating phosphoinositide 3‐kinase‐mediated activation in a RhoA‐dependent manner

Author

Yoo, Edwin J, Cao, Gaoyuan, Koziol‐White, Cynthia J, Ojiaku, Christie A, Sunder, Krishna, Jude, Joseph A, Michael, James V, Lam, Hong, Pushkarsky, Ivan, Damoiseaux, Robert, Di Carlo, Dino, Ahn, Kwangmi, An, Steven S, Penn, Raymond B, and Panettieri, Reynold A

Subjects
Medical Physiology, Biomedical and Clinical Sciences, Asthma, Lung, Biotechnology, Aetiology, 2.1 Biological and endogenous factors, Respiratory, Airway Obstruction, Carbachol, Cells, Cultured, GTP-Binding Protein alpha Subunits, G12-G13, Gene Knockdown Techniques, Humans, Muscle Contraction, Muscle, Smooth, Myosin Light Chains, Phosphatidylinositol 3-Kinase, Phosphorylation, Receptor, Muscarinic M3, Signal Transduction, rhoA GTP-Binding Protein, Pharmacology and Pharmaceutical Sciences, Pharmacology & Pharmacy, Pharmacology and pharmaceutical sciences
Abstract

Background and purposePI3K-dependent activation of Rho kinase (ROCK) is necessary for agonist-induced human airway smooth muscle cell (HASMC) contraction, and inhibition of PI3K promotes bronchodilation of human small airways. The mechanisms driving agonist-mediated PI3K/ROCK axis activation, however, remain unclear. Given that G12 family proteins activate ROCK pathways in other cell types, their role in M3 muscarinic acetylcholine receptor-stimulated PI3K/ROCK activation and contraction was examined.Experimental approachGα12 coupling was evaluated using co-immunoprecipitation and serum response element (SRE)-luciferase reporter assays. siRNA and pharmacological approaches, as well as overexpression of a regulator of G-protein signaling (RGS) proteins were applied in HASMCs. Phosphorylation levels of Akt, myosin phosphatase targeting subunit-1 (MYPT1), and myosin light chain-20 (MLC) were measured. Contraction and shortening were evaluated using magnetic twisting cytometry (MTC) and micro-pattern deformation, respectively. Human precision-cut lung slices (hPCLS) were utilized to evaluate bronchoconstriction.Key resultsKnockdown of M3 receptors or Gα12 attenuated activation of Akt, MYPT1, and MLC phosphorylation. Gα12 coimmunoprecipitated with M3 receptors, and p115RhoGEF-RGS overexpression inhibited carbachol-mediated induction of SRE-luciferase reporter. p115RhoGEF-RGS overexpression inhibited carbachol-induced activation of Akt, HASMC contraction, and shortening. Moreover, inhibition of RhoA blunted activation of PI3K. Lastly, RhoA inhibitors induced dilation of hPCLS.Conclusions and implicationsGα12 plays a crucial role in HASMC contraction via RhoA-dependent activation of the PI3K/ROCK axis. Inhibition of RhoA activation induces bronchodilation in hPCLS, and targeting Gα12 signaling may elucidate novel therapeutic targets in asthma. These findings provide alternative approaches to the clinical management of airway obstruction in asthma.

Published
2017

71. Peptide-based point-of-care serodiagnosis of Lyme disease enabled by deep-learning

Author

Goncharov, Artem, primary, Joung, Hyou-Arm, additional, Ghosh, Rajesh, additional, Ngo, Kevin, additional, Palanisamy, Barath, additional, Horn, Elizabeth J., additional, Arnaboldi, Paul M., additional, Dattwyler, Raymond J., additional, Garner, Omai B., additional, Di Carlo, Dino, additional, Ozcan, Aydogan, additional, Pejcinovic, Katarina, additional, and Krockenberger, Nicole, additional

Published
2024
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73. Probing Cell Adhesion Profiles with a Microscale Adhesive Choice Assay

Author

Kittur, Harsha, Tay, Andy, Hua, Avery, Yu, Min, and Di Carlo, Dino

Subjects
Biochemistry and Cell Biology, Biological Sciences, Breast Cancer, Biotechnology, Nanotechnology, Bioengineering, Cancer, Underpinning research, 1.1 Normal biological development and functioning, Generic health relevance, Actins, Breast Neoplasms, Cell Adhesion, Cell Line, Tumor, Collagen, Culture Media, Cytological Techniques, Dimethylpolysiloxanes, Epithelial Cells, Glass, Humans, Image Processing, Computer-Assisted, Immunohistochemistry, Integrins, Lung Neoplasms, Mesenchymal Stem Cells, Microscopy, Fluorescence, Nylons, Surface Properties, Physical Sciences, Chemical Sciences, Biophysics, Biological sciences, Chemical sciences, Physical sciences
Abstract

In this work, we introduce, to our knowledge, a new set of adhesion-based biomarkers for characterizing mammalian cells. Mammalian cell adhesion to the extracellular matrix influences numerous physiological processes. Current in vitro methods to probe adhesion focus on adhesive force to a single surface, which can investigate only a subcomponent of the adhesive, motility, and polarization cues responsible for adhesion in the 3D tissue environment. Here, we demonstrate a method to quantify the transhesive properties of cells that relies on the microscale juxtaposition of two extracellular matrix-coated surfaces. By multiplexing this approach, we investigate the unique transhesive profiles for breast cancer cells that are adapted to colonize different metastatic sites. We find that malignant breast cancer cells readily transfer to new collagen I surfaces, and away from basement membrane proteins. Integrins and actin polymerization largely regulate this transfer. This tool can be readily adopted in cell biology and cancer research to uncover, to our knowledge, novel drivers of adhesion (or de-adhesion) and sort cell populations based on complex phenotypes with physiological relevance.

