Characterization and optimization of variability in a human colonic epithelium culture model.

Animal models have historically been poor preclinical predictors of gastrointestinal (GI) directed therapeutic efficacy and drug-induced GI toxicity. Human stem and primary cell-derived culture systems are a major focus of efforts to create biologically relevant models that enhance preclinical predictive value of intestinal efficacy and toxicity. The inherent variability in stem-cell-based cultures makes development of useful models a challenge; the stochastic nature of stem-cell differentiation interferes with the ability to build and validate reproducible assays that query drug responses and pharmacokinetics. In this study, we aimed to characterize and reduce sources of variability in a complex stem cell-derived intestinal epithelium model, termed RepliGut® Planar, across cells from multiple human donors, cell lots, and passage numbers. Assessment criteria included barrier formation and integrity, gene expression, and cytokine responses. Gene expression and culture metric analyses revealed that controlling cell passage number reduces variability and maximizes physiological relevance of the model. In a case study where passage number was optimized, distinct cytokine responses were observed among four human donors, indicating that biological variability can be detected in cell cultures originating from diverse human sources. These findings highlight key considerations for designing assays that can be applied to additional primary-cell derived systems, as well as establish utility of the RepliGut® Planar platform for robust development of human-predictive drug-response assays.

Animal models are frequently used as tools for studying gastrointestinal (GI) disease, but they poorly replicate the complexities of the human gut limiting the clinical translation of new therapeutics in development. Human stem cell derived models can better recapitulate human GI physiology, but the inherent dynamic nature of stem cells introduces variability in culture performance. We identified sources of variability in the primary stem-cell derived RepliGut® Planar model to develop robust and reliable assays that can improve preclinical therapeutic development for GI disease. Analysis of barrier formation, gene expression, and cytokine responses demonstrated that controlling cell passage number reduces variability and maximizes physiological relevance of the model. These findings highlight key assay design considerations that can be applied to additional primary-cell derived systems. Availability of reliable and physiologically relevant cell-based models can reduce animal testing, improve research accuracy, and make new treatments more relevant and effective for patients.

Characterization and optimization of variability in a human colonic epithelium culture model.

Animal models have historically been poor preclinical predictors of gastrointestinal (GI) directed therapeutic efficacy and drug-induced GI toxicity. Human stem and primary cell-derived culture systems are a major focus of efforts to create biologically relevant models that enhance preclinical predictive value of intestinal efficacy and toxicity. The inherent variability in stem-cell-based complex cultures makes development of useful models a challenge; the stochastic nature of stem-cell differentiation interferes with the ability to build and validate robust, reproducible assays that query drug responses and pharmacokinetics. In this study, we aimed to characterize and reduce potential sources of variability in a complex stem cell-derived intestinal epithelium model, termed RepliGut® Planar, across cells from multiple human donors, cell lots, and passage numbers. Assessment criteria included barrier formation and integrity, gene expression, and cytokine responses. Gene expression and culture metric analyses revealed that controlling for stem/progenitor-cell passage number reduces variability and maximizes physiological relevance of the model. After optimizing passage number, donor-specific differences in cytokine responses were observed in a case study, suggesting biologic variability is observable in cell cultures derived from multiple human sources. Our findings highlight key considerations for designing assays that can be applied to additional primary-cell derived systems, as well as establish utility of the RepliGut® Planar platform for robust development of human-predictive drug-response assays.

Keratose Hydrogel Drives Differentiation of Cardiac Vascular Smooth Muscle Progenitor Cells: Implications in Ischemic Treatment.

