3D Stem Cell Culture Research Articles

High-content imaging of 3D-cultured neural stem cells on a 384-pillar plate for the assessment of cytotoxicity

The assessment of neurotoxicity has been performed traditionally with animals. However, in vivo studies are highly expensive and time-consuming, and often do not correlate to human outcomes. Thus, there is a need for cost-effective, high-throughput, highly predictive alternative in vitro test methods based on early markers of mechanisms of toxicity. High-content imaging (HCI) assays performed on three-dimensionally (3D) cultured cells could provide better understanding of the mechanism of toxicity needed to predict neurotoxicity in humans. However, current 3D cell culture systems lack the throughput required for screening neurotoxicity against a large number of chemicals. Therefore, we have developed miniature 3D neural stem cell (NSC) culture on a unique 384-pillar plate, which is complementary to conventional 384-well plates. Mitochondrial membrane impairment, intracellular glutathione level, cell membrane integrity, DNA damage, and apoptosis have been tested against 3D-cultured ReNcell VM on the 384-pillar plate with four model compounds rotenone, 4-aminopyridine, digoxin, and topotecan. The HCI assays performed in 3D-cultured ReNcell VM on the 384-pillar plates were highly robust and reproducible as indicated by the average Z′ factor of 0.6 and CV values around 12%. From concentration-response curves and IC50 values, mitochondrial membrane impairment appears to be the early stage marker of cell death by the compounds.

Thiolated gellan gum hydrogels as a peptide delivery system for 3D neural stem cell culture

Stem cell therapies are believed to hold promises for a wide range of neurodegenerative diseases but suffer from the harsh local microenvironment. Here we develop a gellan gum (GG)-based hydrogel that serves as a 3D platform for neural stem cell culture and sustained release of peptide to promote transplant stem cell survival and differentiation. The thiolated GG (TGG) maintains the temperature-sensitive gelation properties of GG while providing binding sites to the peptide for sustained release. TGG hydrogels combined with laminin promote survival of encapsulated human neural stem cells. This TGG hydrogel can serve as a therapeutic adjunct in a stem cell therapy through selective control of stem cell survival and differentiation.

Bioinspired poly (γ-glutamic acid) hydrogels for enhanced chondrogenesis of bone marrow-derived mesenchymal stem cells

While peptide-directed scaffolds now serve as well-established platforms for biomimetic three-dimensional (3D) extracellular matrices (ECM), challenges still remain for chondrogenesis through direct mediation of stem cells. Here, biocompatible poly (γ-glutamic acid) (γ-PGA) hydrogels with robust mechanical properties were developed based on methacrylate-γ-PGA (γ-PGA-GMA) and cysteamine functionalized γ-PGA (γ-PGA-SH) for cartilage regeneration. The γ-PGA hydrogels demonstrated good self-crosslinking property as well as tunability through conjugation between active thiol groups of γ-PGA-SH and methacrylate moieties of γ-PGA-GMA. The mechanical property, porous structure, swelling, and degradation process of the hydrogels could be controlled by adjusting modified γ-PGA polymers component. The rheological behavior and compression test of γ-PGA hydrogels illustrated a wide processing range in addition to superb mechanical properties. These γ-PGA hydrogels showed excellent elasticity as well as toughness, withstanding more than 70% of mechanical strain. Meanwhile, the stress modulus of γ-PGA hydrogels could be up to 749 kPa. We also studied γ-PGA hydrogels as scaffolds for the 3D culture and chondrogenesis differentiation of rabbit bone marrow-derived mesenchymal stem cells (BMSCs) in vitro. In a rabbit auricular cartilage defect model, BMSCs-laden hydrogel effectively promoted chondrogenesis. Based on these findings, biomimetic γ-PGA-based hydrogels hold promising application as favorable scaffold biomaterials for cartilage tissue regeneration.