Published
2017

74. Shape-based separation of microalga Euglena gracilis using inertial microfluidics.

Author

Li, Ming, Muñoz, Hector Enrique, Goda, Keisuke, and Di Carlo, Dino

Subjects
Euglena gracilis, Cell Separation, Microfluidics, Cell Shape
Abstract

Euglena gracilis (E. gracilis) has been proposed as one of the most attractive microalgae species for biodiesel and biomass production, which exhibits a number of shapes, such as spherical, spindle-shaped, and elongated. Shape is an important biomarker for E. gracilis, serving as an indicator of biological clock status, photosynthetic and respiratory capacity, cell-cycle phase, and environmental condition. The ability to prepare E. gracilis of uniform shape at high purities has significant implications for various applications in biological research and industrial processes. Here, we adopt a label-free, high-throughput, and continuous technique utilizing inertial microfluidics to separate E. gracilis by a key shape parameter-cell aspect ratio (AR). The microfluidic device consists of a straight rectangular microchannel, a gradually expanding region, and five outlets with fluidic resistors, allowing for inertial focusing and ordering, enhancement of the differences in cell lateral positions, and accurate separation, respectively. By making use of the shape-activated differences in lateral inertial focusing dynamic equilibrium positions, E. gracilis with different ARs ranging from 1 to 7 are directed to different outlets.

Published
2017

75. Identification of a Human Airway Epithelial Cell Subpopulation with Altered Biophysical, Molecular, and Metastatic Properties

Author

Pagano, Paul C, Tran, Linh M, Bendris, Nawal, O'Byrne, Sean, Tse, Henry T, Sharma, Shivani, Hoech, Jonathan W, Park, Stacy J, Liclican, Elvira L, Jing, Zhe, Li, Rui, Krysan, Kostyantyn, Paul, Manash K, Fontebasso, Yari, Larsen, Jill E, Hakimi, Shaina, Seki, Atsuko, Fishbein, Michael C, Gimzewski, James K, Di Carlo, Dino, Minna, John D, Walser, Tonya C, and Dubinett, Steven M

Subjects
Biomedical and Clinical Sciences, Clinical Sciences, Oncology and Carcinogenesis, Lung, Prevention, Lung Cancer, Cancer, 2.1 Biological and endogenous factors, Animals, Bronchi, Cell Line, Tumor, Cell Movement, Cell Proliferation, Cell Survival, Epithelial Cells, Gene Expression Profiling, Humans, Lung Neoplasms, Mice, Mice, Inbred NOD, Specific Pathogen-Free Organisms, Xenograft Model Antitumor Assays, rac1 GTP-Binding Protein, Oncology & Carcinogenesis, Clinical sciences, Oncology and carcinogenesis
Abstract

Lung cancers are documented to have remarkable intratumoral genetic heterogeneity. However, little is known about the heterogeneity of biophysical properties, such as cell motility, and its relationship to early disease pathogenesis and micrometastatic dissemination. In this study, we identified and selected a subpopulation of highly migratory premalignant airway epithelial cells that were observed to migrate through microscale constrictions at up to 100-fold the rate of the unselected immortalized epithelial cell lines. This enhanced migratory capacity was found to be Rac1-dependent and heritable, as evidenced by maintenance of the phenotype through multiple cell divisions continuing more than 8 weeks after selection. The morphology of this lung epithelial subpopulation was characterized by increased cell protrusion intensity. In a murine model of micrometastatic seeding and pulmonary colonization, the motility-selected premalignant cells exhibit both enhanced survival in short-term assays and enhanced outgrowth of premalignant lesions in longer-term assays, thus overcoming important aspects of "metastatic inefficiency." Overall, our findings indicate that among immortalized premalignant airway epithelial cell lines, subpopulations with heritable motility-related biophysical properties exist, and these may explain micrometastatic seeding occurring early in the pathogenesis of lung cancer. Understanding, targeting, and preventing these critical biophysical traits and their underlying molecular mechanisms may provide a new approach to prevent metastatic behavior. Cancer Prev Res; 10(9); 514-24. ©2017 AACRSee related editorial by Hynds and Janes, p. 491.

Published
2017

76. Biophysical isolation and identification of circulating tumor cells

Author

Che, James, Yu, Victor, Garon, Edward B, Goldman, Jonathan W, and Di Carlo, Dino

Subjects
Clinical Research, Prevention, Biotechnology, Cancer, Bioengineering, Carcinoma, Non-Small-Cell Lung, Cell Line, Tumor, Cell Separation, Humans, Lung Neoplasms, Microfluidic Analytical Techniques, Neoplastic Cells, Circulating, Chemical Sciences, Engineering, Analytical Chemistry
Abstract

Isolation and enumeration of circulating tumor cells (CTCs) from blood is important for determining patient prognosis and monitoring treatment. Methods based on affinity to cell surface markers have been applied to both purify (via immunoseparation) and identify (via immunofluorescence) CTCs. However, variability of cell biomarker expression associated with tumor heterogeneity and evolution and cross-reactivity of antibody probes have long complicated CTC enrichment and immunostaining. Here, we report a truly label-free high-throughput microfluidic approach to isolate, enumerate, and characterize the biophysical properties of CTCs using an integrated microfluidic device. Vortex-mediated deformability cytometry (VDC) consists of an initial vortex region which enriches large CTCs, followed by release into a downstream hydrodynamic stretching region which deforms the cells. Visualization and quantification of cell deformation with a high-speed camera revealed populations of large (>15 μm diameter) and deformable (aspect ratio >1.2) CTCs from 16 stage IV lung cancer samples, that are clearly distinguished by increased deformability compared to contaminating blood cells and rare large cells isolated from healthy patients. The VDC technology demonstrated a comparable positive detection rate of putative CTCs above healthy baseline (93.8%) with respect to standard immunofluorescence (71.4%). Automation allows full enumeration of CTCs from a 10 mL vial of blood within

