Maria Sobolev

A polymer microstructure array for the formation, culturing, and high throughput drug screening of breast cancer spheroids.

Multicellular spheroid models have been recognized as superior to monolayer cell cultures in antitumor drug screening, but their commercial adaptation in the pharmaceutical industry has been delayed, primarily due to technological limitations. The current study presents a new spheroid culture platform that addresses these technical restrictions. The new culturing device is based on a multiwell plate equipped with a glass bottom patterned with an array of UV adhesive microchambers. Each microchamber is designed to accommodate a single spheroid. The system facilitates the simultaneous creation and culturing of a large number of spheroids, as well as screening their response to antitumor drugs. The volume of the spheroids is easily controlled by seeding density. The location of each spheroid is preserved in the same microchamber throughout its growth, treatment with soluble agents, and imaging. The growth ratio parameter, a non-intrusive size analysis of the same spheroid before and after exposure to drugs, was found to be a sensitive indicator for the reaction of MCF7 breast cancer spheroids to cytotoxic drugs. This feature helps reveal the heterogeneity within the spheroid population during the formation process and their drug response, and provides an opportunity to detect specific, highly active or drug-resistant spheroid sub-groups. The advantages of this spheroid-based system make it an efficient drug-screening tool that may be valuable to related fields of research and clinical applications.

Polymer live-cell array for real-time kinetic imaging of immune cells

Direct quantitative experimental investigations of the function of lymphocytes and other immune cells are challenging due to the cell mobility and the complexity of intercellular communications. In order to facilitate such investigations, an in vitro system is required that is noninvasive and provides kinetic data on cellular responses to challenges such as drug treatments. The present work reports the development of a disposable, inexpensive polymer-made device, the Polymer Live Cell Array (PLCA), for real-time, kinetic analysis of immune cells. The PLCA proved to be optically and biologically compatible, thus individual immune cells can be observed and treated independently without being tethered. The cells share a common space which facilitates cellular communications via secreted molecules or via direct intercellular interactions. These properties facilitate real-time, non-intrusive, repeated measurements of immune cells under multiple experimental treatments.

Correlative Analyses of Nitric Oxide Generation Rates and Nitric Oxide Synthase Levels in Individual Cells Using a Modular Cell-Retaining Device

Nitric oxide (NO) is recognized as one of the major immune system agents involved in the pathogenesis and control of various diseases that may benefit from novel drug development, by exploiting NO signaling pathways and targets. This calls for detection of both intracellular levels of NO and expression of its synthesizing enzymes (NOS) in individual, intact, living cells. Such measurements are challenging, however, due to short half-life, low and fluctuating concentrations of NO, cellular heterogeneity, and inability to trace the same cells over time. The current study presents a device and methodology for correlative analysis of NO generation rates and NOS levels in the same individual cells, utilizing fluorescent imaging followed by immunohistochemistry (IHC). U937 promonocyte cell populations demonstrated significant heterogeneity in their baseline levels, in NO-generation kinetics, and in their response rates to stimuli. Individual cell analysis exposed cell subgroups which showed enhanced NO production upon stimulation, concomitantly with significant up-regulation of inducible NOS (iNOS) levels. Exogenous NO modulated the expression of iNOS in nondifferentiated cells within 1 h, in a dose-dependent manner, while treatment with lysophosphatidylcholine (LPC) enhanced the expression of iNOS, demonstrating a nondependence on NO production.

The individual-cell-based cryo-chip for the cryopreservation, manipulation and observation of spatially identifiable cells. II: Functional activity of cryopreserved cells

BackgroundThe cryopreservation and thawing processes are known to induce many deleterious effects in cells and might be detrimental to several cell types. There is an inherent variability in cellular responses among cell types and within individual cells of a given population with regard to their ability to endure the freezing and thawing process. The aim of this study was to evaluate the fate of cryopreserved cells within an optical cryo apparatus, the individual-cell-based cryo-chip (i3C), by monitoring several basic cellular functional activities at the resolution of individual cells.ResultsIn the present study, U937 cells underwent the freezing and thawing cycle in the i3C device. Then a panel of vital tests was performed, including the number of dead cells (PI staining), apoptotic rate (Annexin V staining), mitochondrial membrane potential (TMRM staining), cytoplasm membrane integrity and intracellular metabolism (FDA staining), as well as post-thawing cell proliferation assays. Cells that underwent the freezing - thawing cycle in i3C devices exhibited the same functional activity as control cells. Moreover, the combination of the multi-parametric analysis at a single cell resolution and the optical and biological features of the device enable an accurate determination of the functional status of individual cells and subsequent retrieval and utilization of the most valuable cells.ConclusionsThe means and methodologies described here enable the freezing and thawing of spatially identifiable cells, as well as the efficient detection of viable, specific, highly biologically active cells for future applications.