Lotus seedpod-inspired hydrogels as an all-in-one platform for culture and delivery of stem cell spheroids

3D culture of stem cells can improve therapeutic effects. However, there is limited research on how to deliver cultured stem cell spheroids to the desired target. Here, we developed lotus seedpod-inspired hydrogel (LoSH) containing microwells for culture and delivery of stem cell spheroids. Human adipose-derived stem cells (hADSCs) inside the square microwells (200 or 400 μm in width with various depths) spontaneously formed spheroids with high viability (94.08 ± 1.56%), and fibronectins conjugated to the hydrogel successfully gripped the spheroids, similar to the funiculus gripping seeds in the lotus seedpod. The spheroids slightly bound to the LoSH surface at 37 °C were detached by the expansion of LoSH at lower temperature of 4 °C. After spheroid formation, LoSH was placed on the target substrate upside-down, expanded at 4 °C for 10 min, and removed from the target. As a result, the spheroids within the microwell were successfully transferred to the target substrate with high transfer efficiency (93.78 ± 2.30%). A delivery of spheroids from LoSH to full-thickness murine skin wound with chimney model showed significant enhancement of the number of SMA-positive vessels at day 21 compared to the group received the same number of spheroids by injection. Together, our findings demonstrate LoSH as a one-step platform that can culture and deliver spheroids to a large target area, which will be useful for various biomedical applications.

99mTc-Hydroxydiphosphonate quantification of extracellular matrix mineralization in 3D human mesenchymal stem cell cultures.

ObjectivesBone tissue engineering is one of the fastest growing branches in modern bioscience. New methods are being developed to achieve higher grades of mineral deposition by osteogenically inducted mesenchymal stem cells. In addition to well established monolayer cell culture models, 3D cell cultures for stem cell-based osteogenic differentiation have become increasingly attractive to promote in vivo bone formation. One of the main problems of scaffold-based osteogenic cell cultures is the difficulty in quantifying the amount of newly produced extracellular mineral deposition, as a marker for new bone formation, without destroying the scaffold. In recent studies, we were able to show that 99mTc-methylene diphosphonate (99mTc-MDP), a gamma radiation-emitting radionuclide, can successfully be applied as a reliable quantitative marker for mineral deposition as this tracer binds with high affinity to newly produced hydroxyapatite (HA).MethodsWithin the present study, we evaluated whether this promising new method, using 99mTc-hydroxydiphosphonate (99mTc-HDP), can be used to quantify the amount of newly formed extracellular HA in a 3D cell culture model. Highly porous collagen type II scaffolds were seeded with 1 × 106 human mesenchymal stem cells (hMSCs; n = 6) and cultured for 21 days in osteogenic media (group A – osteogenic (OSM) group) and in parallel in standard media (group B – negative control (CNTRL) group). After incubation with 99mTc-HDP, the tracer uptake, reflected by the amount of emitted gamma counts, was measured.ResultsWe saw a higher uptake (up to 15-fold) of the tracer in the OSM group A compared with the CNTRL group B. Statistical analysis of the results (Student`s t-test) revealed a significantly higher amount of emitted gamma counts in the OSM group (p = 0.048). Qualitative and semi-quantitative analysis by Alizarin Red staining confirmed the presence of extracellular HA deposition in the OSM group.ConclusionOur data indicate that 99mTc-HDP labelling is a promising tool to track and quantify non-destructive local HA deposition in 3D stem cell cultures.Cite this article: T. L. Grossner, U. Haberkorn, T. Gotterbarm. 99mTc-Hydroxydiphosphonate quantification of extracellular matrix mineralization in 3D human mesenchymal stem cell cultures. Bone Joint Res 2019;8:333–341. doi: 10.1302/2046-3758.87.BJR-2017-0248.R1.

Optimized peptide functionalization of thiol‐acrylate emulsion‐templated porous polymers leads to expansion of human pluripotent stem cells in 3D culture

