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Automation needed to truly scale cell therapies, Lonza – Bioprocess Insider – BioProcess Insider

Lonza says it has achieved a significant milestone with the first patient being treated with a CD19 CAR-T cell immunotherapy made using its automated point-of-care Cocoon technology.

In March 2019, Swiss CDMO Lonza entered a partnership with Israels Sheba Medical Center to provide automated and closed CAR-T manufacturing using its point-of-care (POC) Cocoon cell therapy manufacturing platform.

This week, Sheba and Lonza announced the first patient has been dosed with a CD19 CAR-T cell immunotherapy made using the technology in a phase II cancer trial.

Image: iStock/Duncan_Andison

Shebas ongoing immunotherapy program has already treated 100 oncology patients with its CAR-T CD19 therapy with good clinical success. The therapy is currently manufactured at the point-of-care using an open, clinically validated manual process. However, this first patient to be treated with a Cocoon-made CAR-T is significant as it demonstrates the potential of the Lonzas system in scaling up the manufacture of cell therapies, Eytan Abraham, head of Personalized Medicine at Lonza, said.

The ultimate goal of this, as well as other cell and gene therapies, is to treat large patient populations, he told Bioprocess Insider. The Cocoon platform represents an ideal solution for Sheba, solving the shortage of resources e.g., manpower, clean room space and manufacturing bandwidth.

A further ten patients will be tested with the Cocoon-manufactured CAR-T candidate, he added, before the results are reviewed by the Israeli Ministry of Health.

Assuming this goes well, the intention is that Sheba transitions to using the Cocoon for all CAR-T manufacturing, he continued, though noted that with a process change for any candidate being investigated in an ongoing clinical trial Sheba will need to show product comparability and receive approval from the Israeli Ministry of Health.

A full clinical comparability study confirmed that the product produced in the current manual process is indeed comparable to the product produced in the Cocoon platform.

Developed by Octane Biotech, Lonza began working with the system in 2015 to help develop the platform for autologous cell therapy manufacturing. The automated and closed platform is a single system that can be used for a variety of different autologous cell therapy protocols, including CAR-T, but also tumor-infiltrating lymphocytes (TILs) and Mesenchymal stem cells (MSCs).

In October 2018, Lonza acquired an 80% stake in Octane and according to Abraham has significantly advanced the system since.

The main activities have been improving the systems robustness and readiness for commercial sale and clinical manufacturing. This included full qualification of the system, passing all regulatory, safety and quality requirements, scaling up manufacturing, obtaining EU CE marking as well as DMF submission to the FDA, and much more.

Now that the system is launched and proven, we are hard at work, further developing it and enabling additional key capabilities, which will make it even more compelling and efficient. These include capabilities such as adding integrated magnetic cell separation and integrated cell electroporation (using the Lonza Nucleofector system).

Autologous CAR-T therapies such as Novartis Kymriah (tisagenlecleucel) and Gilead/Kites Yescarta (axicabtagene ciloleucel), both of which have been commercialized come at a cost. The personalized nature of the therapy gives rise to the adage the product is the process which, roughly translated, means scaling up manufacturing is difficult if not impossible and the cost is high.

Thus, the only way to truly scale cell therapy manufacturing is automation, said Abraham. The scalability of cell therapy manufacturing will become be critical as more cell therapies continue to reach late phase clinical trials and are commercialized.

He continued: Adding more Cocoon systems will not require much additional footprint thanks to the Cocoon tree, which allows to array multiple cocoons on a central axis. Up to 10 individual processes will be able to be run within approximately 1 m2.

On top of Sheba, other cell therapy developers have therefore turned to Lonza and its Cocoon technology to address this problem. Lonza inked a research collaboration with Stanford University School of Medicine, Fred Hutchinson Cancer Research Center, and Parker Institute for Cancer Immunotherapy earlier this year. And in March, Triumvira Immunologic announced a deal to utilize the Cocoon system, with Triumvira CEO Paul Lammers stating at the time that it is critical to leverage innovative technology to automate manufacturing processes to improve consistency, accelerate logistics, reduce footprint, and reduce cost.

Abraham added Lonza is working with other undisclosed partners to place their patient scale cell therapies into the Cocoon system for clinical manufacturing and expects to enter many more Cocoon collaborations whether with a centralized or decentralized manufacturing model.

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Automation needed to truly scale cell therapies, Lonza - Bioprocess Insider - BioProcess Insider

Using Organoids in the Study of Infectious Diseases – Technology Networks

Organoid cell culture has transformed cell-based assays in drug discovery and basic biology by conferring physiologic relevance to in vitro cell-based biological models. When provided with a suitable growth environment, including appropriate cultureware, growth factors, extracellular matrix, nutrients, and culture media, organ-derived progenitor cells harvested from patients grow and assemble into three-dimensional structures organoids which incorporate all cell types normally found in the original tissue, and allow physical and chemical interactions between and among cells. By providing greater physiologic relevance and a species- or patient-specific test platform, organoids overcome many limitations of conventional 2D cultures and even live-animal disease models. Organoids arise from organ-derived adult pluripotent stem cells, organ stem cells, or cancer stem cells which possess the innate capacity to expand and differentiate into multiple cell types. Organoids generated from dozens of tissues and organs available commercially, or accessible through published protocols include patient-derived models of liver, heart, pancreas, brain, GI tract, kidney, and recently, of human airwayssuitable for drug and vaccine development and for studying infectious human respiratory diseases.

Corning Life Sciences has collaborated with HUB since 2014 to provide advanced organoids and related technology.

Dr Clevers technology allowed, for the first time, the expansion of adult stem cell-derived organoids in genetically stable form and ultimately, the generation of in vitro models of any epithelial disease from any patient.

A second key benefit was indefinite expansion similar to that of transformed cells, but without the genetic abnormalities inherent in cancer cells. Previously, organoids were generated from embryonic or induced pluripotent stem cells, or from tumor cells which by necessity are genetically modified and therefore unrepresentative of the patient.

Under HUBs commercial development, organoid technology also provides standardization and consistency which is difficult to match, especially with primary cell cultures. Biopsies from the same patient collect differing quantities of cells at widely varying stages of cell lifecycle. When cultured under identical HUB protocols adult progenitor cells give rise to organoids with exactly the same cells in the same proportions, physical configuration, and genetics, every time, and with broad expansion capabilities.

Similarly, transformed cells grown on plastic have modified their gene expression to adapt to tissue culture conditions. Studies with such cells can be useful, provided investigators recognize that the patients original genetics have not been preserved. In HUB organoids the patients molecular footprint is maintained.

One field where this has been particularly useful is infectious diseases. Viruses have evolved to infect and replicate in cells in their normal physiological states. For example, respiratory syncytial virus (RSV) readily grows in organoids but will not infect transformed cells because the cells lack the relevant receptors.

Cell-based studies of airway diseases topical in light of the current COVID-19 pandemic were hampered for years for this reason, and technology for expanding primary cell cultures sufficiently for large-scale studies did not exist. By preserving critical cell surface receptors for infectious agents, the HUB method allows the study of such pathogens as RSV, human papillomavirus, norovirus, coronavirus, influenza, malaria and many others.

Epithelial cells are the first point of contact for pathogenic microbes in the respiratory tract, and fortuitously the cell types most easily grown as organoids. Receptors on airway epithelia and alveolar cells sense infection, which initiates mucosal barrier immunity through club, ciliated, basal, goblet and neuroendocrine cells, which together clear inhaled pathogens.

In a recent Science paper, researchers from the Hubrecht Institute and Erasmus Medical Center reported on how gut organoids helped them to uncover two potential avenues for treating or preventing infection with SARS-CoV-2, the coronavirus responsible for the current pandemic. SARS-CoV-2 is known to infect the lungs, but clinical evidence suggests intestinal involvement in both symptomatology and transmission. For example, rectal swabs contain viral RNA for a time after nasal swabs indicate the infection has resolved, suggesting gastro-intestinal infection and possibly fecaloral transmission.

Differentiated enterocytes strongly express the SARS-CoV-2 angiotensin converting enzyme 2 (ACE2) receptor through which the virus enters cells, with the highest receptor levels found in the brush border of intestinal enterocytes. Surprisingly, virus infected both high- and low expressors of ACE2, and infectivity of organoids was not greatly affected by culture conditions.

SARS-CoV-2 rapidly infected a subset of cells within the organoid, and infection increased over time. Using electron microscopy to visualize cellular components, the researchers found virus particles inside and outside the organoids constituent cells. Infection induced release of interferon, an endogenous antiviral whose activation could serve as the target for potential therapies.

The researchers concluded that intestinal epithelium supports SARS-CoV-2 replication, that human small intestinal organoids serve as an experimental model for coronavirus infection and biology, and that human organoids represent faithful experimental models to study the biology of coronaviruses.

In addition to drug screening and toxicology studies, airway organoids have been utilized to study the basic biology of infectious diseases. In an application note, Corning scientists reported that Corning Matrigel extracellular matrix facilitated the expansion of patient-derived bronchial epithelial cells into airway organoids suitable for high throughput analysis. Organoids streamlined the usual sample preparation protocol to a single operation cell lysis eliminating the normal steps of gene amplification, cDNA conversion, and library preparation.

Comparing normal and asthmatic airway organoids, investigators observed increased expression of genes coding for pro-inflammatory chemokines, receptors, and other proteins associated with inflammation in asthmatic airway cells. They also found that the genes upregulated in organoids derived from healthy cells were the same as those downregulated in organoids from asthmatic cells, and vice-versa. Application of the anti-inflammatory steroid dexamethasone induced up- or downregulation to a greater degree in asthmatic organoids compared with normal organoids.

The Corning study illustrates the versatility of organoids for studying airway diseases in the presence of comorbidities, as well as the ability to respond rapidly with suitable models for infectious diseases.

