Cell encapsulation using biopolymer gels for regenerative medicine

There has been a consistent increase in the mean life expectancy of the population of the developed world over the past century. Healthy life expectancy, however, has not increased concurrently. As a result we are living a larger proportion of our lives in poor health and there is a growing demand for the replacement of diseased and damaged tissues. While traditionally tissue grafts have functioned well for this purpose, the demand for tissue grafts now exceeds the supply. For this reason, research in regenerative medicine is rapidly expanding to cope with this new demand. There is now a trend towards supplying cells with a material in order to expedite the tissue healing process. Hydrogel encapsulation provides cells with a three dimensional environment similar to that experienced in vivo and therefore may allow the maintenance of normal cellular function in order to produce tissues similar to those found in the body. In this review we discuss biopolymeric gels that have been used for the encapsulation of mammalian cells for tissue engineering applications as well as a brief overview of cell encapsulation for therapeutic protein production. This review focuses on agarose, alginate, collagen, fibrin, hyaluronic acid and gelatin since they are widely used for cell encapsulation. The literature on the regeneration of cartilage, bone, ligament, tendon, skin, blood vessels and neural tissues using these materials has been summarised.     

Microfibrous carriers for cell culture: A comparative study

Small patches of polyethylene terephthalate (PET) nonwoven microfibrous matrices have excellent properties and can be used as carriers for culturing cells in agitated bioreactors. The microfibrous carriers are highly porous and can provide large surface areas and three‐dimensional space for high‐density cell growth. In this work, the microfibrous carriers and several commercial microcarriers were used to study cell attachment kinetics, growth, and monoclonal antibody production with Chinese hamster ovary cells. Compared with commercial solid and macroporous microcarriers, the microfibrous carriers showed better or similar performances. In addition, the microfibrous carriers provided a wider operable range for agitation rate than commercial microcarriers, effectively protecting cells from shear stress and carrier collisions. In addition, the microfibrous carriers are available at a much lower cost than commercial microcarriers, providing an attractive alternative to microcarrier‐based large‐scale cell cultures. © 2011 American Institute of Chemical Engineers Biotechnol. Prog., 2011     

A novel method of encapsulating and cultivating adherent mammalian cells within collagen microcarriers

A novel method of preparing collagen microcarriers was developed and used to entrap adherent cells for cell culturing. This new technique involved seeding of cells in micro gel beads comprised of collagen fibrils dispersed in alginate. The gel beads were washed with phosphate buffered saline (PBS) to remove alginate and the resulting microspheres, about 300-500 microm in diameter, contained evenly distributed collagen fibrils which provided a 3D biomimetic environment for cell growth. The applicability of this microencapsulating system was demonstrated by its ability to support the growth of C2C12 myoblast cells. When seeded and cultured within the 3D collagen microcarriers, the population of C2C12 cells entrapped within the microcarriers increased by 1.5 folds in 7 days after inoculation. This encapsulation technique is potentially useful for culturing cells and especially useful for adherent cells that require a 3D fibrillar collagen environment.     

Scalable culture and cryopreservation of human embryonic stem cells on microcarriers

As a result of their pluripotency and potential for unlimited self‐renewal, human embryonic stem cells (hESCs) hold tremendous promise in regenerative medicine. An essential prerequisite for the widespread application of hESCs is the establishment of effective and efficient protocols for large‐scale cell culture, storage, and distribution. At laboratory scales hESCs are cultured adherent to tissue culture plates; these culture techniques are labor‐intensive and do not scale to high cell numbers. In an effort to facilitate larger scale hESC cultivation, we investigated the feasibility of culturing hESCs adherent to microcarriers. We modified the surface of Cytodex 3 microcarriers with either Matrigel or mouse embryonic fibroblasts (MEFs). hESC colonies were effectively expanded in a pluripotent, undifferentiated state on both Matrigel‐coated microcarriers and microcarriers seeded with a MEF monolayer. While the hESC expansion rate on MEF‐microcarriers was less than that on MEF‐plates, the doubling time of hESCs on Matrigel‐microcarriers was indistinguishable from that of hESCs expanded on Matrigel‐coated tissue culture plates. Standard hESC cryopreservation methodologies are plagued by poor viability and high differentiation rates upon thawing. Here, we demonstrate that cryopreservation of hESCs adherent to microcarriers in cryovials provides a higher recovery of undifferentiated cells than cryopreservation of cells in suspension. Together, these results suggest that microcarrier‐based stabilization and culture may facilitate hESC expansion and storage for research and therapeutic applications. © 2009 American Institute of Chemical Engineers Biotechnol. Prog., 2009     