ABSTRACTHighly porous polymers produced by polymerization of the continuous phase of a high internal phase emulsion have been developed as scaffolds for 3D culture of human pluripotent stem cells. These emulsion‐templated polymerized high internal phase emulsion (polyHIPE) materials have an interconnected network of pores that provide support for the cells, while also allowing both cell ingress and nutrient diffusion. Thiol‐acrylate polyHIPE materials were prepared by photopolymerization, which, due to a competing acrylate homopolymerization process, leads to a material with residual surface thiols. These thiols were then used as a handle to allow postpolymerization functionalization with both maleimide and a maleimide‐derivatized cyclo‐RGDfK peptide, via Michael addition under benign conditions. Functionalization was evaluated using an Ellman's colorimetric assay, to monitor the residual thiol concentration, and X‐ray photoelectron spectroscopy. Maleimide was used as a model molecule to optimize conditions prior to peptide‐functionalization. The use of triethylamine as a catalyst and a mixed ethanol‐aqueous solvent system led to optimized reaction between surface‐bound thiols and maleimide. Peptide‐functionalized materials showed improved attachment and infiltration of human pluripotent stem cells over 7 days, demonstrating their promise as a scaffold for 3D stem cell culture and expansion. © 2019 Wiley Periodicals, Inc. J. Polym. Sci., Part A: Polym. Chem. 2019, 57, 1974–1981

Bioinspired Hydrogels for 3D Organoid Culture.

Organoids have stepped into the limelight as unique in vitro systems for modeling organ development, function and disease. This review provides a perspective on how chemically defined, bio-inspired hydrogels could be used for replacing ill-defined matrices derived from the native extracellular matrix (ECM) that are used for generating organoids in 3D stem cell culture. In particular, we propose the use of self-healing and light-responsive matrices that should afford control over the inherently stochastic self-organization process that currently underlies organoid morphogenesis. Such designer ECMs could accelerate the translation of organoid technology from the laboratory into various real-life applications.

Collagen Based Multicomponent Interpenetrating Networks as Promising Scaffolds for 3D Culture of Human Neural Stem Cells, Human Astrocytes, and Human Microglia.

This work describes for the first time the fabrication and characterization of multicomponent interpenetrating networks composed of collagenI, hyaluronic acid, and poly(ethylene glycol) diacrylate for the 3D culture of human neural stem cells, astrocytes, and microglia. The chemical composition of the scaffolds can be modulated while maintaining values of complex moduli within the range of the mechanical performance of brain tissue (∼6.9 kPa) and having cell viability exceeding 84%. The developed scaffolds are a promising new family of biomaterials that can potentially serve as 3Din vitro models for studying the physiology and physiopathology of the central nervous system.

Biomimetic microspheres for 3D mesenchymal stem cell culture and characterization

Stem cells reside in niches, specialized microenvironments that sustain and regulate their fate. Extracellular matrix (ECM), paracrine factors or other cells are key niche regulating elements. As the conventional 2D cell culture lacks these elements, it can alter the properties of naïve stem cells. In this work we designed a novel biomimetic microenvironment for cell culture, consisting of magnetic microspheres, prepared with acrylates and acrylic acid copolymers and functionalized with fibronectin or hyaluronic acid as ECM coatings. To characterize cell proliferation and adhesion, porcine mesenchymal stem cells (MSCs) were grown with the different microspheres. The results showed that the 3D environments presented similar proliferation to the 2D culture and that fibronectin allows cell adhesion, while hyaluronic acid hinders it. In the 3D environments, cells reorganize the microspheres to grow in aggregates, highlighting the advantages of microspheres as 3D environments and allowing the cells to adapt the environment to their requirements.

Engineering hydrogels with affinity-bound laminin as 3D neural stem cell culture systems.