HUB Organoids derived from adult stem cells harvested from cystic fibrosis patients have proved valuable in the study of CF pathology, and have permitted patient-centered drug testing, which was the first use of HUB Organoids in personalized medicine. The CF patient derived organoids are tested to identify drug treatments for CF patients and in treated accordingly.

Recent studies on interleukin-17 receptors on lung epithelia have uncovered a role for this cytokine in acute and chronic inflammation, and demonstrated that IL-17 receptors participate in the innate immune defense against pulmonary fungal infections. In vivo, IL-17 expression and immune function requires polarized epithelial cells. In a paper appearing in 2019 in Frontiers in Immunology, a group at the University of Perugia, in Italy, wrote that because lung organoids recapitulate tissue polarity, they provide an exciting possibility of using lung organoids to comprehensively investigate IL-17R signaling in the lung, which is likely to offer new opportunities to develop and test therapeutics for inflammatory diseases and identify new molecular targets to improve resistance to infections.

As a scientific discipline, organoids will continue evolving towards greater ease of use, consistency, assay parallelism capabilities, and manufacturability. Organoids and organ-on-a-chip have already been combined in a complex, multi-tissue retina model, while systems consisting of organoids from two or more organs, discussed earlier, are already used routinely.

If organoid research continues at its current pace there is reason to expect significant streamlining of early-stage drug development, specifically around the preclinical and phase 1 stages. Organoids could eliminate some if not all animal testing, but this will require a leap of faith on the part of regulators already accustomed to reviewing animal data and its inherent caveats. At some point organoids might completely eliminate live preclinical screens, allowing drug developers to recruit patients directly into phase 2 based entirely on organoid-based screening.

While organoid investigations inevitably lead to systems of greater complexity, investigators should keep in mind that validation is the key to patient relevant models. HUB Organoids for the first time allow researchers to develop a model and directly test if and how it resembles the patient from which the tissue originated. With increasing complexity, the validation step should remain a focus of model developers and users. Complexity is good, but only up to a point.

Advancing organoids towards these lofty goals, including greater manufacturability, will require cell culture tools up to the task. Industry collaborations assure that tools for 3D cell culture will continue to advance, both for general research and to meet the challenges of emerging infectious diseases.

Authors: Dr Robert Vries, Chief Executive Officer, Hubrecht Organoid Technology (HUB) Elizabeth Abraham, Senior Product Manager, Corning Incorporated

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Using Organoids in the Study of Infectious Diseases - Technology Networks

Microengineered 3D pulmonary interstitial mimetics highlight a critical role for matrix degradation in myofibroblast differentiation – Science…

INTRODUCTION

Fibrosis is implicated in nearly 45% of all deaths in the developed world and plays a role in numerous pathologies, including pulmonary fibrosis, cardiac disease, atherosclerosis, and cancer (1). In particular, interstitial lung diseases, such as idiopathic pulmonary fibrosis (IPF), are fatal and incurable with a median survival of only 2 to 5 years (2). Often described as dysregulated or incessant wound healing, fibrosis involves persistent cycles of tissue injury and deposition of extracellular matrix (ECM) by myofibroblasts (MFs). These critical cellular mediators of fibrogenesis are primarily derived from tissue-resident fibroblasts (1). MFs drive eventual organ failure through excessive fibrous ECM deposition, force generation and tissue contraction, and eventual disruption of parenchymal tissue function (1). As organ transplantation remains the only curative option for late-stage disease, effective antifibrotic therapeutics that slow MF expansion or even reverse fibrosed tissue remain a major unmet clinical need. Undoubtedly, the limited efficacy of antifibrotic drugs at present underscores limitations of existing models for identifying therapeutics, the complexity of the disease, and an incomplete understanding of MF biology.

A strong correlation between lung tissue stiffening and worse patient outcomes suggests an important role for matrix mechanosensing in fibrotic disease progression (3). Preclinical models of fibrosis in mice have supported the link between tissue stiffening and disease progression. However, a precise understanding of how physical cues from the microenvironment influence MF differentiation in vivo is confounded by concurrent structural (e.g., collagen density and laminin/elastin degradation) and biochemical (e.g., matrix composition and inflammatory) changes to the microenvironment (4). Consequently, natural and synthetic in vitro tissue models have provided great utility for the study of MF mechanobiology. Seminal studies using natural type I collagen gels have elucidated the role of profibrotic soluble cues [e.g., transforming growth factor1 (TGF-1)] in promoting cell contractility, ECM compaction, and MF differentiation, and more recently, precision-cut lung slices, have emerged as a powerful tool to study the complexity of the pulmonary microenvironment in IPF (4, 5). However, their utility in identifying physical microenvironmental determinants of MF differentiation suffers from an intrinsic coupling of multiple biochemical and mechanical material properties (6). Rapid degradation kinetics (1 to 3 days) and resulting issues with material stability (1 to 2 weeks) further impede the use of natural materials for studying fibrogenic events and drug responses, which occur over weeks to months in in vivo models or years in patients (7, 8).

Synthetic hydrogels that are more resistant to cell-mediated degradation have provided a better controlled setting for long-term studies of disease-related processes (9). For example, synthetic hydrogel-based cell culture substrates with tunable stiffness have helped establish a paradigm for mechanosensing during MF differentiation in two-dimensions (2D), where compliant matrices maintain fibroblast quiescence in contrast to stiffer matrices that promote MF differentiation (10, 11). Extensive findings in 2D suggest a causal role for matrix mechanics (e.g., stiffness) during MF differentiation in vitro and potentially in human disease, but these models lack the 3D nature of interstitial spaces where fibrosis originates (12). The interstitium surrounding alveoli is structurally composed of two key components: networks of fibrous ECM proteins (namely, type I collagen fibers) and interpenetrating ground substance, an amorphous hydrogel network rich in glycosaminoglycans such as heparan sulfate proteoglycan. Mechanical cues from fibrotic ECM that promote MF differentiation may arise from changes to the collagen fiber architecture or the gel-like ground substance; whether matrix stiffness is a prerequisite for MF differentiation in 3D fibrous interstitial spaces remains unclear (13). Furthermore, the limited efficacy of antifibrotic therapies identified in preclinical and in vitro models of IPF motivates the development of 3D tissue-engineered systems with improved structural and mechanical biomimicry, relevant pharmacokinetics, and the potential to incorporate patient cells (9). Furthermore, recapitulating key features of the fibrotic progression in an in vitro setting that better approximates interstitial tissues could (i) improve our current understanding of MF mechanobiology and (ii) serve as a more suitable test bed for potential antifibrotic therapeutics.

Accordingly, here, we describe a microengineered pulmonary interstitial matrix that recapitulates mechanical and structural features of fibrotic tissue as well as key biological events observed during IPF progression. Design parameters of these engineered microenvironments were informed by mechanical and structural characterization of fibrotic lung tissue from a bleomycin mouse model. We then investigated the influence of dimensionality, matrix cross-linking/stiffness, and fiber density on TGF-1induced MF differentiation in our pulmonary interstitial matrices. Increased hydrogel cross-linking/stiffness substantially hindered MF differentiation in 3D in contrast to findings in 2D, while fibrotic matrix architecture (i.e., high fiber density) potently promoted fibroblast proliferation and differentiation into MFs. Long-term (21 days) culture of hydrogels with a fibrotic architecture engendered tissue stiffening, collagen deposition, and secretion of profibrotic cytokines, implicating fiber density as a potent fibrogenic cue in 3D microenvironments. Pharmacologic screening in fibrotic pulmonary interstitial matrices revealed matrix metalloproteinase (MMP) activity and hydrogel remodeling as a key step during 3D fibrogenesis, but not in traditional 2D settings. To explore the clinical relevance of our findings, we leveraged a multistep bioinformatics analysis of transcriptional profiles from 231 patients, highlighting increased MMP gene expression and enriched signaling domains associated with matrix degradation in patients with IPF. Together, these results highlight the utility of studying fibrogenesis in a physiologically relevant 3D hydrogel model, underscore the requirement of matrix remodeling in IPF, and establish a new platform for screening antifibrotic therapies.

To inform key design criteria for our pulmonary interstitial matrices, we began by characterizing mechanical properties of fibrotic interstitial tissue in a bleomycin-induced lung injury model in mouse. Nave C57BL/6 mice were intratracheally challenged with bleomycin to induce lung injury and subsequent fibro-proliferative repair, with saline-treated animals maintained as a control group. After 2 weeks, animals were sacrificed and lung tissue was dissected out, sectioned and stained, and then mechanically tested by atomic force microscopy (AFM) nanoindentation to map the stiffness of interstitial tissue surrounding alveoli. While single-dose bleomycin administration does not recapitulate human IPF, the fibro-proliferative response is well characterized and leads to MF differentiation, collagen deposition, and lung stiffening events that are reminiscent of what occurs in human disease over longer time scales. As previously documented (14), bleomycin treatment corresponded to an increase in the thickness of interstitial tissue regions surrounding alveoli, a structural change that occurred alongside matrix stiffening (Fig. 1, A and B); bleomycin-treated lungs had elastic moduli nearly fivefold greater than healthy control tissues. To generate synthetic hydrogels with elastic moduli tunable over this range, we functionalized a biocompatible and protein-resistant polysaccharide, dextran, with pendant vinyl sulfone groups amenable to peptide conjugation (termed DexVS; Fig. 1C). To permit cell-mediated proteolytic hydrogel degradation and thus spreading of encapsulated cells, we cross-linked DexVS with a bifunctional peptide (GCVPMSMRGGCG, abbreviated VPMS) primarily sensitive to MMP9 and MMP14, two MMPs implicated in fibrosis-associated matrix remodeling (15, 16). Tuning input VPMS cross-linker concentration yielded stable hydrogels spanning the full range of elastic moduli we measured by AFM nanoindentation of lung tissue (Fig. 1D). Additional functionalization with cell-adhesive moieties (CGRGDS, abbreviated RGD) facilitated adhesion of primary normal human lung fibroblasts (NHLFs) (Fig. 1E).