Adenoviral transduction of mesenchymal stem cells: in vitro responses and in vivo immune responses after cell transplantation

Adult mesenchymal stem cells (MSCs) are non-hematopoietic cells with multi-lineage potential which makes them attractive targets for regenerative medicine applications. However, to date, therapeutic success of MSC-therapy is limited and the genetic modification of MSCs using viral vectors is one option to improve their therapeutic potential. Ex-vivo genetic modification of MSCs using recombinant adenovirus (Ad) could be promising to reduce undesired immune responses as Ad will be removed before cell/tissue transplantation. In this regard, we investigated whether Ad-modification of MSCs alters their immunological properties in vitro and in vivo. We found that Ad-transduction of MSCs does not lead to up-regulation of major histocompatibility complex class I and II and co-stimulatory molecules CD80 and CD86. Moreover, Ad-transduction caused no significant changes in terms of pro-inflammatory cytokine expression, chemokine and chemokine receptor and Toll-like receptor expression. In addition, Ad-modification of MSCs had no affect on their ability to suppress T cell proliferation in vitro. In vivo injection of Ad-transduced MSCs did not change the frequency of various immune cell populations (antigen presenting cells, T helper and cytotoxic T cells, natural killer and natural killer T cells) neither in the blood nor in tissues. Our results indicate that Ad-modification has no major influence on the immunological properties of MSCs and therefore can be considered as a suitable gene vector for therapeutic applications of MSCs.     

Biolistic transfection of neuronal cultures using a hand-held gene gun

Biolistic transfection is a technique in which subcellular-sized particles coated with DNA are accelerated to high velocity to propel them into cells. This method is applicable to tissues, cells and organelles, and can be used for both in vitro and in vivo transformations; with the right equipment, it is simple, rapid and efficient. Here we provide a detailed protocol for biolistic transfection of plasmids into cultured human embryonic kidney (HEK) 293 cells and organotypic brain slices using a hand-held gene gun. There are three major steps: (i) coating microcarriers with DNA, (ii) transferring the microcarriers into a cartridge to make a 'bullet', and (iii) firing the DNA-coated microcarriers into cells using a pulse of helium gas. The method can be readily adapted to other cell types and tissues. The protocol can be completed in 1-2 h.     

Induction of osteogenic differentiation of osteoblast-like cells MG-63 during cultivation on fibroin microcarriers

We have developed microcarriers made from silk fibroin. Microcarriers can be used as a substrate for cell cultivation and cell delivery during cell-based therapy and for the construction of bioengineered tissue. Fibroin microcarriers were mineralized, which led to the appearance of calcium phosphate crystals on their surface. The ability of mineralized and nonmineralized microcarriers to support osteogenic differentiation of the osteoblast-like cell line MG-63 was estimated by alkaline phosphatase activity, an early marker of bone formation. The experiment showed cells actively proliferating on the surface of both mineralized and nonmodified microcarriers. Culturing MG-63 on the surface of fibroin microcarriers resulted in an increase of alkaline phosphatase activity indicative of osteogenic differentiation of MG-63 cells in the absence of inductors. The level of alkaline phosphatase was higher when mineralized microcarriers were used. Alkaline phosphatase activity of MG-63 cells cultivated using traditional two-dimensional approaches were close to zero. As opposed to conventional monolayer culturing, microcarrier culture cells are in a three-dimensional environment that is closer to physiological conditions. This can have a significant impact on their morphology and functional properties. During this study, we also characterized mechanical properties of porous scaffolds used for microcarriers.     

Dynamic cell culture on porous biopolymer microcarriers in a spinner flask for bone tissue engineering: a feasibility study

Porous microspherical carriers have great promise for cell culture and tissue engineering. Dynamic cultures enable more uniform cell population and effective differentiation than static cultures. Here we applied dynamic spinner flask culture for the loading and multiplication of cells onto porous biopolymer microcarriers. The abilities of the microcarriers to populate cells and to induce osteogenic differentiation were examined and the feasibility of in vivo delivery of the constructs was addressed. Over time, the porous microcarriers enabled cell adhesion and expansion under proper dynamic culture conditions. Osteogenic markers were substantially expressed by the dynamic cell cultures. The cell-cultured microcarriers implanted in the mouse subcutaneous tissue for 4 weeks showed excellent tissue compatibility, with minimal inflammatory signs and significant induction of bone tissues. This first report on dynamic culture of porous biopolymer microcarriers providing an effective tool for bone tissue engineering.     