The individual-cell-based cryo-chip for the cryopreservation, manipulation and observation of spatially identifiable cells. I: Methodology

BackgroundCryopreservation is the only widely applicable method of storing vital cells for nearly unlimited periods of time. Successful cryopreservation is essential for reproductive medicine, stem cell research, cord blood storage and related biomedical areas. The methods currently used to retrieve a specific cell or a group of individual cells with specific biological properties after cryopreservation are quite complicated and inefficient.ResultsThe present study suggests a new approach in cryopreservation, utilizing the Individual Cell-based Cryo-Chip (i3C). The i3C is made of materials having appropriate durability for cryopreservation conditions. The core of this approach is an array of picowells, each picowell designed to maintain an individual cell during the severe conditions of the freezing - thawing cycle and accompanying treatments. More than 97% of cells were found to retain their position in the picowells throughout the entire freezing - thawing cycle and medium exchange. Thus the comparison between pre-freezing and post-thawing data can be achieved at an individual cell resolution. The intactness of cells undergoing slow freezing and thawing, while residing in the i3C, was found to be similar to that obtained with micro-vials. However, in a fast freezing protocol, the i3C was found to be far superior.ConclusionsThe results of the present study offer new opportunities for cryopreservation. Using the present methodology, the cryopreservation of individual identifiable cells, and their observation and retrieval, at an individual cell resolution become possible for the first time. This approach facilitates the correlation between cell characteristics before and after the freezing - thawing cycle. Thus, it is expected to significantly enhance current cryopreservation procedures for successful regenerative and reproductive medicine.

Real-time quantification of protein expression and translocation at individual cell resolution using imaging-dish-based live cell array.

AbstractCell populations represent intrinsically heterogeneous systems with a high level of spatiotemporal complexity. Monitoring and understanding cell-to-cell diversity is essential for the research and application of intra- and interpopulation variations. Optical analysis of live cells is challenging since both adherent and nonadherent cells change their spatial location. However, most currently available single-cell techniques do not facilitate treatment and monitoring of the same live cells over time throughout multistep experiments. An imaging-dish-based live cell array (ID-LCA) has been developed and produced for cell handling, culturing, and imaging of numerous live cells. The dish is composed of an array of pico scale cavities—pico wells (PWs) embossed on its glass bottom. Cells are seeded, cultured, treated, and spatiotemporally measured on the ID-LCA, while each cell or small group of cells are locally constrained in the PWs. Finally, predefined cells can be retrieved for further evaluation. Various types of ID-LCAs were used in this proof-of-principle work, to demonstrate on-ID-LCA transfection of fluorescently tagged chimeric proteins, as well as the detection and kinetic analysis of their induced translocation. High variability was evident within cell populations with regard to protein expression levels as well as the extent and dynamics of protein redistribution. The association of these parameters with cell morphology and functional parameters was examined. Both the new methodology and the device facilitate research of the translocation process at individual cell resolution within large populations and thus, can potentially be used in high-throughput fashion. Graphical Abstractᅟ

The use of sequential staining for detection of heterogeneous intracellular response of individual Jurkat cells to lysophosphatidylcholine

Living cells are known to exhibit great morphological, functional, spatial and temporal heterogeneity. Hence, the study of cells in a bulk, whether this bulk is homogenous or heterogeneous, does not provide sufficiently detailed or interpretable results. An advantageous approach would rather be a comprehensive study of cell biological activity in single isolated living cells. In this study, we present an imaging approach for studying pre-apoptotic and very early apoptotic events, during cell death induced by lysophosphatidylcholine (LPC) at the single cell level. The aim of this study is to investigate intracellular events, such as the mitochondrial membrane potential (MMP) and reactive oxygen species (ROS) formation, before and immediately after LPC introduction to the lymphocytes at the level of individual cells. A new protocol of sequential staining was developed to study the relation between early apoptosis signs (PS externalization), MMP changes and intracellular ROS production rates at an individual Jurkat cell resolution. Simultaneous kinetic assessments of MMP, intracellular ROS levels and phosphatidylserine (PS) externalization were performed at a single cell resolution, using Optical LiveCell™ Array technology and image analysis. The parameters were measured and analyzed both before and during exposure to inducers in a Jurkat cell population, including three groups of single cells: spontaneous apoptotic cells, induced apoptotic cells and fully functional living cells. Exogenous LPC caused a heterogeneous intracellular response among Jurkat cells immediately after its introduction. Subgroups of cells with opposite changes of MMP and different kinetics of ROS increase, were revealed within the whole cell population. The subset of apoptosis-induced Jurkat cells, which became apoptotic within 3h after the LPC introduction, exhibited higher initial MMP compared to fully functional or spontaneous apoptotic cells. LPC-induced apoptosis was accompanied by a concomitant increase in intracellular ROS levels. In the present study, a method is described to assess the intracellular events in cells which were initially different in their physiological status. The individual T lymphocytes (Jurkat cells) in vitro have various susceptibilities to LPC effects at the very early stage of contact with the inducer. The apoptotic effect of LPC in individual Jurkat cells is associated with a relatively higher initial MMP before the introduction of the inducer and with a faster ROS formation within the affected cells. Such divergence may be significant in regulating the balance of lymphocyte subsets in pathological sites, either maintaining or preventing the inflammation components of atherosclerosis. We conclude that the presented approach provides the researcher, not only with the cell retaining methodology, but with opportunities to observe and find the distinctive cell subsets within the whole cell population as well, thus helping to define more exactly the role and importance of such sub-populations in physiological or pathological conditions.