(A) Histological preparations of healthy control and bleomycin-treated murine lung tissue (n = 3 mice per group) stained for collagen by picrosirius red (scale bar, 100 m). (B) Youngs modulus of mouse lung tissue as measured by AFM nanoindentation, with data fit to the Hertz contact model to determine Youngs modulus (n = 3 mice per group, n = 50 indentations per group on n = 9 tissue sections). (C) Schematic of proteolytically sensitive, cell-adhesive DexVS-VPMS bulk hydrogels. (D) Youngs modulus determined by AFM nanoindentation of DexVS-VPMS hydrogels formed with different concentrations of VPMS cross-linker (n = 4 samples per group, n = 20 total indentations per group). (E and F) Representative images of F-actin (cyan), nuclei (yellow), and -SMA (magenta); image-based quantification of -SMA expression (left axis, magenta bars, day 9) and nuclear Ki67 (right axis, gray bars, day 5) in 2D and 3D (n = 4 samples per group, n = 10 fields of view per group, n > 50 cells per field of view; scale bars, 200 m). All data presented are means SDs with superimposed data points; asterisk denotes significance with P < 0.05 determined by one-way analysis of variance (ANOVA). AU, arbitrary units.

To confirm the role of matrix mechanics on cell proliferation and MF differentiation, we seeded patient-derived NHLFs on 2D DexVS protease-sensitive hydrogel surfaces varying in VPMS cross-linker density and resulting stiffness and stimulated cultures with TGF-1 to promote MF differentiation. In accordance with previous literature, we observed a stiffness-dependent stepwise increase in cell proliferation (day 5) and MF differentiation (day 9) as measured by Ki67 and -smooth muscle actin (-SMA) immunofluorescence, respectively (Fig. 1E) (11). As the influence of matrix elasticity on MF differentiation in 3D synthetic matrices has not previously been documented, we also encapsulated NHLFs in 3D within identical DexVS hydrogels. The opposing trend with respect to stiffness was noted for cells encapsulated in 3D; compliant (E = 560 Pa) hydrogels that limited -SMA expression in 2D plated cells instead exhibited the highest levels of MF differentiation in 3D (Fig. 1F). Decreasing proliferation and cell-cell contact formation as a function of increasing hydrogel stiffness were also noted in 3D matrices and may be one reason why rigid hydrogels limit differentiation in 3D. Similar findings have been reported for mesenchymal stem cells encapsulated in hyaluronic acid matrices, where compliant gels promoted stem cell proliferation and yes-associated protein (YAP) activity in 3D, yet inhibited YAP activity and proliferation in 2D (17). These results suggest that while stiff, cross-linked 2D surfaces promote cell spreading, proliferation, and MF differentiation, an equivalent relationship does not directly translate to 3D settings. High cross-linking and stiffness (E = 6.1 kPa) in 3D matrices sterically hinder cell spreading, proliferation, and the formation of cell-cell contacts, all well-established promoters of MF differentiation (18).

Cell-degradable synthetic hydrogels with elastic moduli approximating that of fibrotic tissue proved nonpermissive to MF differentiation in 3D. Although matrix cross-linking and densification of ground substance has previously been implicated in fibrotic tissue stiffening, remodeled collagenous architecture can also engender changes in tissue mechanics and may modulate MF development in IPF independently. To characterize the fibrous matrix architecture within healthy and fibrotic lung interstitium, we used second-harmonic generation (SHG) microscopy to visualize collagen microstructure in saline- and bleomycin-treated lungs, respectively. Per previous literature, saline-treated lungs contained limited numbers of micrometer-scale (~1-m-diameter) collagen fibers, primarily localized to the interstitial spaces supporting the alveoli (Fig. 2A) (19). In contrast, bleomycin-treated lungs had, on average, fourfold higher overall SHG intensity, with collagen fibers localized to both an expanded interstitial region and in disrupted alveolar networks. While no difference in fiber diameter was noted with bleomycin treatment, we did observe thick (~2- to 5-m) collagen bundles containing numerous individual fibers in fibrotic lungs, potentially arising from physical remodeling by resident fibroblasts (Fig. 2A and fig. S1). Given that typical synthetic hydrogels amenable to cell encapsulation (as in Fig. 1) lack fibrous architecture, we leveraged a previously established methodology for generating fiber-reinforced hydrogel composites (20). Electrospun DexVS fibers approximating the diameter of collagen fibers characterized by SHG imaging (fig. S1) were co-encapsulated alongside NHLFs in DexVS-VPMS hydrogel matrices, yielding a 3D interpenetrating network of DexVS fibers ensconced within proteolytically cleavable DexVS hydrogel (Fig. 2B). To recapitulate the adhesive nature of collagen and fibronectin fibers within interstitial tissues, we functionalized DexVS fibers with RGD to support integrin engagement and 3D cell spreading. While increasing the weight % of type I collagen matrices increases collagen fiber density and simultaneously increases hydrogel stiffness (fig. S2), our synthetic matrix platform enables changes to fiber density (0.0 to 5.0%) without altering mechanical properties assessed by AFM nanoindentation (Fig. 2C), likely due to the constant weight percentage of DexVS and VPMS cross-linker within the bulk hydrogel.

(A) SHG imaging of collagen microstructure within healthy and bleomycin-treated lungs on day 14, with quantification of average signal intensity (arrows indicate interstitial tissue regions adjacent to alveoli; n = 3 mice per group, n = 10 fields of view per group; scale bar, 100 m). (B) Schematic depicting polymer cross-linking and functionalization for generating fibrous DexVS hydrogel composites to model changes in fiber density within lung interstitial tissue ECM. (C) Images and intensity quantification of fluorophore-labeled fibers within composites varying in fiber density (n = 4 samples per group, n = 10 fields of view per group; scale bar, 100 m). Youngs modulus determined by AFM nanoindentation of fibrous composites formed with different concentrations of VPMS cross-linker (n = 4 samples per group, n = 20 measurements per group). (D) Representative high-resolution images of NHLFs on day 1 in fibrous composites formed with bulk hydrogels (12.5 mM VPMS) functionalized with integrin ligand arginylglycylaspartic acid (RGD) or heparin-binding peptide (HBP) [F-actin (cyan), nuclei (yellow), and DexVS fibers (magenta); scale bar, 50 m]. Quantification of fiber recruitment as measured by contact between cells and DexVS fibers (n = 10 fields of view per group, n > 25 cells analyzed). (E) Representative high-resolution images of NHLF on day 1 fibrous composites formed with bulk hydrogels functionalized with integrin ligand RGD or HBP [F-actin (cyan), fibronectin (yellow), and DexVS fibers (magenta); scale bar, 5 m]. Quantification of fibronectin deposition into tshe hydrogel matrix as measured by immunostain intensity (n = 10 fields of view per group, n > 25 cells analyzed). All data presented are means SDs with superimposed data points; asterisk denotes significance with P < 0.05 determined by one-way ANOVA or Students t test, where appropriate; NS denotes nonsignificant comparison.

Beyond recapitulating the multiphase structural composition of interstitial ECM, we also sought to mimic the adhesive ligand presentation and protein sequestration functions of native interstitial tissue. More specifically, the gel-like ground substance within fibrotic tissue intrinsically lacks integrin-binding moieties and is increasingly rich in heparan sulfate proteoglycans, primarily serving as a local reservoir for nascent ECM proteins, growth factors, and profibrotic cytokines. In contrast, synthetic hydrogels are often intentionally designed to have minimal interactions with secreted proteins and require uniform functionalization with a cell-adhesive ligand to support cell attachment and mechanosensing. We hypothesized that RGD-presenting fibers alone would support cell spreading (20), enabling the use of a nonadhesive bulk DexVS hydrogel functionalized with heparin-binding peptide (HBP; CGFAKLAARLYRKAG) (21). While both RGD- and HBP-functionalized bulk DexVS gels supported cell spreading upon incorporation of RGD-presenting fibers, HBP-functionalized hydrogels encouraged matrix remodeling in the form of cell-mediated fiber recruitment (Fig. 2D) and enhanced the deposition of fibronectin fibrils into the adjacent matrix (Fig. 2E). Given the multiphase structure of lung interstitium, changes in collagen fiber density noted with fibrotic progression, and the importance of physical and biochemical matrix remodeling to fibrogenesis, we used HBP-tethered 560-Pa DexVS-VPMS bulk hydrogels with tunable density of RGD-presenting fibers in all subsequent studies.

We next investigated whether changes in fiber density reflecting fibrosis-associated alterations to matrix architecture could influence MF differentiation in our 3D model. NHLFs were encapsulated in compliant DexVS-VPMS hydrogels ranging in fiber density (E = 560 Pa, 0.0 to 5.0 volume % fibers). Examining cell morphology after 3 days of culture, we noted increased cell spreading (Fig. 3, A and B) and evident F-actin stress fibers (fig. S3) in fibrous conditions compared to nonfibrous controls. Increased frequency of direct cell-cell interactions was also observed as a function of fiber density, as evidenced by higher area:perimeter ratios and the number of fibroblasts per contiguous multicellular cluster (Fig. 3A and fig. S3). As evidenced by changes in the ratio of nuclear to cytosolic YAP localization, we detected changes in mechanosensing as a function of fiber density, with the highest nuclear ratio measured in samples containing the highest fiber density examined. Given that nuclear YAP activity (a transcriptional coactivator required for downstream mechanotransduction) has been implicated as a promoter of MF differentiation (22), we also assayed other markers associated with fibroblast activation. With increases in fiber density, we found significant increases in cell proliferation and local fibronectin deposition (Fig. 3, A and B). Luminex quantification of cytokine secretion at this time point revealed elevated secretion of inflammatory and profibrotic cytokines (Fig. 3C), suggesting that matrix fibers may modulate the soluble milieu known to regulate the response to tissue damage and repair in vivo (2325). While no -SMA expression or collagen deposition was observed at this early time point, F-actin stress fibers, YAP activity, and fibronectin expression have been previously established as proto-MF markers in vivo (26), suggesting that physical interactions with matrix fibers prime fibroblasts for activation into MFs. Supplying the profibrotic soluble factor TGF-1 prompted increases in the expression of various profibrotic YAP-target genes (ACTA2, COL1A1, FN1, CD11, and CTGF) relative to nonfibrous (FD 0.0%) controls at day 5 (Fig. 3D). Together, these data suggest that heightened fiber density promotes a fibrotic phenotype (Fig. 3, A to C) and gene expression (Fig. 3D), despite the absence of a stiff surrounding hydrogel.

