Galactosylated cellulosic sponge for multi-well drug safety testing

Hepatocyte spheroids can maintain mature differentiated functions, but collide to form bulkier structures when in extended culture. When the spheroid diameter exceeds 200 μm, cells in the inner core experience hypoxia and limited access to nutrients and drugs. Here we report the development of a thin galactosylated cellulosic sponge to culture hepatocytes in multi-well plates as 3D spheroids, and constrain them within a macroporous scaffold network to maintain spheroid size and prevent detachment. The hydrogel-based soft sponge conjugated with galactose provided suitable mechanical and chemical cues to support rapid formation of hepatocyte spheroids with a mature hepatocyte phenotype. The spheroids tethered in the sponge showed excellent maintenance of 3D cell morphology, cell-cell interaction, polarity, metabolic and transporter function and/or expression. For example, cytochrome P450 (CYP1A2, CYP2B2 and CYP3A2) activities were significantly elevated in spheroids exposed to β-naphthoflavone, phenobarbital, or pregnenolone-16α-carbonitrile, respectively. The sponge also exhibits minimal drug absorption compared to other commercially available scaffolds. As the cell seeding and culture protocols are similar to various high-throughput 2D cell-based assays, this platform is readily scalable and provides an alternative to current hepatocyte platforms used in drug safety testing applications.     

The effect of dimensionality on growth and differentiation of neural progenitors from different regions of fetal rat brain in vitro: 3-dimensional spheroid versus 2-dimensional monolayer culture

Three-dimensional (3-D) spheroids are widely used for culturing cells. However, 2-dimensional (2-D) monolayer cultures have also been adopted for culture and used in a broad range of cell biology studies. To address the effect of dimensionality on the growth and differentiation of neuroprogenitor cells in 3-D spheroids and 2-D monolayer cultures, cells were isolated from cerebral cortex, cerebella and brainstem of fetal rat brain then cultured in serum-free DMEM/F12 medium or DMEM with 10% FBS. The growth and differentiation of neuroprogenitor cells from three brain regions in spheroids was compared with that in monolayer cultures, and the differentiation components of neuroprogenitor cells were compared with in vivo brain sections. Neuroprogenitor cells in spheroids proliferate actively over 10 days in culture as showed by Ki67 incorporation and increase in spheroid diameter. More neuroprogenitor cells underwent neuronal differentiation in spheroids than in monolayer cultures. In comparison with fixed rat brain sections, the neuron to astrocyte ratio, as shown by neurofilament to glial fibrillary acidic protein immunoreactivity, in spheroids is similar to that found in adult rat tissue sections. Our results suggest that the spheroid culture system mimics the in vivo cytoarchitecture to a greater extent and more closely reflects the cellular composition in adult brain tissue. This supports the notion that the intercellular niche in spheroids is more favorable for the survival and differentiation of neuronal precursors, while the cues in monolayer cultures may favor glial cell survival. It is therefore concluded that dimensionality plays a significant role in determining cellular behavior in vitro.     

High-throughput generation of spheroids using magnetic nanoparticles for three-dimensional cell culture

Various attempts have been made to develop three-dimensional (3-D) cell culture methods because 3-D cells mimic the structures and functional properties of real tissue compared with those of monolayer cultures. Here, we report on a highly simple and efficient 3-D spheroid generation method based on a magnetic pin-array system to concentrate magnetic nanoparticle-incorporated cells in a focal direction. This system was comprised only of external magnets and magnetically induced iron pins to generate a concentrated magnetic field for attracting cells in a focused direction. 3-D spheroid generation was achieved simply by adding magnetic nanoparticle-incorporated cells into a well and covering the plate with a magnetic lid. Cell clustering occurred rapidly within 5 min and created more compact cells with time through the focused magnetic force. This system ensured not only reproducible and size-controlled generation of spheroids but also versatile types of spheroids such as random mixed, core–shell, and fused spheroids, providing a very useful tool for various biological applications.     