Peripheral artery disease (PAD) is a common vascular disorder in the extremity of limbs with limited clinical treatments. Stem cells hold great promise for the treatment of PAD, but their therapeutic efficiency is limited due to multiple factors, such as poor engraftment and non-optimal selection of cell type. To date, stem cells from a variety of tissue sources have been tested, but little information is available regarding vascular smooth muscle cells (VSMCs) for PAD therapy. The present study examines the effects of keratose (KOS) hydrogels on c-kit+/CD31- cardiac vascular smooth muscle progenitor cell (cVSMPC) differentiation and the therapeutic potential of the resultant VSMCs in a mouse hindlimb ischemic model of PAD. The results demonstrated that KOS but not collagen hydrogel was able to drive the majority of cVSMPCs into functional VSMCs in a defined Knockout serum replacement (SR) medium in the absence of differentiation inducers. This effect could be inhibited by TGF-ß1 antagonists. Further, KOS hydrogel increased expression of TGF-ß1-associated proteins and modulated the level of free TGF-ß1 during differentiation. Finally, transplantation of KOS-driven VSMCs significantly increased blood flow and vascular densities of ischemic hindlimbs. These findings indicate that TGF-ß1 signaling is involved in KOS hydrogel-preferred VSMC differentiation and that enhanced blood flow are likely resulted from angiogenesis and/or arteriogenesis induced by transplanted VSMCs.

Keratose hydrogel for tissue regeneration and drug delivery.

Keratin (KRT), a natural fibrous structural protein, can be classified into two categories: "soft" cytosolic KRT that is primarily found in the epithelia tissues (e.g., skin, the inner lining of digestive tract) and "hard" KRT that is mainly found in the protective tissues (e.g., hair, horn). The latter is the predominant form of KRT widely used in biomedical research. The oxidized form of extracted KRT is exclusively denoted as keratose (KOS) while the reduced form of KRT is termed as kerateine (KRTN). KOS can be processed into various forms (e.g., hydrogel, films, fibers, and coatings) for different biomedical applications. KRT/KOS offers numerous advantages over other types of biomaterials, such as bioactivity, biocompatibility, degradability, immune/inflammatory privileges, mechanical resilience, chemical manipulability, and easy accessibility. As a result, KRT/KOS has attracted considerable attention and led to a large number of publications associated with this biomaterial over the past few decades; however, most (if not all) of the published review articles focus on KRT regarding its molecular structure, biochemical/biophysical properties, bioactivity, biocompatibility, drug/cell delivery, and in vivo transplantation, as well as its applications in biotechnical products and medical devices. Current progress that is directly associated with KOS applications in tissue regeneration and drug delivery appears an important topic that merits a commentary. To this end, the present review aims to summarize the current progress of KOS-associated biomedical applications, especially focusing on the in vitro and in vivo effects of KOS hydrogel on cultured cells and tissue regeneration following skin injury, skeletal muscle loss, peripheral nerve injury, and cardiac infarction.

3D bioprinting using hollow multifunctional fiber impedimetric sensors.

3D bioprinting is an emerging biofabrication process for the production of adherent cell-based products, including engineered tissues and foods. While process innovations are rapidly occurring in the area of process monitoring, which can improve fundamental understanding of process-structure-property relations as well as product quality by closed-loop control techniques, in-line sensing of the bioink composition remains a challenge. Here, we report that hollow multifunctional fibers enable in-line impedimetric sensing of bioink composition and exhibit selectivity for real-time classification of cell type, viability, and state of differentiation during bioprinting. Continuous monitoring of the fiber impedance magnitude and phase angle response from 102 to 106 Hz during microextrusion 3D bioprinting enabled compositional and quality analysis of alginate bioinks that contained fibroblasts, neurons, or mouse embryonic stem cells (mESCs). Fiber impedimetric responses associated with the bioinks that contained differentiated mESCs were consistent with differentiation marker expression characterized by immunocytochemistry. 3D bioprinting through hollow multifunctional fiber impedimetric sensors enabled classification of stem cells as stable or randomly differentiated populations. This work reports an advance in monitoring 3D bioprinting processes in terms of in-line sensor-based bioink compositional analysis using fiber technology and provides a non-invasive sensing platform for achieving future quality-controlled bioprinted tissues and injectable stem-cell therapies.

Alginate-based microcapsules generated with the coaxial electrospray method for clinical application.