Published
2017

77. Modulating motility of intracellular vesicles in cortical neurons with nanomagnetic forces on-chip

Author

Kunze, Anja, Murray, Coleman Tylor, Godzich, Chanya, Lin, Jonathan, Owsley, Keegan, Tay, Andy, and Di Carlo, Dino

Subjects
Neurosciences, Neurological, Animals, Cell Movement, Cells, Cultured, Cerebral Cortex, Cytological Techniques, Lab-On-A-Chip Devices, Liposomes, Magnetic Fields, Magnetite Nanoparticles, Neurons, Rats, Transport Vesicles, Chemical Sciences, Engineering, Analytical Chemistry
Abstract

Vesicle transport is a major underlying mechanism of cell communication. Inhibiting vesicle transport in brain cells results in blockage of neuronal signals, even in intact neuronal networks. Modulating intracellular vesicle transport can have a huge impact on the development of new neurotherapeutic concepts, but only if we can specifically interfere with intracellular transport patterns. Here, we propose to modulate motion of intracellular lipid vesicles in rat cortical neurons based on exogenously bioconjugated and cell internalized superparamagnetic iron oxide nanoparticles (SPIONs) within microengineered magnetic gradients on-chip. Upon application of 6-126 pN on intracellular vesicles in neuronal cells, we explored how the magnetic force stimulus impacts the motion pattern of vesicles at various intracellular locations without modulating the entire cell morphology. Altering vesicle dynamics was quantified using, mean square displacement, a caging diameter and the total traveled distance. We observed a de-acceleration of intercellular vesicle motility, while applying nanomagnetic forces to cultured neurons with SPIONs, which can be explained by a decrease in motility due to opposing magnetic force direction. Ultimately, using nanomagnetic forces inside neurons may permit us to stop the mis-sorting of intracellular organelles, proteins and cell signals, which have been associated with cellular dysfunction. Furthermore, nanomagnetic force applications will allow us to wirelessly guide axons and dendrites by exogenously using permanent magnetic field gradients.

Published
2017

78. Particle focusing by 3D inertial microfluidics

Author

Paiè, Petra, Bragheri, Francesca, Di Carlo, Dino, and Osellame, Roberto

Subjects
Fluid Mechanics and Thermal Engineering, Engineering, Bioengineering, Biotechnology, 3D fluidic network, 3D particle focusing, Dean flow, inertial microfluidics, Nanotechnology
Abstract

Three-dimensional (3D) particle focusing in microfluidics is a fundamental capability with a wide range of applications, such as on-chip flow cytometry, where high-throughput analysis at the single-cell level is performed. Currently, 3D focusing is achieved mainly in devices with complex layouts, additional sheath fluids, and complex pumping systems. In this work, we present a compact microfluidic device capable of 3D particle focusing at high flow rates and with a small footprint, without the requirement of external fields or lateral sheath flows, but using only a single-inlet, single-outlet microfluidic sequence of straight channels and tightly curving vertical loops. This device exploits inertial fluidic effects that occur in a laminar regime at sufficiently high flow rates, manipulating the particle positions by the combination of inertial lift forces and Dean drag forces. The device is fabricated by femtosecond laser irradiation followed by chemical etching, which is a simple two-step process enabling the creation of 3D microfluidic networks in fused silica glass substrates. The use of tightly curving three-dimensional microfluidic loops produces strong Dean drag forces along the whole loop but also induces an asymmetric Dean flow decay in the subsequent straight channel, thus producing rapid cross-sectional mixing flows that assist with 3D particle focusing. The use of out-of-plane loops favors a compact parallelization of multiple focusing channels, allowing one to process large amounts of samples. In addition, the low fluidic resistance of the channel network is compatible with vacuum driven flows. The resulting device is quite interesting for high-throughput on-chip flow cytometry.

Published
2017

79. Label-free isolation of prostate circulating tumor cells using Vortex microfluidic technology

Author

Renier, Corinne, Pao, Edward, Che, James, Liu, Haiyan E, Lemaire, Clementine A, Matsumoto, Melissa, Triboulet, Melanie, Srivinas, Sandy, Jeffrey, Stefanie S, Rettig, Matthew, Kulkarni, Rajan P, Di Carlo, Dino, and Sollier-Christen, Elodie

Subjects
Human Genome, Genetics, Aging, Prostate Cancer, Urologic Diseases, Biotechnology, Cancer, Clinical Research, 4.1 Discovery and preclinical testing of markers and technologies, Detection, screening and diagnosis
Abstract

There has been increased interest in utilizing non-invasive "liquid biopsies" to identify biomarkers for cancer prognosis and monitoring, and to isolate genetic material that can predict response to targeted therapies. Circulating tumor cells (CTCs) have emerged as such a biomarker providing both genetic and phenotypic information about tumor evolution, potentially from both primary and metastatic sites. Currently, available CTC isolation approaches, including immunoaffinity and size-based filtration, have focused on high capture efficiency but with lower purity and often long and manual sample preparation, which limits the use of captured CTCs for downstream analyses. Here, we describe the use of the microfluidic Vortex Chip for size-based isolation of CTCs from 22 patients with advanced prostate cancer and, from an enumeration study on 18 of these patients, find that we can capture CTCs with high purity (from 1.74 to 37.59%) and efficiency (from 1.88 to 93.75 CTCs/7.5 mL) in less than 1 h. Interestingly, more atypical large circulating cells were identified in five age-matched healthy donors (46-77 years old; 1.25-2.50 CTCs/7.5 mL) than in five healthy donors

Published
2017

80. High-throughput physical phenotyping of cell differentiation

Author

Lin, Jonathan, Kim, Donghyuk, Tse, Henry T, Tseng, Peter, Peng, Lillian, Dhar, Manjima, Karumbayaram, Saravanan, and Di Carlo, Dino

Subjects
Engineering, Nanotechnology, Stem Cell Research, Stem Cell Research - Embryonic - Human, cell mechanics, deformation, deformation kinetics, morphology, physical phenotype, stem cells
Abstract