(A) Immunofluorescence images of NHLFs in hydrogel composites over a range of fiber densities after 3 days of culture [F-actin (cyan), fibronectin (FN, yellow), YAP (magenta), Ki67 (white), and nuclei (blue); scale bars, 100 m (F-actin), 20 m (FN), 20 m (YAP), and 100 m (Ki67/nuclei)]. (B) Corresponding image-based quantification of cell area, deposited FN, YAP nuclear to cytosolic ratio, and % of proliferating cells (n = 4 samples per group; for cell spread area analysis, n > 50 cells per group; for FN, YAP, and Ki67 analyses, n = 10 fields of view per group and n > 25 cells per field of view). (C) Cytokine secretion into culture medium on day 3 (all data were normalized to background levels in control medium, n = 4 samples per condition). (D) Expression of MF-related genes in NHLFs stimulated with TGF-1 on day 3, in either highly fibrous (FD 5.0%) or nonfibrous (FD 0.0%) hydrogels (data presented are GAPDH-normalized fold changes relative to NHLFs within an FD 0% hydrogel lacking TGF-1 supplementation). All data presented are means SDs with superimposed data points; asterisk denotes significance with P < 0.05 determined by one-way ANOVA or Students t test where appropriate.

To explore whether fibrotic matrix cues in the form of heightened fiber density could promote 3D MF differentiation over longer-term culture, NHLFs were encapsulated within hydrogels varying in fiber density and maintained in medium supplemented with TGF-1 beginning on day 1. Immunofluorescent imaging and cytokine quantification were performed on days 3, 5, 7, and 9 to capture dynamic changes in cellular phenotype and secretion, respectively. No -SMApositive stress fibers or changes in total cytokine secretion were observed on day 3 or 5. On day 7, we noted the sparse appearance of -SMApositive cells alongside increased total cytokine secretion (Fig. 4D) in FD 5.0% conditions containing TGF-1, indicating the beginning of a potential phenotypic shift. Extensive MF differentiation (designated by -SMApositive cells) and a sixfold increase in total cytokine secretion occurred rapidly between days 7 and 9 (Fig. 4, B, D, and E) in the highest fiber density (FD 5.0%) condition. Despite the high proliferation within high fiber density hydrogels (Fig. 4C), -SMApositive cells were not evident in samples lacking exogenous TGF-1 supplementation. Moreover, -SMApositive cells were also absent in TGF-1 supplemented conditions that lacked fibrous architecture, indicating a requirement for both soluble and physical fibrogenic cues in 3D. Furthermore, inhibiting integrin engagement by incorporating fibers lacking RGD also abrogated MF differentiation and proliferation despite the presence of TGF-1 (Fig. 4, A and B), suggesting that a fibrotic matrix architecture drives -SMA expression primarily through integrin engagement and downstream mechanosensing pathways. These results were replicated with primary human dermal fibroblasts and mammary fibroblasts, where similar trends with -SMA expression as a function of fiber density were observed (fig. S4). While high fiber density promoted proliferation in dermal fibroblasts, mammary fibroblasts underwent MF differentiation in the absence of higher proliferation rates, demonstrating intrinsic differences between cell populations originating from different tissues. Nevertheless, these results suggest that fibrotic matrix architecture may be promoting MF differentiation in other pathologies, namely, dermal scarring in systemic sclerosis and desmoplasia in breast cancer.

(A) Representative immunofluorescence images of NHLFs in microenvironmental conditions leading to low (top row) or high (bottom row) MF differentiation after 9 days in culture [-SMA (magenta) and nuclei (cyan); n = 4 samples per group, n = 10 fields of view per group, and n > 50 cells per field of view; scale bar, 200 m], with corresponding image-based quantification in (B) and (C). Insets depict representative fiber densities. (D) Measurement of total cytokine secretion over time as a function of fiber density (n = 4 samples per condition; * indicates significant differences between FD 5.0% and all other groups at a given time point; NS denotes nonsignificant comparison). (E) Secretion of specific cytokines and chemoattractants as a function of fiber density on day 9 (n = 4 samples per condition). (F) Representative images and quantification of tissue contraction within day 14 fibroblast-laden hydrogels of varying fiber density (n = 4 samples per group, dashed line indicates initial diameter of 5 mm). Photo credit: Daniel Matera, University of Michigan. (G) AFM measurements of day 14 fibroblast-laden hydrogels of varying fiber density (n = 20 measurements from n = 4 samples per group). Dashed line indicates original hydrogel stiffness. (H) SHG images of fibrous collagen within fibroblast-laden hydrogels after 21 days of culture in medium supplemented with ascorbic acid (scale bar, 100 m). (I) Measurement of total collagen content within digested DexVS hydrogels at day 21 as measured by biochemical assay (n = 4 samples per group). All data presented are means SDs with superimposed data points; asterisk denotes significance with P < 0.05 determined by one-way ANOVA; NS denotes nonsignificant comparison.

While proliferation and -SMA expression are accepted markers of activated fibroblasts, fibrotic lesions contribute to patient mortality through airway inflammation, collagen secretion, tissue contraction, and lung stiffeningpathogenic events that hinder the physical process of respiration (27). Luminex screening of 41 cytokines and chemokines within hydrogel supernatant revealed elevated total cytokine secretion as a function of fiber density over time (Fig. 4D), many of which were soluble mediators known to regulate airway inflammation (Fig. 4E) (23). Numerous other cytokines were additionally secreted at day 9 but did not change as a function of fiber density despite differences in cell number at this time point (fig. S5), suggesting that cell number alone cannot account for the increased cytokine secretion in high fiber density conditions. By generating free-floating hydrogels that allow contraction over time, we also examined macroscale changes in tissue geometry. Consistent with the influence of fiber density on -SMA expression, hydrogels containing high fiber densities underwent greater hydrogel contraction compared to nonfibrous or low fiber density conditions (Fig. 4F). Day 14 fibrotic hydrogels (FD 5.0%) were also fourfold stiffer (2.0 versus 0.5 kPa) as measured by AFM nanoindentation (Fig. 4G) compared to conditions that yielded low rates of MF differentiation in shorter-term studies (i.e., FD 0.0 or FD 0.5% in Fig. 4, A and B). When medium was supplemented with ascorbic acid to permit procollagen hydroxylation, collagen deposition into the surrounding matrix was evident by SHG microscopy by day 21 in high fiber density hydrogels (Fig. 4H) as compared to nonfibrous controls. Further biochemical analysis of hydrogel collagen content confirmed a stepwise increase in collagen production as a function of fiber density (Fig. 4I). Together, these findings demonstrate a clear influence of fiber density on MF differentiation and phenotype in 3D and furthermore suggest that this in vitro model recapitulates key pathogenic events associated with the progression of fibrosis in vivo.

Having established microenvironmental cues that promote robust 3D MF differentiation, we next evaluated the potential of our fibrous hydrogel model for use as an antifibrotic drug screening platform. Nintedanib, a broad-spectrum receptor tyrosine kinase inhibitor, and pirfenidone, an inhibitor of the mitogen-activated protein kinase (MAPK)/nuclear factor B (NF-B) pathway, were selected due to their recent Food and Drug Administration approval for use in patients with IPF (28). We also included dimethyl fumarate, an inhibitor of the YAP/TAZ pathway clinically approved for treatment of systemic sclerosis, and marimastat, a broad-spectrum MMP inhibitor that has shown efficacy in murine preclinical models of fibrosis (29, 30). We generated fibrotic matrices (560-Pa DexVS-VPMS-HBP bulk hydrogels containing 5.0 volume % DexVS-RGD fibers) that elicited the highest levels of MF differentiation, matrix contraction, and collagen secretion in our previous studies (Fig. 4). As a comparison to the current standard for high-throughput compound screening, we also seeded identical numbers of NHLFs on 2D tissue culture plastic in parallel. Cultures were stimulated with TGF-1 on day 1, and pharmacologic treatments were added on day 3, following extensive fibroblast spreading, cell-cell junction formation, and proliferation (Fig. 3A).

As in our earlier studies, TGF-1 supplementation promoted proliferation and -SMA expression within 3D constructs as well as on rigid tissue culture plastic (Fig. 5A). Nintedanib and pirfenidone had differential effects on NHLFs depending on culture format; NHLFs on 2D tissue culture plastic were resistant to pirfenidone/nintedanib treatment with no difference in proliferation or -SMA expression relative to vehicle controls, whereas modest but significant decreases in -SMA expression (pirfenidone and nintedanib) and proliferation (nintedanib) were detected in 3D (Fig. 5, A to E). Combined treatment with pirfenidone and nintedanib provided an antifibrotic effect only in fibrotic matrices, supporting ongoing clinical studies exploring their use as a combinatorial therapy (ClinicalTrials.gov identifier NCT03939520). Dimethyl fumarate abrogated cell proliferation and -SMA expression across all conditions, suggesting that inhibition of downstream mechanosensing inhibits MF differentiation in both 2D and 3D contexts in support of the general requirement for mechanosensing during MF differentiation independent of culture substrate (11). Inhibition of YAP activity in vivo has been shown to mitigate fibrosis and may be an advantageous therapeutic target (22). Blockade of MMP activity via marimastat treatment proved ineffectual in reducing -SMA expression or proliferation on 2D tissue culture plastic, but surprisingly fully abrogated the proliferation and differentiation response in 3D fibrotic matrices (Fig. 5, A to E). Given the role of protease activity in tissue remodeling in vivo (30) and in cellular outgrowth within 3D hydrogels (17, 31), our data suggest that degradative matrix remodeling is a requirement for MF differentiation in 3D, but not in more simplified 2D settings. To summarize, multiple antifibrotic agents (pirfenidone, nintedanib, dimethyl fumarate, and marimastat) demonstrating efficacy in clinical literature elicited an antifibrotic effect in our engineered fibrotic pulmonary interstitial matrices, but not in the 2D tissue culture plastic contexts traditionally used for compound screening.