聚N-异丙基丙烯酰胺细胞培养平台的研究进展

聚N-异丙基丙烯酰胺(poly(N-isopropylacrylamide),PNIPAAm),温敏性聚合物,可利用其温敏特性替代酶类物质或细胞刮刀用于贴壁细胞的收获,从而有效避免酶解和机械损伤,可为生物医药领域提供品质优良的种子细胞。重点阐述促进细胞有效粘附和快速脱附的温敏性PNIPAAm二维平面的研发情况,包括选取特殊基材、引入亲水基团、调节反应物比率、控制聚合物厚度/密度、提供适宜外力等方式,从而有效改善细胞对温敏性平面的适应性并降低染菌风险以及减少低温处理对细胞的影响。同时介绍PNIPAAm微载体、支架和凝胶等温敏性三维培养介质的研究进展,此方式不仅增加细胞生长面积,更可以模拟体内微环境,从而保持细胞原始生理特征,同时实现大规模扩增和非酶解收获细胞以及组织器官修复和重构的目标。最后简单说明PNIPAAm培养平台的应用,PNIPAAm的研发为再生医学的发展提供了崭新思路。     

Brief exposure to hyperglycemia activates dendritic cells in vitro and in vivo

Dendritic cells are key players in regulating immunity. These cells both activate and inhibit the immune response depending on their cellular environment. Their response to hyperglycemia, a condition common amongst diabetics wherein glucose is abnormally elevated, remains to be elucidated. In this study, the phenotype and immune response of dendritic cells exposed to hyperglycemia were characterized in vitro and in vivo using the streptozotocin-induced diabetes model. Dendritic cells were shown to be sensitive to hyperglycemia both during and after differentiation from bone marrow precursor cells. Dendritic cell behavior under hyperglycemic conditions was found to vary by phenotype, among which, tolerogenic dendritic cells were particularly sensitive. Expression of the costimulatory molecule CD86 was found to reliably increase when dendritic cells were exposed to hyperglycemia. Additionally, hydrogel-based delivery of the anti-inflammatory molecule interleukin-10 was shown to partially inhibit these effects in vivo.     

Modulation of A-NK cell rigidity: In vitro characterization and in vivo implications for cell delivery

The delivery of cells to specific regions of the vasculature is a critical step in many therapeutic strategies. These include the packaging of DNA or RNA in cell "vehicles" for delivery to tissues, the reconstitution of differentiated cells to an organ using embryonic stem cells, and the enhancement of the immune response using effector lymphocytes. In most cases, these cells must be injected systemically. Unfortunately, ex vivo manipulation or activation can affect cell visco-elastic properties, making it difficult for the injected cells to traverse capillary beds. Compounding the problem is the fact that common agents used in the laboratory for increasing cell deformability generally have adverse side effects on the therapeutic potential of the cells. Using micropipet aspiration techniques, cytotoxicity assays and in vivo trafficking studies we show that: (1) the rigidity of injected effector cells directly affects resistance to passage through tissue; (2) modulation of cytoskeletal organization can be used to decrease cell rigidity, but can also compromise therapeutic efficacy; and (3) thioglycollate, an agent which does not influence effector lymphocyte cytotoxic activity, reduces cell rigidity and entrapment in the lungs.     

Suppression of the immune system as a critical step for bone formation from allogeneic osteoprogenitors implanted in rats

The surface marker profile of mesenchymal stromal cells (MSCs) suggests that they can escape detection by the immune system of an allogeneic host. This could be an optimal strategy for bone regeneration applications, where off‐the‐shelf cells could be implanted to heal bone defects. However, it is unknown how pre‐differentiation of MSCs to an osteogenic lineage, a means of improving bone formation, affects their immunogenicity. Using immunohistological techniques in a rat ectopic implantation model, we demonstrate that allogeneic osteoprogenitors mount a T cell‐ and B cell‐mediated immune response resulting in an absence of in vivo bone formation. Suppression of the host immune response with daily administration of an immunosuppressant, FK506, is effective in preventing the immune attack on the allogeneic osteoprogenitors. In the immunosuppressed environment, the allogeneic osteoprogenitors are capable of generating bone in amounts similar to those of syngeneic cells. However, using osteoprogenitors from one of the allogeneic donors led to newly deposited bone that was attacked by the host immune system, despite the continued administration of the immunosuppressant. This suggests that, although using an immunosuppressant can potentially suppress the immune attack on the allogeneic cells, optimizing the dose of the immunosuppressant may be crucial to ensure bone formation within the allogeneic environment. Overall, allografts comprising osteoprogenitors derived from allogeneic MSCs have the potential to be used in bone regeneration applications.     