In this report, we present multiparameter deformability cytometry (m-DC), in which we explore a large set of parameters describing the physical phenotypes of pluripotent cells and their derivatives. m-DC utilizes microfluidic inertial focusing and hydrodynamic stretching of single cells in conjunction with high-speed video recording to realize high-throughput characterization of over 20 different cell motion and morphology-derived parameters. Parameters extracted from videos include size, deformability, deformation kinetics, and morphology. We train support vector machines that provide evidence that these additional physical measurements improve classification of induced pluripotent stem cells, mesenchymal stem cells, neural stem cells, and their derivatives compared to size and deformability alone. In addition, we utilize visual interactive stochastic neighbor embedding to visually map the high-dimensional physical phenotypic spaces occupied by these stem cells and their progeny and the pathways traversed during differentiation. This report demonstrates the potential of m-DC for improving understanding of physical differences that arise as cells differentiate and identifying cell subpopulations in a label-free manner. Ultimately, such approaches could broaden our understanding of subtle changes in cell phenotypes and their roles in human biology.

Published
2017

81. High-throughput and automated diagnosis of antimicrobial resistance using a cost-effective cellphone-based micro-plate reader.

Author

Feng, Steve, Tseng, Derek, Di Carlo, Dino, Garner, Omai B, and Ozcan, Aydogan

Subjects
Humans, Gram-Negative Bacteria, Klebsiella pneumoniae, Gram-Negative Bacterial Infections, Anti-Bacterial Agents, Microarray Analysis, Nephelometry and Turbidimetry, Microbial Sensitivity Tests, Drug Resistance, Bacterial, Automation, High-Throughput Screening Assays, Cell Phone, Drug Resistance, Bacterial
Abstract

Routine antimicrobial susceptibility testing (AST) can prevent deaths due to bacteria and reduce the spread of multi-drug-resistance, but cannot be regularly performed in resource-limited-settings due to technological challenges, high-costs, and lack of trained professionals. We demonstrate an automated and cost-effective cellphone-based 96-well microtiter-plate (MTP) reader, capable of performing AST without the need for trained diagnosticians. Our system includes a 3D-printed smartphone attachment that holds and illuminates the MTP using a light-emitting-diode array. An inexpensive optical fiber-array enables the capture of the transmitted light of each well through the smartphone camera. A custom-designed application sends the captured image to a server to automatically determine well-turbidity, with results returned to the smartphone in ~1 minute. We tested this mobile-reader using MTPs prepared with 17 antibiotics targeting Gram-negative bacteria on clinical isolates of Klebsiella pneumoniae, containing highly-resistant antimicrobial profiles. Using 78 patient isolate test-plates, we demonstrated that our mobile-reader meets the FDA-defined AST criteria, with a well-turbidity detection accuracy of 98.21%, minimum-inhibitory-concentration accuracy of 95.12%, and a drug-susceptibility interpretation accuracy of 99.23%, with no very major errors. This mobile-reader could eliminate the need for trained diagnosticians to perform AST, reduce the cost-barrier for routine testing, and assist in spatio-temporal tracking of bacterial resistance.

Published
2016

82. Multiparameter mechanical and morphometric screening of cells.

Author

Masaeli, Mahdokht, Gupta, Dewal, O'Byrne, Sean, Tse, Henry TK, Gossett, Daniel R, Tseng, Peter, Utada, Andrew S, Jung, Hea-Jin, Young, Stephen, Clark, Amander T, and Di Carlo, Dino

Subjects
Fibroblasts, Animals, Humans, Mice, Microfluidic Analytical Techniques, Flow Cytometry, Cell Count, Rheology, Microfluidics, Biophysics, Phenotype, Embryonic Stem Cells, Hydrodynamics, Machine Learning
Abstract

We introduce a label-free method to rapidly phenotype and classify cells purely based on physical properties. We extract 15 biophysical parameters from cells as they deform in a microfluidic stretching flow field via high-speed microscopy and apply machine-learning approaches to discriminate different cell types and states. When employing the full 15 dimensional dataset, the technique robustly classifies individual cells based on their pluripotency, with accuracy above 95%. Rheological and morphological properties of cells while deforming were critical for this classification. We also show the application of this method in accurate classifying cells based on their viability, drug screening and detecting populations of malignant cells in mixed samples. We show that some of the extracted parameters are not linearly independent, and in fact we reach maximum classification accuracy by using only a subset of parameters. However, the informative subsets could vary depending on cell types in the sample. This work shows the utility of an assay purely based on intrinsic biophysical properties of cells to identify changes in cell state. In addition to a label-free alternative to flow cytometry in certain applications, this work, also can provide novel intracellular metrics that would not be feasible with labeled approaches (i.e. flow cytometry).

Published
2016

83. Underlying Mechanisms of Vascular Disease in Hutchinson-Gilford Progeria Syndrome

Author

Kim, Paul, Fong, Loren G1, Di Carlo, Dino, Kim, Paul, Kim, Paul, Fong, Loren G1, Di Carlo, Dino, and Kim, Paul