Laminin incorporation into biological or synthetic hydrogels has been explored to recapitulate the dynamic nature and biological complexity of neural stem cell (NSC) niches. However, the strategies currently explored for laminin immobilization within three-dimensional (3D) matrices do not address a critical aspect influencing cell-matrix interactions, which is the control over laminin conformation and orientation upon immobilization. This is a key feature for the preservation of the protein bioactivity. In this work, we explored an affinity-based approach to mediate the site-selective immobilization of laminin into a degradable synthetic hydrogel. Specifically, a four-arm maleimide terminated poly(ethylene glycol) (PEG-4MAL) macromer was functionalized with a mono-PEGylated recombinant human N-terminal agrin (NtA) domain, to promote high affinity binding of laminin. Different NtA concentrations (10, 50 and 100 μM) were used to investigate the impact of NtA density on laminin incorporation, hydrogel biophysical properties, and biological outcome. Laminin was efficiently incorporated for all the conditions tested (laminin incorporation >95%), and the developed hydrogels revealed mechanical properties (average storage modulus (G') ranging from 187 to 256 Pa) within the values preferred for NSC proliferation and neurite branching and extension. Affinity-bound laminin PEG-4MAL hydrogels better preserve laminin bioactivity, compared to unmodified hydrogels and hydrogels containing physically entrapped laminin, this effect being dependent on NtA concentration. This was evidenced by the 10 μM NtA-functionalized PEG-4MAL gels incorporating laminin that support enhanced human NSC proliferation and neurite extension, compared to the latter. Overall, this work highlights the potential of the proposed engineered matrices to be used as defined 3D platforms for the establishment of artificial NSC niches and as extracellular matrix-mimetic microenvironments to support human NSC transplantation.

Development of extracellular matrix supported 3D culture of renal cancer cells and renal cancer stem cells

Novel experimental conditions of cancer cell line culture have evolved throughout the recent years, with significantly growing interest in xeno-free, serum-free and three-dimensional culture variants. The choice of proper culture media may enable to mimic tumor microenvironment and promotion of cancer stem cells proliferation. To assess whether stem-like phenotype inducing media may be applied in renal cancer stem cell research, we performed a widespread screening of 13 cell culture media dedicated for mesenchymal cells, stem cells as well as mesenchymal stem cells. We have also screened extracellular matrix compounds and selected optimal RCC 3D—ECM supported culture model. Our results revealed that 786-O as well as HKCSCs cell line cultures in xeno-free media (NutriStem/StemXvivo) and laminin coated plates provide a useful tool in RCC cancer biology research and at the same time enable effective drug toxicity screening. We propose bio-mimic 3D RCC cell culture model with specific low-serum and xeno-free media that promote RCC cell viability and stem-like phenotype according to the tested genes encoding stemness factors including E-cadherin, N-cadherin, HIF1, HIF2, VEGF, SOX2, PAX2 and NESTIN.

Synthesis of Entirely Protein-Based Hydrogels by Enzymatic Oxidation Enabling Water-Resistant Bioadhesion and Stem Cell Encapsulation.

Growing complexity in modern surgery and guided tissue repair calls for new materials capable of dual functions-water-resistant adhesion to biological tissues and stem cell encapsulation/delivery. Here, we demonstrate the creation of entirely recombinant protein-based adhesive hydrogels by leveraging the sequence derived from natural adhesive molecules-mussel foot protein-3 (Mfp-3), in vitro enzymatic oxidation mediated by recombinant tyrosinase and genetically encoded SpyTag/SpyCatcher chemistry. The resulting materials exhibited varied stiffness dependent on the polymer concentration, strong water-resistant adhesion to porcine skin, and excellent compatibility with 3D stem cell culture. The presence of SpyCatcher domains within the protein networks also enabled postgelation decoration with SpyTagged proteins under mild physiological conditions. These results point to a new approach for designing genetically programmable materials that enable both water-resistant bioadhesion and stem cell encapsulation for biomedical applications.

High-throughput identification of factors promoting neuronal differentiation of human neural progenitor cells in microscale 3D cell culture.

Identification of conditions for guided and specific differentiation of human stem cell and progenitor cells is important for continued development and engineering of in vitro cell culture systems for use in regenerative medicine, drug discovery, and human toxicology. Three-dimensional (3D) and organotypic cell culture models have been used increasingly for in vitro cell culture because they may better model endogenous tissue environments. However, detailed studies of stem cell differentiation within 3D cultures remain limited, particularly with respect to high-throughput screening. Herein, we demonstrate the use of a microarray chip-based platform to screen, in high-throughput, individual and paired effects of 12 soluble factors on the neuronal differentiation of a human neural progenitor cell line (ReNcell VM) encapsulated in microscale 3D Matrigel cultures. Dose-response analysis of selected combinations from the initial combinatorial screen revealed that the combined treatment of all-trans retinoic acid (RA) with the glycogen synthase kinase 3 inhibitor CHIR-99021 (CHIR) enhances neurogenesis while simultaneously decreases astrocyte differentiation, whereas the combined treatment of brain-derived neurotrophic factor and the small azide neuropathiazol enhances the differentiation into neurons and astrocytes. Subtype specification analysis of RA- and CHIR-differentiated cultures revealed that enhanced neurogenesis was not biased toward a specific neuronal subtype. Together, these results demonstrate a high-throughput screening platform for rapid evaluation of differentiation conditions in a 3D environment, which will aid the development and application of 3D stem cell culture models.