(A) Representative confocal images stained for -SMA (magenta), F-actin (cyan), and nuclei (yellow) of NHLFs after 9 days of culture on tissue culture plastic (TCP) (top row) or 3D fibrotic matrices (bottom row) with pharmacologic treatment indicated from days 3 to 9 (scale bar, 100 m). Imaged regions were selected to maximize the number of -SMA+ cells per field of view within each sample. (B) Quantification of -SMA and (C) total cell count within 2D NHLF cultures. (D) Quantification of -SMA and (E) total cell count within 3D fibrotic matrices (n = 4 samples per group, n = 10 fields of view per group, and n > 50 cells per field of view). All data presented are means SDs with superimposed data points; asterisk denotes significance with P < 0.05 determined by one-way ANOVA; NS denotes nonsignificant comparison.

As the protease inhibitor marimastat fully ablated TGF-1induced -SMA expression and proliferation in our 3D fibrotic matrices, we leveraged bioinformatics methodologies to investigate the role of matrix proteases in patients with IPF on a network (Reactome) and protein (STRING) basis. Differential expression analysis of microarray data within the National Center for Biotechnology Information (NCBI) Gene Expression Omnibus (GEO) (dataset #GSE47460) was used to generate an uncurated/unbiased dataset composed of the top 1000 differentially regulated genes in IPF, revealing MMP1 as the most up-regulated gene in patients with IPF, with other matrix proteases (MMP1, MMP3, MMP7, MMP9, MMP10, MMP11, and MMP12) and matrix remodeling proteins (COL1A2, LOX, ACAN, DCN, and HS6ST2) similarly up-regulated (Fig. 6B, table S1, and data file S1). To focus on genes associated with MF differentiation for subsequent analyses, we performed Gene Ontology (GO) term enrichment (via GEO2R) to compile a curated dataset containing 188 key genes associated with MF differentiation (data file S1) and used Reactome and STRING analyses to investigate network signaling within both the uncurated and curated datasets. Analyses revealed 103 (uncurated) and 89 (curated) enriched signaling pathways in IPF (data file S1). The top 3/5 (uncurated) and 5/5 (curated) significantly enriched pathways in IPF involved matrix degradation and remodeling (Fig. 6C). Subsequent STRING protein-protein interaction analysis of datasets revealed that top signaling nodes were MMPs (uncurated: MMP1 and MMP3; Fig. 6D), fibrous collagens (uncurated: COL1A2 and COL3A1), or cytokines (curated: IL6, VEGFA, IL1B, and IGF1; Fig. 6D) known to increase MMP expression in fibroblasts (3235). These results emphasize the interdependence between MMP activity and systems-level pathogenic signaling in IPF and, in combination with our 3D drug screening results, highlight fibroblast-specific protease activity as a potential therapeutic target. Furthermore, given that protease inhibition had no effect on MF differentiation in 2D culture, these data also support the growing sentiment that simplified 2D screening models may be masking the identification of potentially viable antifibrotics.

(A) Schematic representation of bioinformatics workflow: Whole-genome transcriptomes from 91 healthy and 140 patients with lung fibrosis were fetched from the NCBI GEO. Differential expression analysis was used to assemble an uncurated list of the top 1000 differentially expressed genes. GO enrichment of choice biological pathways was used to assemble a curated list of genes associated with MF differentiation. Datasets were fed through a previous knowledgebased analysis pipeline to identify enriched signaling pathways (Reactome) and key protein signaling nodes (STRING) within patients with IPF. (B) Heatmaps of the top 20 differentially expressed genes within specified GO categories, which were manually selected for curated analysis. CN values indicate a high degree of interaction between proteins selected for curated analysis. Colors are based on differential expression values that were not log-normalized. (C) Summary of the top 5 significantly enriched pathways in the curated and uncurated gene set. (D) Representative STRING diagram depicting protein interactions within the curated dataset, with summary of the top 5 signaling nodes in the uncurated and curated gene set. Blue nodes and edges represent interactions within the top 5 signaling nodes for the curated dataset.

Despite fibrosis widely contributing to mortality worldwide, inadequate understanding of fibrotic disease pathogenesis has limited the development of efficacious therapies (12). Preclinical studies in vivo, while indispensable, often fail to translate to clinical settings as evidenced by the failure of ~90% of drugs identified in animal studies (36). In addition, limitations in current technologies (e.g., the embryonic lethality of many genetic ECM knockouts and the limited resolution/imaging depth of intravital microscopy) have hindered the application of preclinical in vivo models for the study of cell-ECM interactions that underlie fibrogenesis (37). In contrast, existing in vitro models use patient-derived cells that are affordable, scalable, and amenable to microscopy, but often fail to recapitulate the complex 3D matrix structure of the interstitial tissue regions where fibrotic diseases such as IPF originate. We leveraged electrospinning and bio-orthogonal chemistries to engineer novel pulmonary interstitial matrices that are 3D and have fibrous architecture with biomimetic ligand presentation. In the presence of profibrotic soluble factors, these settings reproduce hallmarks of fibrosis at cellular and tissue levels (Figs. 2 to 4). Examining the influence of physical microenvironmental cues (cross-linking/stiffness and fiber density) on MF differentiation, we find that cross-linking/stiffness has opposing effects on MF differentiation in 2D versus 3D (Fig. 1) and that incorporation of a fibrous architecture in 3D is a prerequisite to MF differentiation (Fig. 4). Furthermore, supported by the importance of protease signaling in IPF (Fig. 6), we performed proof-of-concept pharmacologic screening within our 3D fibrotic matrices (Fig. 5) and highlighted enhanced biomimicry as compared to traditional 2D drug screening substrates where matrix remodeling appears to be dispensable for MF differentiation.

While tunable synthetic hydrogels have identified mechanosensing pathways critical to MF differentiation in 2D, these observations have yet to be translated to 3D fibrous settings relevant to the interstitial spaces where fibrosis originates. Given that late-stage IPF progresses in the absence of external tissue damage, current dogma implicates fibrotic matrix stiffness as the continual driver of MF differentiation in vivo (10, 11, 38). While we cannot disregard this hypothesis, our work elucidates a contrasting MMP-dependent mechanism at play in 3D, whereby a compliant, degradable, and fibrous matrix architecture supports MF differentiation, with matrix contraction and stiffening occurring downstream of -SMA expression, nearly a week later. Given numerous 2D studies indicating matrix stiffness as a driver of MF differentiation, the finding that a compliant matrix promotes MF differentiation may appear counterintuitive (10, 11). However, MF accumulation has been documented before tissue stiffening in human disease (3), and a recent phase 2 clinical trial (ClinicalTrials.gov Identifier: NCT01769196) targeting the LOX pathway (the family of enzymes responsible for matrix stiffening in vivo) failed to prevent disease progression in patients with IPF and was terminated due to lack of efficacy (39). Furthermore, compelling recent work by Fiore et al. (3) combined immunohistochemistry with high-resolution AFM to characterize human IPF tissue mechanics and found that regions of active fibrogenesis were highly fibrous but had a similar Youngs modulus as healthy tissue. In concert with our in vitro data, these findings suggest that MF differentiation is possible within soft provisional ECM in vivo and that the initiation of fibrogenesis may not be dependent on heightened tissue stiffness so long as matrix fibers and appropriate soluble cues (e.g., TGF-1) are present.

Consequently, understanding the source of profibrotic soluble cues in vivo is of critical importance when identifying therapeutic targets for IPF. Luminex screening of supernatant from 3D fibrotic matrices revealed sixfold increases in cytokine secretion during fibrogenesis, most of which were potent inflammatory factors [e.g., granulocyte-macrophage colony-stimulating factor (GM-CSF), interleukin-6 (IL-6), IL-8, and vascular endothelial growth factor A (VEGF-A)] and chemoattractants (e.g., CCL2, CCL7, CCL11, and CXCL1) (Fig. 4E). Furthermore, IL-6 and VEGF-A were found to be major signaling nodes in patients with IPF (Fig. 6D). While not typically regarded as an immunomodulatory cell population, these findings suggest that MFs may maintain localized inflammation to support continual fibrogenesis. Mitogens such as IL-6 and IL-8 promote endothelial- and epithelial-to-mesenchymal transition, a process that gives rise to matrix-producing MF-like cells in IPF (40). CCR2 (CCL2 and CCL7) and CXCR1 (CXCL1 and IL-8) ligation facilitates macrophage chemotaxis, potentially leading to a sustained influx of TGF-1producing cells in IPF, and glycoproteins such as GM-CSF inhibit caspase activity in mononuclear cells, potentially preventing apoptotic events required for the resolution of wound repair and return to homeostasis (23, 41). In addition, secretion of nearly all cytokines was increased as a function of fiber density, highlighting a potential feed-forward loop distinct from canonical TGF-1 signaling. Further model development (e.g., coculture platforms) will be required to examine these hypotheses and the role of MF-derived cytokines in persistent inflammation and fibrosis.