Abstract

Children with Hutchinson-Gilford progeria syndrome (HGPS) display symptoms resembling accelerated aging, with most succumbing in their mid-teens to complications from arteriosclerotic lesions in major arteries. HGPS arises from a de novo mutation in the LMNA gene, such as the Gly608Gly mutation, which creates an aberrant splice donor site, resulting in a deletion of 50 amino acids in prelamin A and the production of mutant protein called progerin. Progerin, unlike mature lamin A, retains a farnesyl lipid anchor, which contributes to cellular toxicity. In HGPS, a prominent vascular anomaly is reduced numbers of smooth muscle cells (SMCs) in the medial layer of large arteries, promoting arteriosclerotic disease. In order to study the underlying mechanisms of vascular disease in HGPS, we created a mouse model of HGPS (LmnaG609G) which exhibits disease phenotypes reminiscent of human HGPS, including the hallmark vascular disease. We also created an in vitro doxycycline-inducible cell culture system to investigate properties of progerin by studying the effects of progerin on the nuclear lamina meshwork, nuclear mechanics, integrity of the nuclear envelope, their relationship to nuclear morphology, DNA damage, and cell viability. In this dissertation, my goal was to understand the mechanisms underlying vascular pathology in HGPS, focusing on the interactions between progerin, lamin B1, and the integrity of the nuclear lamina meshwork in vascular SMCs. In Chapter 2, we investigated the role of mechanical stress on the vascular disease and showed that disrupting the LINC complex in smooth muscle cells reduces SMC loss in LmnaG609G mice. In Chapter 3, we hypothesized that progerin weakens the structural integrity of the nuclear envelope. Indeed, we showed that progerin resulted in nuclear membrane ruptures and found that it was responsible for vascular pathology in vivo. In Chapter 4, we investigated a more fundamental question—how does progerin induce abnormal biological ef

Published
2024

84. Unraveling the Dynamics of Burn Wound Healing in Murine Model: Insights into Immune Signaling Pathways, Tissue Regeneration, and Biomaterial-Based Therapies

Author

Hsu, Wilson, Scumpia, Phillip O1, Di Carlo, Dino, Hsu, Wilson, Hsu, Wilson, Scumpia, Phillip O1, Di Carlo, Dino, and Hsu, Wilson

Abstract

This study investigates wound healing differences between full-thickness excisional wounds and scald burns in adult mice, highlighting the challenges of burn injury regeneration. Despite timely debridement, burns consistently exhibit delayed healing and increased scarring compared to excisional wounds. We develop a mouse model that recapitulates the clinical features of burn wounds in humans. We use this model to explore the potential of D-peptide and L-peptide crosslinked microporous annealed particle (MAP) hydrogels to enhance burn wound regeneration. Our findings underscore the critical influence of injury mechanisms on tissue regenerative potential, suggesting that MAP hydrogels, particularly those with peptide crosslinking would improve burn wounds. These insights deepen our understanding of wound healing dynamics. Our findings reveal the therapeutic strategies to enhance tissue repair and regeneration in burn injuries, ultimately advancing clinical interventions and improving patient care.

Published
2024

85. Direct Measurement of Particle Inertial Migration in Rectangular Microchannels

Author

Hood, Kaitlyn, Kahkeshani, Soroush, Di Carlo, Dino, and Roper, Marcus

Subjects
Physics - Fluid Dynamics
Abstract

Particles traveling at high velocities through microfluidic channels migrate from their starting streamlines due to inertial lift forces. Theories predict different scaling laws for these forces and there is little experimental evidence by which to validate theory. Here we experimentally measure the three dimensional positions and migration velocities of particles. Our experimental method relies on a combination of sub-pixel accurate particle tracking and velocimetric reconstruction of the depth dimension to track thousands of individual particles in three dimensions. We show that there is no simple scaling of inertial forces upon particle size, but that migration velocities agree well with numerical simulations and with a two-term asymptotic theory that contains no unmeasured parameters., Comment: 11 pages, 7 figures

Published
2015
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86. Optimization of micropillar sequences for fluid flow sculpting

Author

Stoecklein, Daniel, Wu, Chueh-Yu, Kim, Donghyuk, Di Carlo, Dino, and Ganapathysubramanian, Baskar

Subjects
Physics - Fluid Dynamics
Abstract

Inertial fluid flow deformation around pillars in a microchannel is a new method for controlling fluid flow. Sequences of pillars have been shown to produce a rich phase space with a wide variety of flow transformations. Previous work has successfully demonstrated manual design of pillar sequences to achieve desired transformations of the flow cross-section, with experimental validation. However, such a method is not ideal for seeking out complex sculpted shapes as the search space quickly becomes too large for efficient manual discovery. We explore fast, automated optimization methods to solve this problem. We formulate the inertial flow physics in microchannels with different micropillar configurations as a set of state transition matrix operations. These state transition matrices are constructed from experimentally validated streamtraces. This facilitates modeling the effect of a sequence of micropillars as nested matrix-matrix products, which have very efficient numerical implementations. With this new forward model, arbitrary micropillar sequences can be rapidly simulated with various inlet configurations, allowing optimization routines quick access to a large search space. We integrate this framework with the genetic algorithm and showcase its applicability by designing micropillar sequences for various useful transformations. We computationally discover micropillar sequences for complex transformations that are substantially shorter than manually designed sequences. We also determine sequences for novel transformations that were difficult to manually design. Finally, we experimentally validate these computational designs by fabricating devices and comparing predictions with the results from confocal microscopy.

Published
2015

87. Inhibition of PI3K promotes dilation of human small airways in a rho kinase‐dependent manner

Author

Koziol-White, Cynthia J, Yoo, Edwin J, Cao, Gaoyuan, Zhang, Jie, Papanikolaou, Eleni, Pushkarsky, Ivan, Andrews, Adam, Himes, Blanca E, Damoiseaux, Robert D, Liggett, Stephen B, Di Carlo, Dino, Kurten, Richard C, and Panettieri, Reynold A

Subjects
Medical Physiology, Biomedical and Clinical Sciences, Asthma, Clinical Research, Lung, Aetiology, 2.1 Biological and endogenous factors, Respiratory, Cells, Cultured, Dose-Response Relationship, Drug, Humans, Myocytes, Smooth Muscle, Phosphatidylinositol 3-Kinases, Phosphoinositide-3 Kinase Inhibitors, Protein Kinase Inhibitors, RNA, Small Interfering, Structure-Activity Relationship, Pharmacology and Pharmaceutical Sciences, Pharmacology & Pharmacy, Pharmacology and pharmaceutical sciences
Abstract