Development of peptide and protein nanotherapeutics by nanoencapsulation and nanobioconjugation

The targeted delivery of therapeutic peptide by nanocarriers systems requires the knowledge of interactions of nanomaterials with the biological environment, peptide release, and stability of therapeutic peptides. Therapeutic application of nanoencapsulated peptides are increasing exponentially and >1000 peptides in nanoencapsulated form are in different clinical/trial phase. This review covers current scenario of therapeutic protein and peptides encapsulation on polymer to metallic nanocarriers including methods of protein encapsulation, peptide bioconjugation on nanoparticles, stability enhancement of encapsulated proteins and its biomedical applications.     

Attachment and growth of anchorage-dependent cells on a novel, charged-surface microcarrier under serum-free conditions

The present study describes a novel microcarrier substrate consisting of a swellable, copolymer of styrene and divinylbenzene, derivatized with trimethylamine. The co-polymer trimethylamine microcarriers support the growth of a number of different cell lines – Madin Darby Bovine Kidney, Madin-Darby Canine Kidney, Vero and Cos-7 – under serum-free conditions, and human diploid fibroblasts in serum-containing medium. Cells attach to the co- polymer trimethylamine microcarriers as rapidly as they attach to other charged-surface microcarriers (faster than they attach to collagen-coated polystyrene microcarriers) and spread rapidly after attachment. All of the cells examined grow to high density on the co- polymer trimethylamine microcarriers. Furthermore, cells are readily released from the surface after exposure to a solution of trypsin/EDTA. In this respect, the co-polymer trimethylamine microcarriers are different from other charged-surface microcarriers. Madin-Darby Bovine Kidney cells grown on this substrate support production of vaccine strain infectious bovine rhinotracheitis virus as readily as on other charged-surface or collagen-coated microcarriers. Thus, the co-polymer trimethylamine microcarriers combine the positive characteristics of the currently available charged-surface and adhesion-peptide coated microcarriers in a single product. The viral vaccine production industry is undergoing considerable change as manufacturers move toward complete, animal product-free culture systems. This novel substrate should find application in the industry, especially in processes which depend on viable cell recovery. This revised version was published online in August 2006 with corrections to the Cover Date.     

Hydrogel‐based three‐dimensional cell culture for organ‐on‐a‐chip applications

Recent studies have reported that three‐dimensionally cultured cells have more physiologically relevant functions than two‐dimensionally cultured cells. Cells are three‐dimensionally surrounded by the extracellular matrix (ECM) in complex in vivo microenvironments and interact with the ECM and neighboring cells. Therefore, replicating the ECM environment is key to the successful cell culture models. Various natural and synthetic hydrogels have been used to mimic ECM environments based on their physical, chemical, and biological characteristics, such as biocompatibility, biodegradability, and biochemical functional groups. Because of these characteristics, hydrogels have been combined with microtechnologies and used in organ‐on‐a‐chip applications to more closely recapitulate the in vivo microenvironment. Therefore, appropriate hydrogels should be selected depending on the cell types and applications. The porosity of the selected hydrogel should be controlled to facilitate the movement of nutrients and oxygen. In this review, we describe various types of hydrogels, external stimulation‐based gelation of hydrogels, and control of their porosity. Then, we introduce applications of hydrogels for organ‐on‐a‐chip. Last, we also discuss the challenges of hydrogel‐based three‐dimensional cell culture techniques and propose future directions. © 2017 American Institute of Chemical Engineers Biotechnol. Prog., 33:580–589, 2017     

Simplifying the extracellular matrix for 3-D cell culture and tissue engineering: a pragmatic approach

The common technique of growing cells on tissue culture plastic (TCP) is gradually being supplanted by methods for culturing cells in two-dimensions (2-D) on matrices with more appropriate physical and biological properties or by encapsulation of cells in three-dimensions (3-D). The universal acceptance of the new 3-D paradigm is currently constrained by the lack of a biocompatible material in the marketplace that offers ease of use, experimental flexibility, and a seamless transition from in vitro to in vivo applications. In this Prospect, I argue that the standard for 3-D cell culture should be bio-inspired, biomimetic materials that can be used "as is" in drug discovery, toxicology, cell banking, and ultimately in medicine. Such biomaterials must therefore be highly reproducible, manufacturable, approvable, and affordable. To obtain integrated, functional, multicellular systems that recapitulate tissues and organs, the needs of the true end-users-physicians and patients-must dictate the key design criteria. Herein I describe the development of one such material that meets these requirements: a covalently crosslinked, biodegradable, simplified mimic of the extracellular matrix (ECM) that permits 3-D culture of cells in vitro and enables tissue formation in vivo. In contrast to materials that were designed for in vitro cell culture and then found unsuitable for clinical use, these semi-synthetic hyaluronan-derived materials were developed for in vivo tissue repair, and are now being re-engineered for in vitro applications in research.     