In addition to documenting the role of fibrotic matrix architecture in 3D fibrogenesis, we demonstrate proof-of-concept pharmacologic screening within our synthetic pulmonary interstitial matrices and highlight their improved relevance to human disease. Previous work in vitro has documented profound reductions in MF differentiation after treatment with clinically approved antifibrotics (pirfenidone and nintedanib), whereas in the clinic, pirfenidone and nintedanib impede disease progression but are far from curative (4, 28, 42, 43). Pirfenidone or nintedanib had insignificant effects in 2D settings in our hands and only modest effects in 3D (Fig. 5). One reason for this discrepancy may be the use of supraphysiologic pirfenidone and nintedanib concentrations in previous in vitro studies, whereas we selected dosages based on plasma concentrations in patients with IPF (44). Differences in pharmacokinetics, nutrient/growth factor diffusion, and cell metabolism between 2D and 3D tissue constructs likely also play a role. Furthermore, as evidenced by the preventative effect of the protease inhibitor marimastat in 3D hydrogels but not 2D settings (Fig. 5), pharmacologics that influence matrix degradation and remodeling are likely to have a minimized effect in 2D settings due to the less dynamic nature of tissue culture plastic and flat hydrogels (45). Nintedanib and pirfenidone have been shown to influence protease activity and matrix remodeling in vivo (16), and may be mediating their effects within fibrotic matrices through modulation of ECM remodeling. Given the identification of numerous potential antifibrotic agents (microRNA, TGF-1 inhibitors, IL-4, IL-13 neutralizing antibodies, and integrin blockers) in preclinical models, application of the system described here could elucidate how choice pharmacologics affect MF differentiation and matrix remodeling processes that are difficult to recapitulate in 2D culture. Further development of our interstitial matrices as an arrayed platform, as has been elegantly implemented with collagen matrices (42), is a critical next step to moving this technology toward high-throughput screening applications.

It is important to note that this work has several potential limitations. Our material approach allows facile control of initial microenvironmental conditions (e.g., dimensionality, fiber density, ligand density, and elastic modulus), and of note, composites of RGD-bearing nondegradable fibers and degradable bulk hydrogel decouple degradation-induced changes in matrix mechanics and ligand availability. However, we have no experimental control over subsequent dynamic cell-driven remodeling events (e.g., MMP-mediated hydrogel softening, fibronectin and collagen deposition, and hydrogel contraction/stiffening from resident cells) that likely affect local matrix mechanics, cellular mechanosensing, and MF differentiation. Exciting recent technologies such as 3D traction force microscopy (TFM) and magnetic bead microrheology could enable future examination of how these dynamic changes in cell-scale mechanics potentiate MF differentiation in 3D. Along similar lines, although our study suggests a requirement for initial adhesion to the surrounding matrix, how the dynamics of ligand presentation due to matrix remodeling regulates mechanosensing was not explored here. We present this platform as a reductionist approach to modeling the activation of fibroblasts within the 3D fibrous interstitia associated with fibrosis, a pathology that develops over years in vivo and involves multiple cell types. Human pulmonary tissue and fibrotic foci, in particular, also have viscoelastic and nonlinear mechanical behaviors (3, 46) that were not explored in our AFM measurements of murine lung or hydrogel composites. Given the important role such mechanical features can play in ECM mechanosensing, incorporating new synthetic material strategies in combination with cell-scale mechanical measurements will be essential to modeling physiologic complexity. Given that the development of lung organoids is still in its infancy, decellularized precision-cut lung slices currently represent the best culture platform to capture the full complexity of the lung microenvironment (5).

In summary, we designed a tunable 3D and fibrous hydrogel model that recapitulates dynamic physical (e.g., stiffening and contraction) and biochemical (e.g., secretion of fibronectin, collagen, and cytokines) alterations to the microenvironment observed during the progression of IPF. Implementation of our model allowed us to establish a developing mechanism for MF differentiation in 3D compliant environments, whereby cell spreading upon matrix fibers drives YAP activity, cytokine release, and proteolysis-dependent MF differentiation. Furthermore, we leveraged bioinformatics techniques to explore protease signaling in clinical IPF and, in concert with our therapeutic screening data, establish a strong role for proteases during IPF pathogenesis and in 3D MF differentiation. Whether protease activity promoted MF differentiation directly through modulation of intracellular signaling or indirectly through affects on the local matrix environment has yet to be explored in these settings but will be the focus of future efforts. Consequently, these results highlight critical design parameters (3D degradability and matrix architecture) frequently overlooked in established synthetic models of MF differentiation. Future work incorporating macrophages, endothelial cells, and epithelial cells may expand current understanding of how developing MF populations influence otherwise homeostatic cells and how matrix remodeling influences paracrine signaling networks and corresponding drug response. Given the low translation rate of drugs identified in high-throughput screening assays, we show that the application and development of engineered biomimetics, in combination with preclinical models, can improve drug discovery and pathophysiological understanding.

All reagents were purchased from Sigma-Aldrich and used as received, unless otherwise stated.

Dextran vinyl sulfone. A previously described protocol for vinyl sulfonating polysaccharides was adapted for use with linear highmolecular weight (MW) dextran (MW 86,000 Da; MP Biomedicals, Santa Ana, CA) (20). Briefly, pure divinyl sulfone (12.5 ml; Thermo Fisher Scientific, Hampton, NH) was added to a sodium hydroxide solution (0.1 M, 250 ml) containing dextran (5 g). This reaction was carried out at 1500 rpm for 3.5 min, after which the reaction was terminated by adjusting the pH to 5.0 via the addition of hydrochloric acid. A lower functionalization of DexVS was used for hydrogels, where the volume of divinyl sulfone reagent was reduced to 3.875 ml. All reaction products were dialyzed for 5 days against Milli-Q ultrapure water, with two water exchanges daily, and then lyophilized for 3 days to obtain the pure product. Functionalization of DexVS was characterized by 1H nuclear magnetic resonance (NMR) spectroscopy in D2O and was calculated as the ratio of the proton integral [6.91 parts per million (ppm)] and the anomeric proton of the glucopyranosyl ring (5.166 and 4.923 ppm); here, vinyl sulfone/dextran repeat unit ratios of 0.376 and 0.156 were determined for electrospinning and hydrogel DexVS polymers, respectively.

DexVS was dissolved at 0.6 g ml1 in a 1:1 mixture of Milli-Q ultrapure water and dimethylformamide with 0.015% Irgacure 2959 photoinitiator. Methacrylated rhodamine (0.5 mM; Polysciences Inc., Warrington, PA) was incorporated into the electrospinning solution to fluorescently visualize fibers under 555 laser. This polymer solution was used for electrospinning within an environment-controlled glovebox held at 21C and 30% relative humidity. Electrospinning was performed at a flow rate of 0.3 ml hour1, gap distance of 5 cm, and voltage of 10.0 kV onto a grounded collecting surface attached to a linear actuator. Fiber layers were collected on glass slabs and primary cross-linked under ultraviolet light (100 mW cm2) and then secondary cross-linked (100 mW cm2) in an Irgacure 2959 solution (1 mg ml1). After polymerization, fiber segments were resuspended in a known volume of phosphate-buffered saline (PBS) (typically 3 ml). The total volume of fibers was then calculated via a conservation of volume equation: total resulting solution volume = volume of fibers + volume of PBS (3 ml). After calculating total fiber volume, solutions were re-centrifuged, supernatant was removed, and fiber pellets were resuspended to create a 10 volume % fiber solution, which were then aliquoted and stored at 4C. To support cell adhesion, 2.0 mM RGD was coupled to vinyl sulfone groups along the DexVS backbone via Michael-type addition chemistry for 30 min, followed by quenching of excess VS groups in a 300 mM cysteine solution for 30 min.

DexVS gels were formed via a thiol-ene click reaction at 3.3% (w/v) (pH 7.4, 37C, 45 min) with VPMS cross-linker (12.5, 20, and 27.5 mM) (GCRDVPMSMRGGDRCG, GenScript, George Town, KY) in the presence of varying amounts of arginylglycylaspartic acid (RGD, CGRGDS, 2.0 mM; GenScript, George Town, KY), HBP (GCGAFAKLAARLYRKA, 1.0 mM; GenScript, George Town, KY), and fiber segments (0.0 to 5.0%, v/v). For experiments comparing hydrogels of varying ligand type (1 mM HBP versus 2 mM RGD), cysteine was added to precursor solutions to maintain a final vinyl sulfone concentration of 60 mM. All hydrogel and peptide precursor solutions were made in PBS containing 50 mM Hepes. To create fibrous hydrogels, a defined stock solution (10% v/v) of suspended fibers in PBS/Hepes was mixed into hydrogel precursor solutions before gelation. By controlling the dilution of the fiber suspension, fiber density was readily tuned within the hydrogel at a constant hydrogel weight percentage. For gel contraction experiments, DexVS was polymerized within a 5-mm-diameter polydimethylsiloxane (PDMS) gasket to ensure consistent hydrogel area on day 0.

NHLFs (University of Michigan Central Biorepository), normal human dermal fibroblasts (Lonza, Basel, Switzerland), and normal human mammary fibroblasts (Sciencal, Carlsbad, CA) were cultured in Dulbeccos modified Eagles medium containing 1% penicillin/streptomycin, l-glutamine, and 10% fetal bovine serum (Atlanta Biologicals, Flowery Branch, GA). NHLFs derived from three separate donors were used for experiments. Cells were passaged upon achieving 90% confluency at a 1:4 ratio and used for studies until passage 7. For all hydrogel studies, cells were trypsinized, counted and either encapsulated into or seeded onto 25-l hydrogels at a density of 1,000,000 cells ml1 of hydrogel, and subsequently cultured at 37C and 5% CO2 in serum-containing medium. For studies comparing 3D hydrogels to tissue culture plastic, the number of cells seeded into 2D conditions was analogous to the total cell number within hydrogel matrices. Medium was refreshed the day after encapsulation and every 2 days after. In selected experiments, recombinant human TGF-1 (5 ng/ml; PeproTech, Rocky Hill, NJ) was supplemented into the medium at 5 ng ml1. For pharmacological studies, nintedanib (50 nM; Thermo Fisher Scientific, Hampton, NH), pirfenidone (100 M; Thermo Fisher Scientific, Hampton, NH), marimastat (1.0 M), and dimethyl fumarate (100 nM) were supplemented in serum-containing medium and refreshed every 2 days.