Background and purposeAsthma manifests as a heterogeneous syndrome characterized by airway obstruction, inflammation and hyperresponsiveness (AHR). Although the molecular mechanisms remain unclear, activation of specific PI3K isoforms mediate inflammation and AHR. We aimed to determine whether inhibition of PI3Kδ evokes dilation of airways and to elucidate potential mechanisms.Experimental approachHuman precision cut lung slices from non-asthma donors and primary human airway smooth muscle (HASM) cells from both non-asthma and asthma donors were utilized. Phosphorylation of Akt, myosin phosphatase target subunit 1 (MYPT1) and myosin light chain (MLC) were assessed in HASM cells following either PI3K inhibitor or siRNA treatment. HASM relaxation was assessed by micro-pattern deformation. Reversal of constriction of airways was assessed following stimulation with PI3K or ROCK inhibitors.Key resultsSoluble inhibitors or PI3Kδ knockdown reversed carbachol-induced constriction of human airways, relaxed agonist-contracted HASM and inhibited pAkt, pMYPT1 and pMLC in HASM. Similarly, inhibition of Rho kinase also dilated human PCLS airways and suppressed pMYPT1 and pMLC. Baseline pMYPT1 was significantly elevated in HASM cells derived from asthma donors in comparison with non-asthma donors. After desensitization of the β2 -adrenoceptors, a PI3Kδ inhibitor remained an effective dilator. In the presence of IL-13, dilation by a β agonist, but not PI3K inhibitor, was attenuated.Conclusion and implicationsPI3Kδ inhibitors act as dilators of human small airways. Taken together, these findings provide alternative approaches to the clinical management of airway obstruction in asthma.

Published
2016

88. Simplified three-dimensional tissue clearing and incorporation of colorimetric phenotyping.

Author

Sung, Kevin, Ding, Yichen, Ma, Jianguo, Chen, Harrison, Huang, Vincent, Cheng, Michelle, Yang, Cindy F, Kim, Jocelyn T, Eguchi, Daniel, Di Carlo, Dino, Hsiai, Tzung K, Nakano, Atsushi, and Kulkarni, Rajan P

Subjects
Animals, Humans, Imaging, Three-Dimensional, Microscopy, Confocal, Colorimetry, Histocytological Preparation Techniques, Phenotype, Imaging, Three-Dimensional, Microscopy, Confocal
Abstract

Tissue clearing methods promise to provide exquisite three-dimensional imaging information; however, there is a need for simplified methods for lower resource settings and for non-fluorescence based phenotyping to enable light microscopic imaging modalities. Here we describe the simplified CLARITY method (SCM) for tissue clearing that preserves epitopes of interest. We imaged the resulting tissues using light sheet microscopy to generate rapid 3D reconstructions of entire tissues and organs. In addition, to enable clearing and 3D tissue imaging with light microscopy methods, we developed a colorimetric, non-fluorescent method for specifically labeling cleared tissues based on horseradish peroxidase conversion of diaminobenzidine to a colored insoluble product. The methods we describe here are portable and can be accomplished at low cost, and can allow light microscopic imaging of cleared tissues, thus enabling tissue clearing and imaging in a wide variety of settings.

Published
2016

89. The Age of Cortical Neural Networks Affects Their Interactions with Magnetic Nanoparticles

Author

Tay, Andy, Kunze, Anja, Jun, Dukwoo, Hoek, Eric, and Di Carlo, Dino

Subjects
Information and Computing Sciences, Biomedical and Clinical Sciences, Machine Learning, Nanotechnology, Neurosciences, Aging, Bioengineering, Underpinning research, 1.1 Normal biological development and functioning, Neurological, Animals, Cells, Cultured, Chemokine CCL11, Chitosan, Magnetite Nanoparticles, Rats, CCL11/eotaxin, age, conditioned media, cortical neurons, nanoparticles, Nanoscience & Nanotechnology
Abstract

Despite increasing use of nanotechnology in neuroscience, the characterization of interactions between magnetic nanoparticles (MNPs) and primary cortical neural networks remains underdeveloped. In particular, how the age of primary neural networks affects MNP uptake and endocytosis is critical when considering MNP-based therapies for age-related diseases. Here, primary cortical neural networks are cultured up to 4 weeks and with CCL11/eotaxin, an age-inducing chemokine, to create aged neural networks. As the neural networks are aged, their association with membrane-bound starch-coated ferromagnetic nanoparticles (fMNPs) increases while their endocytic mechanisms are impaired, resulting in reduced internalization of chitosan-coated fMNPs. The age of the neurons also negates the neuroprotective effects of chitosan coatings on fMNPs, attributing to decreased intracellular trafficking and increased colocalization of MNPs with lysosomes. These findings demonstrate the importance of age and developmental stage of primary neural cells when developing in vitro models for fMNP therapeutics targeting age-related diseases.

Published
2016

90. High-throughput label-free image cytometry and image-based classification of live Euglena gracilis

Author

Lei, Cheng, Ito, Takuro, Ugawa, Masashi, Nozawa, Taisuke, Iwata, Osamu, Maki, Masanori, Okada, Genki, Kobayashi, Hirofumi, Sun, Xinlei, Tiamsak, Pimsiri, Tsumura, Norimichi, Suzuki, Kengo, Di Carlo, Dino, Ozeki, Yasuyuki, and Goda, Keisuke

Subjects
Biomedical and Clinical Sciences, Engineering, Biomedical Engineering, Physical Sciences, Ophthalmology and Optometry, Atomic, Molecular and Optical Physics, Biotechnology, (100.0100) Image processing, (110.0180) Microscopy, (120.0120) Instrumentation, measurement, and metrology, Optical Physics, Materials Engineering, Ophthalmology and optometry, Biomedical engineering, Atomic, molecular and optical physics
Abstract

We demonstrate high-throughput label-free single-cell image cytometry and image-based classification of Euglena gracilis (a microalgal species) under different culture conditions. We perform it with our high-throughput optofluidic image cytometer composed of a time-stretch microscope with 780-nm resolution and 75-Hz line rate, and an inertial-focusing microfluidic device. By analyzing a large number of single-cell images from the image cytometer, we identify differences in morphological and intracellular phenotypes between E. gracilis cell groups and statistically classify them under various culture conditions including nitrogen deficiency for lipid induction. Our method holds promise for real-time evaluation of culture techniques for E. gracilis and possibly other microalgae in a non-invasive manner.