Alginate-based microencapsulation of cells has made a significant impact on the fields of regenerative medicine and tissue engineering mainly because of its ability to provide immunoisolation for the encapsulated material. This characteristic has allowed for the successful transplantation of non-autologous cells in several clinical trials for life threatening conditions, such as diabetes, myocardial infarction, and neurodegenerative disorders. Methods for alginate hydrogel microencapsulation have been well developed for various types of cells and can generate microcapsules of different diameters, degradation time, and composition. It appears the most prominent and successful method in clinical applications is the coaxial electrospray method, which can be used to generate both homogenous and non-homogeneous microcapsules with uniform size on the order of 100 µm. The present review aims to discuss why alginate hydrogel is an ideal biomaterial for the encapsulation of cells, how alginate-based microcapsules are generated, and methods of modifying the microcapsules for specific clinical treatments. This review will also discuss clinical applications that have utilized alginate-based microencapsulation in the treatment of diabetes, ischemic heart disease, and neurodegenerative diseases.

Keratose Hydrogels Promote Vascular Smooth Muscle Differentiation from C-kit-Positive Human Cardiac Stem Cells.

Stem cell-based therapies have demonstrated great potential for the treatment of cardiac diseases, for example, myocardial infarction; however, low cell viability, low retention/engraftment, and uncontrollable in vivo differentiation after transplantation are still major limitations, which lead to low therapeutic efficiency. Biomaterials provide a promising solution to overcome these issues due to their biocompatibility, biodegradability, low/nonimmunogenicity, and low/noncytotoxicity. The present study aimed to investigate the impacts of keratose (KOS) hydrogel biomaterial on cellular viability, proliferation, and differentiation of c-kit+ human cardiac stem cells (hCSCs). Briefly, hCSCs were cultured on both KOS hydrogel-coated dishes and regular tissue culture dishes (Blank control). Cell viability, stemness, proliferation, cellular morphology, and cardiac lineage differentiation were compared between KOS hydrogel and the Blank control at different time points. We found that KOS hydrogel is effective in maintaining hCSCs without any observable toxic effects, although cell size and proliferation rate appeared smaller on the KOS hydrogel compared to the Blank control. To our surprise, KOS hydrogel significantly promoted vascular smooth muscle cell (VSMC) differentiation (∼72%), while on the Blank control dishes, most of the hCSCs (∼78%) became cardiomyocytes. Furthermore, we also observed "endothelial cell tube-like" microstructures formed by differentiated VSMCs only on KOS hydrogel, suggesting a potential capability of the hCSC-derived VSMCs for in vitro angiogenesis. To the best of our knowledge, this is the first report to discover the preferred differentiation of hCSCs toward VSMCs on KOS hydrogel. The underlying mechanism remains unknown. This innovative methodology may offer a new approach to generate a robust number of VSMCs simply by culturing hCSCs on KOS hydrogel, and the resulting VSMCs may be used in animal studies and clinical trials in combination with an injectable KOS hydrogel to treat cardiovascular diseases.

Impacts of femoral artery and vein excision versus femoral artery excision on the hindlimb ischemic model in CD-1 mice.

BACKGROUND AND AIM: Although femoral artery ligation-induced ischemia is commonly used in C57BL/6 or Balb/c mice, direct comparisons between femoral artery/vein (FAV) versus femoral artery (FA) excisions have not been reported. The goal of the present study is to investigate the effects of FAV versus FA excisions on hindlimb models using adult CD-1 mice. METHODS: Two groups (n=10/group) of adult, mixed gender CD-1 mice were used to generate hindlimb ischemic models by excising either the FAV or FA. Laser Doppler Imaging was used to evaluate blood flow before surgery, immediately after surgery (Day 0), and then on Days 14 and 28. Toe necrosis was checked every 14days while skeletal muscle cellular remodeling and vascular networks were analyzed at the end of the experiment using pathohistological, Dil-vessel painting, and immunohistochemical approaches. RESULTS: During the 4-week period, no statistical differences were found between FAV and FA excision-induced ischemia in terms of reduction of limb blood flow, paw size, number of necrotic toes, or skeletal muscle cell sizes. However, significant increases in centrally-located nuclei cells, adipose cells, diameters of Dil-stained arterioles, and CD31+ capillary densities, but decreases in arteriole densities/lengths were observed in ischemic limbs of both FAV and FA groups compared to control limbs. CONCLUSION: We conclude that FAV and FA excision in CD-1 mice generate a comparable degree of hindlimb ischemia, suggesting that, as expected, FAV is no more severe than FA. These findings may provide important information for researchers when selecting ligation methods for their hindlimb models.