Cultures were fixed with 4% paraformaldehyde for 30 min at room temperature. To stain the actin cytoskeleton and nuclei, samples were permeabilized in PBS solution containing Triton X-100 (5%, v/v), sucrose (10%, w/v), and magnesium chloride (0.6%, w/v); blocked in 1% bovine serum albumin (BSA); and stained simultaneously with phalloidin and 4,6-diamidino-2-phenylindole (DAPI). For immunostaining, samples were permeabilized, blocked for 8 hours in 1% (w/v) BSA, and incubated with mouse monoclonal anti-YAP antibody (1:1000; Santa Cruz Biotechnology, SC-101199), mouse monoclonal anti-fibronectin antibody (FN, 1:2000; Sigma-Aldrich, #F6140), rabbit monoclonal anti-Ki67 (1:500; Sigma-Aldrich #PIMA514520), or mouse monoclonal anti-SMA (1:2000; Sigma-Aldrich, #A2547) followed by secondary antibody for 6 hours each at room temperature with 3 PBS washes in between. High-resolution images of YAP, FN, and actin morphology were acquired with a 40 objective. Unless otherwise specified, images are presented as maximum intensity projections of 100-m Z-stacks. Hydrogel samples were imaged on a Zeiss LSM 800 laser scanning confocal microscope. SHG imaging of lung tissue was conducted on a Leica SPX8 laser scanning confocal microscope with an excitation wavelength of 820 nm and a collection window of 400 to 440 nm. Single-cell morphometric analyses (cell spread area) were performed using custom Matlab scripts with sample sizes >50 cells per group, while YAP, -SMA, Ki67, and FN immunostains were quantified on an image basis with a total of 10 frames of view. MFs were denoted as nucleated, F-actin+, -SMA+ cells. For cell density (number of nuclei) calculations, DAPI-stained cell nuclei were thresholded and counted in six separate 600 m 600 m 200 m image volumes, allowing us to calculate a total number of cells per mm3 of gel. Fiber recruitment analysis was conducted via a custom Matlab script; briefly, cell outlines were created via actin masking and total fiber fluorescence was quantified under each actin mask on a per-cell basis. A similar analysis method using Matlab was used for cell-cell junction analysis as published previously, with higher area:perimeter ratios and clusters/cell indicative as more pronounced network formation (47).

For all experiments, additional hydrogel replicates were finely minced and degraded in dextranase solution (4 IU/ml; Sigma-Aldrich) for 20 min and homogenized in buffer RLT (Qiagen, Venlo, The Netherlands), and RNA was isolated according to the manufacturers protocols. Complementary DNA (cDNA) was generated from deoxyribonuclease (DNase)free RNA and amplified, and gene expression was normalized to the housekeeping gene glyceraldehyde-3-phosphate dehydrogenase (GAPDH). Experiments were run with technical triplicates across three individual biological experiments. For a complete list of primers, see table S2.

To determine the elastic modulus of lung tissue and DexVS hydrogels, indentation tests were used with a Nanosurf FlexBio AFM (Nanosurf, Liestal, Switzerland). Samples were indented via a 5-m bead at a depth of 10 m and an indentation rate of 0.333 m/s. Resulting force-displacement curves were fit to a spherical Hertz model using AtomicJ. Poissons ratios of 0.5 and 0.4 were used for hydrogels and lung tissue, respectively.

All animal studies were approved by the Animal Care and Use Committee at the University of Michigan. Bleomycin (0.025 U; Sigma-Aldrich) was instilled intratracheally in C57BL6 mice (8 weeks of age; The Jackson Laboratory, Bar Harbor, ME, USA) on day 0. Briefly, mice were anesthetized with sodium pentobarbital, the trachea was exposed and entered with a 30-gauge needle under direct visualization, and a single 30-l injection containing 0.025 U of bleomycin (Sigma-Aldrich) diluted in normal saline was injected. Lungs were collected on day 14 for mechanical and histological analysis. For histology samples, lungs were perfused with saline and inflated with 4% paraformaldehyde, sectioned, and stained with picrosirius red. For mechanical characterization via AFM, lungs were perfused with saline, infused with OCT (optimal cutting temperature) compound (Thermo Fisher Scientific), and flash-frozen in a slurry of dry ice and ethanol. Sections were mechanically tested via AFM nanoindentation immediately upon thawing.

To characterize the inflammatory secretome associated with various DexVS-VPMS environments, medium was collected from NHLF cultures 3, 5, 7, and 9 days after encapsulation. A Luminex FlexMAP 3D (Luminex Corporation, Austin, TX) systems technology was used to measure 41 cytokines/chemokines (HCTYMAG-60 K-PX41, Milliplex, EMD Millipore Corporation) in the medium samples according to the manufacturers instructions. Total secretion was reported as the sum of all 41 analytes measured for each respective condition. Cell-secreted collagen was measured using the established colorimetric Sircol assay in hydrogels cultured with serum-free medium in the presence of ascorbic acid (25 g ml1).

The NCBI GEO database was consulted [dataset GSE47460 (GP14550)] to fetch gene expression data from 91 healthy patients and 140 patients with IPF; patients with chronic obstructive pulmonary disease and nonidiopathic fibrotic lung diseases were excluded from the analysis (48). GEO2R (www.ncbi.nlm.nih.gov/geo/geo2r/) software was used for GO term enrichment, with keywords ECM, MMP, integrin, cytoskeleton, cytokine, chemokine, and MAPK used as search terms for dataset curation (48). Noncurated datasets were composed of the top 1000 differentially expressed genes between healthy and interstitial lung disease (ILD) conditions. Differential expression was calculated on the basis of subtracting normalized expression values between diseased and healthy patients. All genes were normalized before analysis with GEO2R via a pairwise cyclic losses approach. For pathway and protein-protein enrichment analyses, a curated pathway database [Reactome (49)] and Search Tool for Retrieval of Interacting Genes/Proteins [STRING (50)] methodology were consulted, respectively. For STRING analyses, up-regulated genes within the druggable genome were focused upon. A tabulated list of top genes, pathways, and nodes can be seen in data file S1.

Statistical significance was determined by one-way analysis of variance (ANOVA) or Students t test where appropriate, with significance indicated by P < 0.05. All data are presented as means SD.

Acknowledgments: We thank E. S. White (University of Michigan) for providing patient-derived lung fibroblasts used in these studies. Funding: This work was supported, in part, by the NIH (HL124322, R35HL144481). D.L.M. and C.D.D. acknowledge financial support from the NSF Graduate Research Fellowship Program (DGE1256260). Author contributions: D.L.M. and B.M.B. conceived and supervised the project. D.L.M. designed and performed the experiments. K.M.D. and K.B.A. performed and aided in analysis of the Luminex experiments. M.R.S. and C.D.D. helped with data analysis. R.P. and M.S. aided in polymer syntheses and microfiber fabrication. I.M.L. provided equipment for and assisted in polymerase chain reaction experiments. C.A.W. and B.B.M. helped perform the animal experiments for the bleomycin-induced lung fibrosis model. All authors edited and approved the manuscript. Competing interests: The authors declare that they have no competing interests. Data and materials availability: All data needed to evaluate the conclusions in the paper are present in the paper and/or the Supplementary Materials. Additional data related to this paper may be requested from the authors.

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Microengineered 3D pulmonary interstitial mimetics highlight a critical role for matrix degradation in myofibroblast differentiation - Science...

Boryung Pharmaceutical Signs R&D Agreement with Vigencell to Develop Immunocyte Therapy – BusinessKorea

Boryung Pharmaceutical and Vigencell announced on Sept. 8 that they have signed an R&D agreement to develop immunocyte therapy. The agreement will pave the way for the two companies to cooperate in development and commercialization of diverse immune-cell treatments.

The agreement will help Vigencell accelerate commercialization of its three immuno-cell therapy platform technologies ViTier, ViMedier, and ViRanger. It will help Vigencell speed up development of new products based on its platform technologies and, after product development, set up production facilities and bring the products to global markets.

Boryung Pharmaceutical brings its experience in commercializing Kanarb, a new drug for hypertension, to development of new drugs with Vigencell. The agreement will allow Boryung to ramp up sales by expanding its anti-cancer drug pipeline and portfolio.

Vigencell's platform technologies are ViTier, ViMedier, and ViRanger. ViTier is a customized T-cell therapy using antigen-specific cytotoxic T lymphocytes (CTLs). It is an effective and safe tumor killing T-cell therapy platform technology optimized for target antigens and patients. ViMedier is a general-purpose immunity control cell therapy. It uses Vigencells unique technique to proliferate and induce myeloid inhibitory cells from CD34 benign stem cells that are derived rom cord blood. ViRanger is a high-functional general-purpose cell-genetic complex therapy platform technology that can accommodate various genes.

Using its ViTier platform technology, Vigencell is carrying out phase two clinical trials in Korea for cell therapy drugs that can directly attack and remove NK/T cell non-hodgkin lymphoma which is Epstein-barr virus (EBV)-positive.