Published
2016

91. Quantitative Magnetic Separation of Particles and Cells Using Gradient Magnetic Ratcheting

Author

Murray, Coleman, Pao, Edward, Tseng, Peter, Aftab, Shayan, Kulkarni, Rajan, Rettig, Matthew, and Di Carlo, Dino

Subjects
Engineering, Biomedical Engineering, Biotechnology, Bioengineering, Cell Line, Tumor, Cell Separation, Epithelial Cell Adhesion Molecule, Flow Cytometry, Humans, Magnetics, Male, cell manipulation, circulating tumor cells, equilibrium separation, magnetic separation, Nanoscience & Nanotechnology
Abstract

Extraction of rare target cells from biosamples is enabling for life science research. Traditional rare cell separation techniques, such as magnetic activated cell sorting, are robust but perform coarse, qualitative separations based on surface antigen expression. A quantitative magnetic separation technology is reported using high-force magnetic ratcheting over arrays of magnetically soft micropillars with gradient spacing, and the system is used to separate and concentrate magnetic beads based on iron oxide content (IOC) and cells based on surface expression. The system consists of a microchip of permalloy micropillar arrays with increasing lateral pitch and a mechatronic device to generate a cycling magnetic field. Particles with higher IOC separate and equilibrate along the miropillar array at larger pitches. A semi-analytical model is developed that predicts behavior for particles and cells. Using the system, LNCaP cells are separated based on the bound quantity of 1 μm anti-epithelial cell adhesion molecule (EpCAM) particles as a metric for expression. The ratcheting cytometry system is able to resolve a ±13 bound particle differential, successfully distinguishing LNCaP from PC3 populations based on EpCAM expression, correlating with flow cytometry analysis. As a proof-of-concept, EpCAM-labeled cells from patient blood are isolated with 74% purity, demonstrating potential toward a quantitative magnetic separation instrument.

Published
2016

92. Classification of large circulating tumor cells isolated with ultra-high throughput microfluidic Vortex technology

Author

Che, James, Yu, Victor, Dhar, Manjima, Renier, Corinne, Matsumoto, Melissa, Heirich, Kyra, Garon, Edward B, Goldman, Jonathan, Rao, Jianyu, Sledge, George W, Pegram, Mark D, Sheth, Shruti, Jeffrey, Stefanie S, Kulkarni, Rajan P, Sollier, Elodie, and Di Carlo, Dino

Subjects
Biomedical and Clinical Sciences, Oncology and Carcinogenesis, Bioengineering, Cancer, Detection, screening and diagnosis, 4.1 Discovery and preclinical testing of markers and technologies, Adult, Aged, Aged, 80 and over, Breast Neoplasms, Female, High-Throughput Screening Assays, Humans, Lung Neoplasms, Male, Microfluidic Analytical Techniques, Middle Aged, Neoplastic Cells, Circulating, circulating tumor cells, immunofluorescent staining, rare cell enrichment, size based cell isolation, Vortex, Oncology and carcinogenesis
Abstract

Circulating tumor cells (CTCs) are emerging as rare but clinically significant non-invasive cellular biomarkers for cancer patient prognosis, treatment selection, and treatment monitoring. Current CTC isolation approaches, such as immunoaffinity, filtration, or size-based techniques, are often limited by throughput, purity, large output volumes, or inability to obtain viable cells for downstream analysis. For all technologies, traditional immunofluorescent staining alone has been employed to distinguish and confirm the presence of isolated CTCs among contaminating blood cells, although cells isolated by size may express vastly different phenotypes. Consequently, CTC definitions have been non-trivial, researcher-dependent, and evolving. Here we describe a complete set of objective criteria, leveraging well-established cytomorphological features of malignancy, by which we identify large CTCs. We apply the criteria to CTCs enriched from stage IV lung and breast cancer patient blood samples using the High Throughput Vortex Chip (Vortex HT), an improved microfluidic technology for the label-free, size-based enrichment and concentration of rare cells. We achieve improved capture efficiency (up to 83%), high speed of processing (8 mL/min of 10x diluted blood, or 800 μL/min of whole blood), and high purity (avg. background of 28.8±23.6 white blood cells per mL of whole blood). We show markedly improved performance of CTC capture (84% positive test rate) in comparison to previous Vortex designs and the current FDA-approved gold standard CellSearch assay. The results demonstrate the ability to quickly collect viable and pure populations of abnormal large circulating cells unbiased by molecular characteristics, which helps uncover further heterogeneity in these cells.

Published
2016

95. High-Throughput Assessment of Cellular Mechanical Properties

Author

Darling, Eric M and Di Carlo, Dino

Subjects
Cancer, Bioengineering, Generic health relevance, Acoustics, Biomechanical Phenomena, Biomedical Engineering, Cell Separation, Drug Evaluation, Preclinical, Flow Cytometry, High-Throughput Screening Assays, Humans, Hydrodynamics, Immune System Phenomena, Microfluidic Analytical Techniques, Microscopy, Atomic Force, Neoplasms, Optical Phenomena, Optical Tweezers, Osmotic Pressure, Rheology, Single-Cell Analysis, single-cell analysis, inertial microfluidics, mechanical phenotyping, cell sorting, cancer, mechanophenotyping, enrichment
Abstract

Traditionally, cell analysis has focused on using molecular biomarkers for basic research, cell preparation, and clinical diagnostics; however, new microtechnologies are enabling evaluation of the mechanical properties of cells at throughputs that make them amenable to widespread use. We review the current understanding of how the mechanical characteristics of cells relate to underlying molecular and architectural changes, describe how these changes evolve with cell-state and disease processes, and propose promising biomedical applications that will be facilitated by the increased throughput of mechanical testing: from diagnosing cancer and monitoring immune states to preparing cells for regenerative medicine. We provide background about techniques that laid the groundwork for the quantitative understanding of cell mechanics and discuss current efforts to develop robust techniques for rapid analysis that aim to implement mechanophenotyping as a routine tool in biomedicine. Looking forward, we describe additional milestones that will facilitate broad adoption, as well as new directions not only in mechanically assessing cells but also in perturbing them to passively engineer cell state.