Programming Niche Accessibility and In Vitro Stemness with Intercellular DNA Reactions.

Stem cells generally exist in low abundance and tend to lose stemness in the absence of self-renewal signals. While extracellular-matrix-mimicking techniques have been developed to support stem cell proliferation, the lack of niche cells in these synthetic systems often hampers continuous stem cell expansion and maintenance of pluripotency, which are indispensable for regenerative medicine. Here, an intercellular DNA-reaction-programmed ESPN (expansion of stem cells with pairing niches) strategy is developed for 3D culture of mammary stem cells (MaSCs). Boolean logic operations are implemented to confer DNA-programmed mechanical signaling and genetically engineered morphogen signaling by niche cells, resulting in sustained expansion of MaSCs in vitro. The creation of stem cell niches improves the proliferation of pluripotent cells by four times during one-week culture. This method thus provides a novel approach for logical regulation of stemness and proliferation of stem cells for biomedicine.

Exosomes Produced from 3D Cultures of MSCs by Tangential Flow Filtration Show Higher Yield and Improved Activity.

Exosomes can deliver therapeutic RNAs to neurons. The composition and the safety profile of exosomes depend on the type of the exosome-producing cell. Mesenchymal stem cells are considered to be an attractive cell type for therapeutic exosome production. However, scalable methods to isolate and manufacture exosomes from mesenchymal stem cells are lacking, a limitation to the clinical translation of exosome technology. We evaluate mesenchymal stem cells from different sources and find that umbilical cord-derived mesenchymal stem cells produce the highest exosome yield. To optimize exosome production, we cultivate umbilical cord-derived mesenchymal stem cells in scalable microcarrier-based three-dimensional (3D) cultures. In combination with the conventional differential ultracentrifugation, 3D culture yields 20-fold more exosomes (3D-UC-exosomes) than two-dimensional cultures (2D-UC-exosomes). Tangential flow filtration (TFF) in combination with 3D mesenchymal stem cell cultures further improves the yield of exosomes (3D-TFF-exosomes) 7-fold over 3D-UC-exosomes. 3D-TFF-exosomes are seven times more potent in small interfering RNA (siRNA) transfer to neurons compared with 2D-UC-exosomes. Microcarrier-based 3D culture and TFF allow scalable production of biologically active exosomes from mesenchymal stem cells. These findings lift a major roadblock for the clinical utility of mesenchymal stem cell exosomes.

3D Culture of Bone Marrow-Derived Mesenchymal Stem Cells (BMSCs) Could Improve Bone Regeneration in 3D-Printed Porous Ti6Al4V Scaffolds.

Mandibular bone defect reconstruction is an urgent challenge due to the requirements for daily eating and facial aesthetics. Three-dimensional- (3D-) printed titanium (Ti) scaffolds could provide patient-specific implants for bone defects. Appropriate load-bearing properties are also required during bone reconstruction, which makes them potential candidates for mandibular bone defect reconstruction implants. However, in clinical practice, the insufficient osteogenesis of the scaffolds needs to be further improved. In this study, we first encapsulated bone marrow-derived mesenchymal stem cells (BMSCs) into Matrigel. Subsequently, the BMSC-containing Matrigels were infiltrated into porous Ti6Al4V scaffolds. The Matrigels in the scaffolds provided a 3D culture environment for the BMSCs, which was important for osteoblast differentiation and new bone formation. Our results showed that rats with a full thickness of critical mandibular defects treated with Matrigel-infiltrated Ti6Al4V scaffolds exhibited better new bone formation than rats with local BMSC injection or Matrigel-treated defects. Our data suggest that Matrigel is able to create a more favorable 3D microenvironment for BMSCs, and Matrigel containing infiltrated BMSCs may be a promising method for enhancing the bone formation properties of 3D-printed Ti6Al4V scaffolds. We suggest that this approach provides an opportunity to further improve the efficiency of stem cell therapy for the treatment of mandibular bone defects.