Microfluidic self-assembly of tumor spheroids for anticancer drug discovery

Creating multicellular tumor spheroids is critical for characterizing anticancer treatments since it may provide a better model than monolayer culture of in vivo tumors. Moreover, continuous dynamic perfusion allows the establishment of physiologically relevant drug profiles to exposed spheroids. Here we present a physiologically inspired design allowing microfluidic self-assembly of spheroids, formation of uniform spheroid arrays, and characterizations of spheroid dynamics all in one platform. Our microfluidic device is based on hydrodynamic trapping of cancer cells in controlled geometries and the formation of spheroids is enhanced by maintaining compact groups of the trapped cells due to continuous perfusion. It was found that spheroid formation speed (average of 7 h) and size uniformity increased with increased flow rate (up to 10 μl min⁻¹). A large amount of tumor spheroids (7,500 spheroids per square centimeter) with a narrow size distribution (10 ± 1 cells per spheroid) can be formed in the device to provide a good platform for anticancer drug assays. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users. Liz Y. Wu and Dino Di Carlo contributed equally to this work.     

A method for the effective formation of hepatocyte spheroids using a biodegradable polymer nanosphere

Cultures of hepatocytes in spheroid form are known to maintain higher cell viability and exhibit better hepatocyte functions than those in monolayer cultures. In this study, a method for the formation of hepatocyte spheroids was developed using biodegradable polymer nanospheres. The addition of poly(lactic-co-glycolic acid) nanospheres to hepatocyte cultures in spinner flasks increased the efficiency of hepatocyte spheroid formation (the number of cells in spheroids divided by the total cell number) as compared with hepatocyte cultures without nanospheres (control). The viability and mitochondrial activity of the hepatocyte spheroids in the nanosphere-added cultures were significantly higher than those in the control. In addition, the mRNA expression levels of albumin and phenylalanine hydroxylase, both of which are hepatocyte-specific proteins, were significantly higher in the nanosphere-added cultures than in the control. This new culture method improves upon the conventional method of forming hepatocyte spheroids in terms of spheroid formation efficiency, cell viability, and hepatocyte function.     

Tethered spheroids as an in vitro hepatocyte model for drug safety screening

Hepatocyte spheroids mimic many in vivo liver-tissue phenotypes but increase in size during extended culture which limits their application in drug testing applications. We have developed an improved hepatocyte 3D spheroid model, namely tethered spheroids, on RGD and galactose-conjugated membranes using an optimized hybrid ratio of the two bioactive ligands. Cells in the spheroid configuration maintained 3D morphology and uncompromised differentiated hepatocyte functions (urea and albumin production), while the spheroid bottom was firmly tethered to the substratum maintaining the spheroid size in multi-well plates. The oblate shape of the tethered spheroids, with an average height of 32 μm, ensured efficient nutrient, oxygen and drug access to all the cells within the spheroid structure. Cytochrome P450 induction by prototypical inducers was demonstrated in the tethered spheroids and was comparable or better than that observed with hepatocyte sandwich cultures. These data suggested that tethered 3D hepatocyte spheroids may be an excellent alternative to 2D hepatocyte culture models for drug safety applications.     

Acquisition of epithelial–mesenchymal transition and cancer stem-like phenotypes within chitosan-hyaluronan membrane-derived 3D tumor spheroids

Cancer drug development has to go through rigorous testing and evaluation processes during pre-clinical in vitro studies. However, the conventional two-dimensional (2D) in vitro culture is often discounted by the insufficiency to present a more typical tumor microenvironment. The multicellular tumor spheroids have been a valuable model to provide more comprehensive assessment of tumor in response to therapeutic strategies. Here, we applied chitosan-hyaluronan (HA) membranes as a platform to promote three-dimensional (3D) tumor spheroid formation. The biological features of tumor spheroids of human non-small cell lung cancer (NSCLC) cells on chitosan-HA membranes were compared to those of 2D cultured cells in vitro. The cells in tumor spheroids cultured on chitosan-HA membranes showed higher levels of stem-like properties and epithelial–mesenchymal transition (EMT) markers, such as NANOG, SOX2, CD44, CD133, N-cadherin, and vimentin, than 2D cultured cells. Moreover, they exhibited enhanced invasive activities and multidrug resistance by the upregulation of MMP2, MMP9, BCRC5, BCL2, MDR1, and ABCG2 as compared with 2D cultured cells. The grafting densities of HA affected the tumor sphere size and mRNA levels of genes on the substrates. These evidences suggest that chitosan-HA membranes may offer a simple and valuable biomaterial platform for rapid generation of tumor spheroids in vitro as well as for further applications in cancer stem cell research and cancer drug screening.     