Published
2015

97. High efficiency vortex trapping of circulating tumor cells.

Author

Dhar, Manjima, Wong, Jessica, Karimi, Armin, Che, James, Renier, Corinne, Matsumoto, Melissa, Triboulet, Melanie, Garon, Edward B, Goldman, Jonathan W, Rettig, Matthew B, Jeffrey, Stefanie S, Kulkarni, Rajan P, Sollier, Elodie, and Di Carlo, Dino

Subjects
Cancer, Biotechnology, Classical Physics, Interdisciplinary Engineering, Nanotechnology, Nanoscience & Nanotechnology
Abstract

Circulating tumor cells (CTCs) are important biomarkers for monitoring tumor dynamics and efficacy of cancer therapy. Several technologies have been demonstrated to isolate CTCs with high efficiency but achieve a low purity from a large background of blood cells. We have previously shown the ability to enrich CTCs with high purity from large volumes of blood through selective capture in microvortices using the Vortex Chip. The device consists of a narrow channel followed by a series of expansion regions called reservoirs. Fast flow in the narrow entry channel gives rise to inertial forces, which direct larger cells into trapping vortices in the reservoirs where they remain circulating in orbits. By studying the entry and stability of particles following entry into reservoirs, we discover that channel cross sectional area plays an important role in controlling the size of trapped particles, not just the orbital trajectories. Using these design modifications, we demonstrate a new device that is able to capture a wider size range of CTCs from clinical samples, uncovering further heterogeneity. This simple biophysical method opens doors for a range of downstream interventions, including genetic analysis, cell culture, and ultimately personalized cancer therapy.

Published
2015

98. Accelerated wound healing by injectable microporous gel scaffolds assembled from annealed building blocks

Author

Griffin, Donald R, Weaver, Westbrook M, Scumpia, Philip O, Di Carlo, Dino, and Segura, Tatiana

Subjects
Bioengineering, Regenerative Medicine, Biocompatible Materials, Cell Line, Cell Movement, Cell Proliferation, Fibroblasts, Humans, Hydrogels, Materials Testing, Microfluidics, Porosity, Regeneration, Skin, Tissue Engineering, Tissue Scaffolds, Wound Healing, Nanoscience & Nanotechnology
Abstract

Injectable hydrogels can provide a scaffold for in situ tissue regrowth and regeneration, yet gel degradation before tissue reformation limits the gels' ability to provide physical support. Here, we show that this shortcoming can be circumvented through an injectable, interconnected microporous gel scaffold assembled from annealed microgel building blocks whose chemical and physical properties can be tailored by microfluidic fabrication. In vitro, cells incorporated during scaffold formation proliferated and formed extensive three-dimensional networks within 48 h. In vivo, the scaffolds facilitated cell migration that resulted in rapid cutaneous-tissue regeneration and tissue-structure formation within five days. The combination of microporosity and injectability of these annealed gel scaffolds should enable novel routes to tissue regeneration and formation in vivo.

Published
2015

99. Optofluidic fabrication for 3D-shaped particles.

Author

Paulsen, Kevin S, Di Carlo, Dino, and Chung, Aram J

Abstract

Complex three-dimensional (3D)-shaped particles could play unique roles in biotechnology, structural mechanics and self-assembly. Current methods of fabricating 3D-shaped particles such as 3D printing, injection moulding or photolithography are limited because of low-resolution, low-throughput or complicated/expensive procedures. Here, we present a novel method called optofluidic fabrication for the generation of complex 3D-shaped polymer particles based on two coupled processes: inertial flow shaping and ultraviolet (UV) light polymerization. Pillars within fluidic platforms are used to deterministically deform photosensitive precursor fluid streams. The channels are then illuminated with patterned UV light to polymerize the photosensitive fluid, creating particles with multi-scale 3D geometries. The fundamental advantages of optofluidic fabrication include high-resolution, multi-scalability, dynamic tunability, simple operation and great potential for bulk fabrication with full automation. Through different combinations of pillar configurations, flow rates and UV light patterns, an infinite set of 3D-shaped particles is available, and a variety are demonstrated.

Published
2015

100. Flexible and Stretchable Micromagnet Arrays for Tunable Biointerfacing

Author

Tseng, Peter, Lin, Jonathan, Owsley, Keegan, Kong, Janay, Kunze, Anja, Murray, Coleman, and Di Carlo, Dino

Subjects
Engineering, Materials Engineering, Alloys, Crystallization, Dimethylpolysiloxanes, Elastic Modulus, Electroplating, Equipment Design, Equipment Failure Analysis, Magnetic Fields, Magnets, Materials Testing, Microfluidic Analytical Techniques, Miniaturization, Particle Size, biomagnetism, bioseparation, flexible electromagnetics, magnetic droplet, magnetic separation, Physical Sciences, Chemical Sciences, Nanoscience & Nanotechnology, Chemical sciences, Physical sciences
Abstract

A process to surface pattern polydimethylsiloxane (PDMS) with ferromagnetic structures of varying sizes (micrometer to millimeter) and thicknesses (>70 μm) is developed. Their flexibility and magnetic reach are utilized to confer dynamic, additive properties to a variety of substrates, such as coverslips and Eppendorf tubes. It is found that these substrates can generate additional modes of magnetic droplet manipulation, and can tunably steer magnetic-cell organization.

Published
2015

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