3D culture of neural stem cells within conductive PEDOT layer-assembled chitosan/gelatin scaffolds for neural tissue engineering

Neural stem cells (NSCs), as a self-renewing and multipotent cell population, have been widely studied for never regeneration. Engineering scaffold is one of the important factors to regulate NSCs proliferation and differentiation towards the formation of the desired cells and tissues. Because neural cells are electro-active ones, a conductive scaffold is required to provide three-dimensional cell growth microenvironments and appropriate synergistic cell guidance cues. In this study, a poly (3,4‑ethylenedioxythiophene)/chitosan/gelatin (PEDOT/Cs/Gel) scaffold was prepared via in situ interfacial polymerization, with a nanostructured layer of PEDOT assembling on the channel surface of porous Cs/Gel scaffold. This electrically conductive, three-dimensional, porous and biodegradable PEDOT/Cs/Gel scaffold was used as a novel scaffold for NSCs three-dimension (3D) culture in vitro. It was found that the layer of PEDOT on the channel surface of Cs/Gel scaffolds could greatly promote NSCs adhesion and proliferation. Additionally, under the differentiation condition, the protein and gene analysis suggested that PEDOT/Cs/Gel scaffolds could significantly enhance the NSCs differentiation towards neurons and astrocytes with the up-regulation of β tubulin-III and GFAP expression. In conclusion, these results demonstrated that the PEDOT/Cs/Gel scaffolds as an electrically conductive scaffold could not only promote NSCs adhesion and proliferation but also enhance NSCs differentiation into neurons and astrocytes with higher protein and gene expression. PEDOT-assembled Cs/Gel scaffold will be a promising conductive substrate for NSCs research and neural tissue engineering.

Abstract B40: Model liver cancer metastasis using 3D spheroids derived from primary tumors in liver cancer genetic mouse models

Abstract Introduction: Liver cancer, predominantly hepatocellular carcinoma (HCC) in adults, has become the fastest-growing cause of cancer death in the United States. Most cases of HCC are diagnosed at the metastatic stage and have a 5-year survival rate below 3%. Liver cancer in children, most commonly hepatoblastoma (HB), has a better prognosis than in adults, but the 5-year survival falls from 70% to 30% if the tumor has disseminated. Without basic research into the biology of liver cancer metastasis, cure rates for this disease are unlikely to improve. Preclinical mouse models have played a central role in linking basic and translational cancer research. However, current mouse models of liver cancer have mostly addressed the early stages of the disease and have rarely focused on its metastatic forms. Accurate model systems of liver cancer metastasis are urgently needed to elucidate the associated cellular and molecular mechanisms. Methods: Metastasis-initiating cells often hijack normal stem cell pathways to gain survival and growth advantages. Recent advances in 3D stem cell spheroid culture have provided a means to rapidly select and propagate cancer cells with stemness potential for in-depth biologic analysis. We have previously generated two liver cancer genetic mouse models (GMMs) of HCC and HB, both of which developed frequent primary tumors in the liver but only rare metastases. Our laboratory recently developed a robust protocol for growing liver cancer spheroids (LCSs) from primary tumors in the two GMM using 3D stem cell culture. To evaluate the in vivo tumorigenicity of the LCSs, we developed a novel ultrasound-guided, noninvasive intrahepatic injection method for transplanting cells into the liver with high accuracy and minimal animal manipulation. Results: We found that a subset of LCSs from each model exhibited potent tumorigenicity, driving widespread metastases in vivo upon orthotopic transplant. Gene set enrichment analysis demonstrated substantial enrichment of a number of metastatic and recurrent human HCC gene signatures in the LCS-driven HCC tumors and the enrichment of a human HB gene signature in the LCS-driven HB tumors. A large RNA-seq transcriptomic analysis revealed a significant enrichment of inflammatory and extracellular processes in the metastatic LCSs and tumors they generated compared to their nonmetastatic counterparts in both models, suggesting a critical role of tumor microenvironment (TME) in liver cancer metastasis. Conclusion: Our LCS-based approach to model liver cancer metastasis represents a unique strategy to model liver cancer metastasis by using primary tumors from non- or low-metastatic GMMs, an approach that can potentially be extended to other cancer types, considering the rapid advances in cancer spheroid studies across a wide range of solid malignant tumors. It also permits rapid mechanistic studies of liver cancer metastasis in the future by allowing gene manipulation in vitro within a uniform population of tumor-derived, metastasis-initiating LCSs, with subsequent tracking of metastasis development in transplantation models to be built in disease-relevant TMEs. Citation Format: Liyuan Li, Maoxiang Qian, David Finkelstein, Melissa Johnson, Dolores H. López-Terrada, Liqin Zhu. Model liver cancer metastasis using 3D spheroids derived from primary tumors in liver cancer genetic mouse models [abstract]. In: Proceedings of the AACR Special Conference: Advances in Modeling Cancer in Mice: Technology, Biology, and Beyond; 2017 Sep 24-27; Orlando, Florida. Philadelphia (PA): AACR; Cancer Res 2018;78(10 Suppl):Abstract nr B40.