Enhanced insulin secretion of physically crosslinked pancreatic β-cells by using a poly(ethylene glycol) derivative with oleyl groups

A polymeric crosslinker was developed to promote the formation of cellular spheroids. Our approach was based on the crosslinking of cell membrane using a polymeric crosslinker that worked via hydrophobic interaction. The crosslinker, a poly(ethylene glycol) derivative with oleyl groups as a hydrophobic group at both ends, was synthesized and characterized by gel permeation chromatography and Fourier-transform infrared spectroscopy. Cell culture experiments were then performed to confirm spheroid formation. The rat pancreatic islet β-cell line RIN, which possesses the ability to secrete insulin, was cultured with the crosslinker in a round-bottomed 96-well plate. The formation of a spheroid was achieved when the crosslinker was added to the cell suspension, especially in the absence of serum. The size of the spheroid decreased with time and with increasing crosslinker concentration, and depended on the number of cells plated in each well. The number of cells cultured with crosslinker was almost constant during 7 days and hardly proliferated in crosslinker concentrations of 0–2.5 mg ml^?1, while the number of cells showed a decrease in the 25 mg ml^?1 crosslinker concentration. It was shown that the insulin protein secretion in the spheroid cultured with crosslinker for 1 week was enhanced. The cell adhesion protein E-cadherin mRNA expression of the resulting spheroid was also enhanced. These results indicate that the promoted cell function was due to the cell–cell and cell–matrix interactions in the spheroid, suggesting that this polymeric crosslinker was useful for the formation of cell spheroids.     

Stable immobilization of rat hepatocyte spheroids on galactosylated nanofiber scaffold

Primary rat hepatocytes self-assemble into multi-cellular spheroids and maintain differentiated functions when cultured on a two-dimensional (2-D) substrate conjugated with galactose ligand. The aim of this study is to investigate how a functional nanofiber scaffold with surface-galactose ligand influences the attachment, spheroid formation and functional maintenance of rat hepatocytes in culture, as compared with the functional 2-D substrate. Highly porous nanofiber scaffolds comprising of fibers with an average diameter of 760 nm were prepared by electrospinning of poly(epsilon-caprolactone-co-ethyl ethylene phosphate) (PCLEEP), a novel biodegradable copolymer. Galactose ligand with a density of 66 nmol/cm(2) was achieved on the nanofiber scaffold via covalent conjugation to a poly(acrylic acid) spacer UV-grafted onto the fiber surface. Hepatocytes cultured on the galactosylated PCLEEP nanofiber scaffold exhibited similar functional profiles in terms of cell attachment, ammonia metabolism, albumin secretion and cytochrome P450 enzymatic activity as those on the functional 2-D substrate, although their morphologies are different. Hepatocytes cultured on galactosylated PCLEEP film formed 50-300 microm spheroids that easily detached from surface upon agitation, whereas hepatocytes cultured on galactosylated nanofiber scaffold formed smaller aggregates of 20-100 microm that engulfed the functional nanofibers, resulting in an integrated spheroid-nanofiber construct.     

Receding cytochrome P450 activity in disassembling hepatocyte spheroids.