In Situ Evaluation of Physiological Activity and Mitochondrial Dysfunction viaNovo Label-Free Measures Based on Fluctuation of Image Gray Values

Characteristics of spatiotemporal fluctuation of gray values at a single-pixel level within bright field, label free image of a cell are explored in a variety of physiological and mitochondrial dysfunction states. From these fluctuations, the gray level information entropy (GLIE) is calculated and its derivative measures such as standard deviation, autocorrelation and periodic aspect are analyzed. This is realized by a user-friendly combination of common bright field microscopy and a unique imaging dish, wherein cells are individually held untethered, each within a picoliter volume optical chamber in an array, which allows repeatable spatiotemporal observation before, during and after bio-manipulation in situ, at a single-cell resolution, while in a population. GLIE fluctuation measures were exploited to demonstrate the gradual dying process of serum-deprived cells. Furthermore, these measures were realized in the evaluation of cell response to Phorbol Myristic Acetate (PMA), triiodothyronine (T3) thyroid hormone and mild hypothermia, and three different mitochondrial inhibitors as well: rotenone, carbonyl cyanide m-chlorophenyl hydrazine (CCCP) and oligomycin. The GLIE fluctuation-based measures demonstrated the ability to (a) significantly distinguish cellular response to all six mediators, and (b) identify subgroups of cells according to their response to mild hypothermia. On the whole, employment of high contrast microscopy approaches, i.e., Phase Contrast (PC) and Differential Interference Contrast (DIC), for tracing cellular events via the spatiotemporal fluctuation measures, did not show noticeable advantages over simple Bright Field (BF) microscopy.

Analysis of the Spectroscopic Aspects of Cationic Dye Basic Orange 21.

Spectroscopic properties of cationic dye basic orange 21 (BO21) in solutions, in solids, and within leukocytes were examined. Results obtained with solutions indicate that influence of variables such as pH, viscosity, salt composition, and various proteins on the absorption spectrum of BO21 is negligible. However, in the presence of heparin, a blue shift (484-465 nm) is observed, which is attributed to the aggregation of BO21 on the polyanion. Applying density functional theory demonstrates that in aqueous solutions (a) the formation of BO21 oligomers is thermodynamically favorable, they are oriented in an antiparallel dipolar arrangement, and their binding energies are lower than those of parallel dipolar arrangements, (b) association between BO21 aggregates and heparin is highly favorable, and (c) the blue shift is due to the mixing of π → π* transitions caused by BO21 molecule stacking. However, when embedded in basophils, the absorption spectra of intracellular BO21 is extremely red-shifted, with two peaks (at 505 and 550 nm) found to be attributed to BO21 and the BO21-heparin complex, respectively, which are intracellularly hosted in nonaqueous environments. Initial evidence of the ability to differentiate between leukocyte types by BO21 is presented.

In situ label-free static cytometry by monitoring spatiotemporal fluctuations of image gray values.

Abstract. Spatiotemporal fluctuation of homogeneity and randomness of gray values within an image was explored and utilized as a label-free means for cell examination. This was done by utilizing a user-friendly combination of simple bright field microscope and Cytocapture dish, wherein cells are individually held, each within a picoliter optical chamber, forming an array of cells to be repeatedly measured over time and biomanipulated in situ at single-cell resolution. First, the measured gray level information entropy (GLIE) was used and, based on the fact that living cells are not in a state of thermodynamic equilibrium but rather in a metastable state, two fluctuation-sensitive measures were proposed and examined: ASDE—the spatial average of temporal standard deviation (SD) of GLIE, and AA—the average time autocorrelation of GLIE. System performance was validated on cell-free solutions. This was followed by examining the performance of the measures AGLIE, ASDE, and AA to distinguish among individual live-still, dead and live cells from various cell lines, as well as between cells which were and were not induced to differentiate. Results, which were obtained on four types of cells, indicate advantages of the proposed measures which are believed to be significant additions to the microscope-based probe-free toolbox.