Closed system isolation and scalable expansion of human placental mesenchymal stem cells

Mesenchymal stem cells (MSC) are emerging as a leading cellular therapy for a number of diseases. However, for such treatments to become available as a routine therapeutic option, efficient and cost-effective means for industrial manufacture of MSC are required. At present, clinical grade MSC are manufactured through a process of manual cell culture in specialized cGMP facilities. This process is open, extremely labor intensive, costly, and impractical for anything more than a small number of patients. While it has been shown that MSC can be cultivated in stirred bioreactor systems using microcarriers, providing a route to process scale-up, the degree of numerical expansion achieved has generally been limited. Furthermore, little attention has been given to the issue of primary cell isolation from complex tissues such as placenta. In this article we describe the initial development of a closed process for bulk isolation of MSC from human placenta, and subsequent cultivation on microcarriers in scalable single-use bioreactor systems. Based on our initial data, we estimate that a single placenta may be sufficient to produce over 7,000 doses of therapeutic MSC using a large-scale process.     

3D Bone tissue engineered with bioactive microspheres in simulated microgravity

Three-dimensional (3D) osteoblast cell cultures were obtained in rotating-wall vessels (RWV), simulating microgravity. Three types of bioactive microcarriers, specifically modified bioactive glass particles, bioceramic hollow microspheres, and biodegradable bioactive glass-polymer composite microspheres, were developed and used with osteoblasts. The surfaces of composite microspheres fully transformed into bone apatite after 2-wk immersion in simulated physiological fluid, which demonstrated their bone-bonding ability. The motion of microcarriers in RWVs was photographically recorded and numerically analyzed. The trajectories of hollow microspheres showed that they migrated and eventually stayed around at the central region of the RWV. At their surfaces, shear stresses were low. In contrast, solid glass or polymer particles moved toward and finally bounced off the outer wall of the RWVs. Cell culture studies in the RWV using bone marrow stromal cells showed that the cells attached to and formed 3D aggregates with the hollow microspheres. Extracellular matrix and mineralization were observed in the aggregates. Cell culture studies also confirmed the ability of the composite microspheres to support 3D bone-like tissue formation. These data suggest that the new hollow bioceramic microspheres and degradable composite microspheres can be used as microcarriers for 3D bone tissue engineering in microgravity. They also have potential applications as drug delivery systems.     

Mitoxantrone induces natural killer cell maturation in patients with secondary progressive multiple sclerosis

Mitoxantrone is one of the few drugs approved for the treatment of progressive multiple sclerosis (MS). However, the prolonged use of this potent immunosuppressive agent is limited by the appearance of severe side effects. Apart from its general cytotoxic effect, the mode of action of mitoxantrone on the immune system is poorly understood. Thus, to develop safe therapeutic approaches for patients with progressive MS, it is essential to elucidate how mitoxantrone exerts it benefits. Accordingly, we initiated a prospective single-arm open-label study with 19 secondary progressive MS patients. We investigated long-term effects of mitoxantrone on patient peripheral immune subsets using flow cytometry. While we corroborate that mitoxantrone persistently suppresses B cells in vivo, we show for the first time that treatment led to an enrichment of neutrophils and immunomodulatory CD8(low) T cells. Moreover, sustained mitoxantrone applications promoted not only persistent NK cell enrichment but also NK cell maturation. Importantly, this mitoxantrone-induced NK cell maturation was seen only in patients that showed a clinical response to treatment. Our data emphasize the complex immunomodulatory role of mitoxantrone, which may account for its benefit in MS. In particular, these results highlight the contribution of NK cells to mitoxantrone efficacy in progressive MS.     

肿瘤患者CD8+T细胞中CD28表达的研究进展

CD28与B7结合形成的共刺激信号是T细胞激活的第二信号,肿瘤患者CD8^＋T细胞上CD28分子在肿瘤免疫中发挥着重要作用。人体抗肿瘤免疫主要由CD8^＋T细胞介导,根据CD28的表达与否可将CD8^＋T细胞分为细胞毒T细胞（CD8^＋CD28^＋,CTL）和抑制性T细胞（CD8^＋C28^-,Ts）。CTL是体内杀伤肿瘤细胞的主要功能性细胞之一,当该细胞与肿瘤接触时,通过共刺激信号而被激活,发挥其对肿瘤细胞的杀伤作用;Ts在机体的免疫耐受中发挥作用。现就肿瘤患者CD8^＋T细胞上CD28的表达作一综述。