Looking into the Future: Toward Advanced 3D Biomaterials for Stem-Cell-Based Regenerative Medicine.

Stem-cell-based therapies have the potential to provide novel solutions for the treatment of a variety of diseases, but the main obstacles to such therapies lie in the uncontrolled differentiation and functional engraftment of implanted tissues. The physicochemical microenvironment controls the self-renewal and differentiation of stem cells, and the key step in mimicking the stem cell microenvironment is to construct a more physiologically relevant 3D culture system. Material-based 3D assemblies of stem cells facilitate the cellular interactions that promote morphogenesis and tissue organization in a similar manner to that which occurs during embryogenesis. Both natural and artificial materials can be used to create 3D scaffolds, and synthetic organic and inorganic porous materials are the two main kinds of artificial materials. Nanotechnology provides new opportunities to design novel advanced materials with special physicochemical properties for 3D stem cell culture and transplantation. Herein, the advances and advantages of 3D scaffold materials, especially with respect to stem-cell-based therapies, are first outlined. Second, the stem cell biology in 3D scaffold materials is reviewed. Third, the progress and basic principles of developing 3D scaffold materials for clinical applications in tissue engineering and regenerative medicine are reviewed.

Efficient and cost-effective generation of hepatocyte-like cells through microparticle-mediated delivery of growth factors in a 3D culture of human pluripotent stem cells

Biomedical application of human pluripotent stem cell-derived hepatocyte-like cells (hPSC-HLCs) relies on efficient large-scale differentiation, which is commonly performed by a suspension culture of three-dimensional (3D) multicellular spheroids in bioreactors. However, this approach requires large amounts of growth factors (GFs) and the need to overcome limited diffusional transport posed by the inherent 3D structure of hPSC spheroids. Here, we have hypothesized that localized delivery of GFs by incorporation of GF-laden degradable polymeric microparticles (MPs) within the hPSC spheroids would circumvent such limitations. In this study, GFs for hepatocytic differentiation were encapsulated in gelatin-coated poly (l-lactic acid)/poly (DL-lactic-co-glycolic acid) (PLLA/PLGA) MPs which were subsequently incorporated into the hPSC spheroids. Gene expression analyses demonstrated that MP delivery of the GFs resulted in similar expression levels of hepatocytic markers despite the use of 10-fold less total GFs. The differentiated HLCs in the MP group exhibited ultrastructure and functional characteristics comparable with the conventional soluble GF group. The generated HLCs in the MP group were successfully engrafted in an acute liver injury mouse model and maintained hepatocytic function after implantation. These results suggested that sustained and localized delivery of GFs using MPs might offer a novel approach towards scalable technologies for hepatocytic differentiation and engineer a better 3D microenvironment for cells.