Primary rat hepatocytes can self-assemble to form multicellular spheroids when plated onto Primaria petri dishes or suspended in stirred vessels. These spheroids exhibit prolonged viability, enhanced liver-specific functions and differentiated ultrastructure compared to monolayer cultures. Upon transfer to collagen coated surface, or upon the addition of fetal bovine serum (FBS) to the culture, these spheroids began to disassemble and spread on the surface. The dynamics of cytochrome P450 CYP1A1/2 activity in the course of spheroid disassembly was examined in situ by detection of the fluorescent product, resorufin, of ethoxyresorufin O-dealkylation. Optical sectioning of the disassembling spheroids by confocal microscopy demonstrated that hepatocytes that reverted to monolayer exhibited markedly lower CYP1A1/2 activity than those that remained in a multilayered structure. This occurred whether the disassembly was caused by incubation with FBS-containing medium or by cultivation on a collagen-coated surface. When spheroids were cultured on the surface of agar, the disassembly process was retarded even in the presence of FBS. However, even in those intact spheroids, the exposure to FBS markedly decreased CYP1A1/2 activity. The decreased CYP1A1/2 activity was correlated to a diminished smooth endoplasmic reticulum as seen in the transmission electron micrograph. The results clearly demonstrate that the disassembly of hepatocyte spheroids led to decreased CYP1A1/2 activity. Furthermore, FBS contained a factor that caused CYP1A1/2 to decrease even in intact spheroids.     

Ezrin and BCAR1/p130Cas mediate breast cancer growth as 3-D spheroids

CAS proteins and Ezrin, Radixin, Moesin (ERM) family members act as intracellular scaffolds and are involved in interactions with the cytoskeleton, respectively. Both protein families have previously been associated with metastasis and poor prognosis in cancer. Our group recently reported on the overexpression of EZR/VIL2 and BCAR1 and their protein products in breast carcinoma effusions compared to primary breast carcinoma. In the present study, the role of these two proteins was studied in semi-normal MCF10A cells and metastatic MDA-MB-231 breast carcinoma cells cultured in tri-dimensional (3-D) conditions that were hypothesized to reproduce the in vivo conditions of breast cancer metastasis. MCF10A cells formed spheroid-shaped colonies without any Matrigel invasion, while MDA-MB-231 cells displayed an invasive phenotype and showed satellite projections that bridged multiple cell colonies in 3-D culture. E-cadherin was expressed in MCF10A, but not in MDA-MB-231 cells. The temporal expression of ezrin and BCAR1/p130Cas at the mRNA and protein level differed in the two cell lines upon 3-D culturing on Matrigel. Upregulation of BCAR1/p130cas was observed in the transition of MDA-MB-231 from attached to detached culture. Silencing of Ezrin and p130Cas in MDA-MB-231 cells by short hairpin RNA resulted in decreased invasive potential, and p130Cas silencing further resulted in smaller spheroid/colony formation. Our data show that MCF10A and MDA-MB-231 cells differ in their ability to form spheroids, in expression of E-cadherin and in the expression of Ezrin and BCAR1/p130Cas in 3-D cultures on Matrigel, suggesting a role in tumor progression in breast carcinoma.     

Establishment of self-organization system in rapidly formed multicellular heterospheroids

Multicellular heterospheroids including two or more cell types have some tissue/organ properties and can be used in cell-to-cell interaction studies. However, the spheroid formation is difficult to control because the adhesion efficacy is different in each cell type. To solve this, we applied a rapid cell-to-cell adhesion method, avidin-biotin (AB) binding, to spheroid formation. Introduction of avidin or biotin molecules to the cell surfaces of Mile Sven 1 (MS1) cells promoted formation of spheroid in minutes. This method allowed the construction of heterospheroids having homogenous distributions of different cell types. Interestingly, cells showed self-organization and MS1 cells formed networks with Hep G2 cells. NIH3T3 cells also remodeled when mixed with Hep G2 cells. In contrast, a combination of MS1 and NIH3T3 cells failed to show pattern formation, indicating that self-organization was based on the composition of cell types. Actin polymerization not cell proliferation was the dominant factor in remodeling of heterospheroids in the first 24?h. We also demonstrated the self-organization of spheroids comprising three different cell types. The new technology to assemble cells is important not only to study cell-to-cell interaction but also to make three-dimensional complicated tissues.     

Microfluidic device flow field characterization around tumor spheroids with tunable necrosis produced in an optimized off-chip process

Tumor spheroids are a 3-D tumor model that holds promise for testing cancer therapies in vitro using microfluidic devices. Tailoring the properties of a tumor spheroid is critical for evaluating therapies over a broad range of possible indications. Using human colon cancer cells (HCT-116), we demonstrate controlled tumor spheroid growth rates by varying the number of cells initially seeded into microwell chambers. The presence of a necrotic core in the spheroids could be controlled by changing the glucose concentration of the incubation medium. This manipulation had no effect on the size of the tumor spheroids or hypoxia in the spheroid core, which has been predicted by a mathematical model in computer simulations of spheroid growth. Control over the presence of a necrotic core while maintaining other physical parameters of the spheroid presents an opportunity to assess the impact of core necrosis on therapy efficacy. Using micro-particle imaging velocimetry (micro-PIV), we characterize the hydrodynamics and mass transport of nanoparticles in tumor spheroids in a microfluidic device. We observe a geometrical dependence on the flow rate experienced by the tumor spheroid in the device, such that the “front” of the spheroid experiences a higher flow velocity than the “back” of the spheroid. Using fluorescent nanoparticles, we demonstrate a heterogeneous accumulation of nanoparticles at the tumor interface that correlates with the observed flow velocities. The penetration depth of these nanoparticles into the tumor spheroid depends on nanoparticle diameter, consistent with reports in the literature.     

The influence of spheroid formation of human adipose-derived stem cells on chitosan films on stemness and differentiation capabilities

Adipose-derived stem cells (ASCs) have valuable applications in regenerative medicine, but maintaining the stemness of ASCs during in vitro culture is still a challenging issue. In this study, human ASCs spontaneously formed three-dimensional spheroids on chitosan films. Most ASCs within the spheroid were viable, and the cells produced more extracellular molecules, like laminin and fibronectin. Comparing to monolayer culture, ASC spheroids also exhibited enhanced cell survival in serum deprivation condition. Although cell proliferation was inhibited in spheroids, ASCs readily migrated out and proliferated upon transferring spheroids to another adherent growth surface. Moreover, spheroid-derived ASCs exhibited higher expansion efficiency and colony-forming activity. Importantly, we demonstrated that spheroid formation of human ASCs on chitosan films induced significant upregulation of pluripotency marker genes (Sox-2, Oct-4 and Nanog). By culturing the ASC spheroids in proper induction media, we found that ASC differentiation capabilities were significantly enhanced after spheroid formation, including increased transdifferentiation efficiency into neuron and hepatocyte-like cells. In a nude mice model, we further showed a significantly higher cellular retention ratio of ASC spheroids after intramuscular injection of spheroids and dissociated ASCs. These results suggested that ASCs cultured as spheroids on chitosan films can increase their therapeutic potentials.     

Differential expression of CD44(S) and variant isoforms v3, v10 in three-dimensional cultures of mouse melanoma cell lines

Multi-cellular spheroids (MCS) generated from tumor cells serve as excellent in vitro models for understanding the mechanisms of tumor progression and micro-metastasis. We have compared the expression of molecular markers with reference to their growth as conventional adherent monolayers (2-D) and anchorage independent cultures (3-D) using two mouse melanoma cell lines, B16F10 and Clone M3. The two cell lines differed in their ability to form spheroids with respect to their aggregation potential, with B16F10 forming large clusters compared to Clone M3. A panel of molecular markers comprising cell adhesion molecules, cyclin dependent kinase inhibitors and members of the cadherin–catenin complex were analyzed by flow cytometry in 2-D and 3-D cultures. There was a distinct difference in the patterns of expression of CD44(S) and variant isoforms v3,v10 in spheroids compared to cells grown as monolayers in both cell lines. Also, there was an increase in cells positive for CDK inhibitor p27 in 3-D cultures from the B16F10 cell line. The expression of alpha and gamma catenin was down regulated in spheroids. As these molecules are implicated in the regulation of cell proliferation, alterations in the expression of these molecules in 3-D cultures compared to their 2-D counterparts suggests the importance of spheroids as experimental model for tumorigenesis. This revised version was published online in July 2006 with corrections to the Cover Date.