Vigencell has also submitted an investigational new drug (IND) application for VT-Tri-A, a treatment pipeline with the ability to directly attack/remove acute myelogenous leukemia. At the same time, the company is developing a unique cell therapy titled VT-Tri-II for cytomegalovirus (CMV) and common tumor antigen with government support to treat glioblastoma multiforme patients. Within this year, the company will submit an investigational new drug (IND) application for VT-Tri-II.

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Boryung Pharmaceutical Signs R&D Agreement with Vigencell to Develop Immunocyte Therapy - BusinessKorea

‘We wanted a chance’: Sask. family left with $1M medical bill after 4-year-old’s potentially life-saving treatment – CTV News Saskatoon

SASKATOON -- The family of a four-year-old Saskatoon boy who is now recovering in a Minneapolis hospital after receiving a potentially life-saving treatment hopes their experience will ultimately help others in Saskatchewan.

In June, Conner Finn was diagnosed with cerebral adrenoleukodystrophy (ALD), a rare and sometimes fatal disease that attacks the membrane which insulates nerve cells the brain.

His father Craig Finn said the family quickly learned that the window of opportunity to treat the disease, which affects one in 18,000 people, was a narrow one and Saskatchewan did not offer the procedure that was Conner's best hope a blood stem cell transplant,

The procedure halts the degeneration in the body including brain deterioration which can cause hearing loss, losing the ability to walk and even death, Finn said.

He says tests showed they caught Conners level of degeneration at a lower stage, around three or four out of 10 which was positive news.

We knew we had to move quickly if we wanted a chance to stop this, Finn told CTV News.

Finn said the Government of Saskatchewan gave him the option of having the transplant done in Winnipeg or Toronto, but did not provide a definite timeline or confirm if there was an ALD specialist to treat him.

After learning the process could take months and cut into the window to effectively treat Conner, the Finns took matters into their own hands.

(A) doctor in Minneapolis said they had a plan in motion immediately to find a donor," Finn said.

The family drove to Minnesota on July 7. With a letter from the specialist, they crossed the border with relative ease despite COVID-19 restrictions after a phone call was made by border security to the ALD Leukodystrophy Centre in Minneapolis where Conner would receive treatment.

The procedure came with a hefty price tag, a cost of around CAD $1 million, according to Finn.

Finn said he was still in conversation with the province trying to get some funding for the medical costs involved.

I told the government 'This is serious with his brain deteriorating every day and you guys are still bouncing around ideas of hospitals while the doctor in the States has found a perfect match and has a plan.'"

He said he is planning on further appeals to the government to have the costs covered.

In an emailed statement, the Ministry of Health said while it does cover the cost of some elective medical services outside of the country, the coverage must have prior approval.

"One of the key requirements outlined in legislation is that the specialist must confirm that all care options in Saskatchewan and Canada have been explored and exhausted. That is, the services being requested are not obtainable within Canada," the statement said.

Conner is recovering in hospital, where he's expected to stay until well into November.

According to his dad, the family has been told that in two months, doctors will be able to determine if any more brain deterioration has occurred and if Conner's ALD will be fixed in the long term.

A GoFundMe page has been set up by a family friend to help with some of their expenses.

Finn said he will continue to push the province to pay for the procedure and if they do agree to cover the bill, he will donate all of the GoFundMe money to the doctors research at the ALD centre.

Currently, just over $87,000 of the $100,000 goal has been raised.

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'We wanted a chance': Sask. family left with $1M medical bill after 4-year-old's potentially life-saving treatment - CTV News Saskatoon

Innovative treatments for heart failure – Open Access Government

Concerning heart failure (HF), the current COVID-19 pandemic is having a dramatic effect on the daily life of each individual, ranging from social distancing measures applied in most countries to getting severely diseased due to the virus. Cardiovascular Disease (CVD) is among the most common conditions in people that die of the infection. The burden of CVD accounts for over 60 million people in the EU alone, therefore, it is the leading cause of death in the world.

Although COVID-19 shows us the direct impact of a potential treatment for peoples health, CVD is a stealthy pandemic killer. HF is a chronic disease condition in which the heart is not able to fill properly or efficiently pump blood throughout your body, caused by different stress conditions including myocardial infarction, atherosclerosis, diabetes and high blood pressure. Several measures are commonly used to treat heart disease, such as lifestyle changes and medications like beta-blockers and ACE inhibitors, yet these typically only slow down the progression of the disease.

Biomedical research is exploring new avenues by combining scientific insights with new technologies to overcome chronic diseases like HF. Among the most appealing and promising technologies are the use of cardiac tissue engineering and extracellular vesicles-mediated repair strategies.

Upon an initial cell loss post-infarction, it is appealing to replace this massive loss in contractile cells for new cells and thereby not treating patients symptoms, but repairing the cause of the disease. Cardiac cell therapy has been pursued for many years with variable results in small initial trials upon injection into patients. Different cell types have been used to help the myocardium in need, but the most promising approaches aim to use induced pluripotent cells (iPS) from reprogrammed cells from the patient themselves that can be directed towards contractile myocardial cells. These cells in combination with natural materials, in which the cells are embedded in the heart, can be used for tissue engineering strategies (1). Together with different international partners, Sluijters team are trying to develop strategies to use these iPS-derived contractile cells for myocardial repair via direct myocardial injection (H2020-Technobeat-66724) or to make a scaffold that can be used as a personalised biological ventricular assist device (H2020-BRAV-874827). A combination of engineering and biology to mimic the native myocardium aims to replace the chronically ill tissue for healthy and well-coupled heart tissue that can enhance the contractile performance of the heart.

Recently, a Dutch national programme started, called RegMedXB, in which the reparative treatment of the heart is aimed to be performed outside the patients body. During the time the heart is outside the body; the patient is connected to the heart-lung machine, and after restoring function, it will be re-implanted. The so-called Cardiovascular Moonshot aims to create a therapy that best suits the individual patient, by having their heart beating in a bioreactor, outside the body. Although it sounds very futuristic, many small lessons will be learned to feet novel therapeutic insights.

The initial injection of stem cells did result in a nice improvement of myocardial performance. We have now learned that rather than these delivered cells helping the heart themselves, the release of small lipid carriers called extracellular vesicles (EVs) (2) from these cells occur. These EVs carry different biological molecules, including nucleotides, proteins and lipids, and are considered to be the bodies nanosized messengers for communication. The use of stem cell-derived EVs are now being explored as a powerful means to change the course of the disease. Via these small messengers, natural biologics are delivered to diseased cells and thereby help them to overcome the stressful circumstances. EVs carry reparative signals that can be transferred to the diseased heart and thereby change the course of heart disease in some patients.

Within the EVICARE program (3) (H2020-ERC-725229), Sluijters team are using stem cell-derived EVs to change the response of the heart to injury. Also, to understand which heart cells and processes are being affected, they use materials to facilitate a slow release of biomaterials over an extended period rather than a single dose, which is probably essential for a chronic disease like HF. For now, improved blood flow is the main aim but the team have seen other effects as well, such as cardiovascular cell proliferation (4) by which the heart cells themselves start to repair the organ.

The use of EVs basically aims to enhance the endogenous repair mechanisms of the heart. These natural carriers can be mimicked with synthetic materials, or used as a hybrid of the two, thereby creating an engineered nanoparticle, that is superior in the intracellular delivery of genetic materials. The possibility of loading different biological materials allows a further tuning of its effectiveness and use in different disease conditions, creating a new off-the-shelf delivery system for nanomedicine to treat cancer and CVD (H2020-Expert-825828).

As is true of the current COVID-19 pandemic, HF is also a growing chronic disease that affects millions of people worldwide. The chronic damaged myocardium needs reparative strategies in the future to lower the social burden for patients, but also to keep the economic consequences affordable. New scientific insights with cutting edge technological developments will help to address these needs of CVD patients and their families.

References

(1) Madonna R, Van Laake LW, Botker HE, Davidson SM, De Caterina R, Engel FB, Eschenhagen T, Fernandez-Aviles F, Hausenloy DJ, Hulot JS, Lecour S, Leor J, Menasch P, Pesce M, Perrino C, Prunier F, Van Linthout S, Ytrehus K, Zimmermann WH, Ferdinandy P, Sluijter JPG. ESC Working Group on Cellular Biology of the Heart: position paper for Cardiovascular Research: tissue engineering strategies combined with cell therapies for cardiac repair in ischaemic heart disease and heart failure. Cardiovasc Res. 2019 Mar 1;115(3):488-500.

(2) Sluijter JPG, Davidson SM, Boulanger, CM, Buzs EI, de Kleijn DPV, Engel FB, Giricz Z, Hausenloy DJ, Kishore R, Lecour S, Leor J, Madonna R, Perrino C, Prunier F, Sahoo S, Schiffelers RM, Schulz R, Van Laake LW, Ytrehus K, Ferdinandy P. Extracellular vesicles in diagnostics and therapy of the ischaemic heart: Position Paper from the Working Group on Cellular Biology of the Heart of the European Society of Cardiology. Cardiovasc Res. 2018 Jan 1;114(1):19-34.

(3) https://www.sluijterlab.com/extracellular-vesicle-inspired-ther

(4) Maring JA, Lodder K, Mol E, Verhage V, Wiesmeijer KC, Dingenouts CKE, Moerkamp AT, Deddens JC, Vader P, Smits, AM, Sluijter JPG, Goumans MJ. Cardiac Progenitor Cell-Derived Extracellular Vesicles Reduce Infarct Size and Associate with Increased Cardiovascular Cell Proliferation. J Cardiovasc Transl Res. 2019 Feb;12(1):5-17.

Please note: this is a commercial profile.

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Innovative treatments for heart failure - Open Access Government

Reasons Industries to Thrive Post-Pandemic! Stem Cell Therapy for Osteoarthritis Market Report xyz Answers it Analysis by Key Companies Mesoblast,…

Global Coronavirus pandemic has impacted all industries across the globe, Stem Cell Therapy for Osteoarthritis market being no exception. As the global economy heads towards major recession post-2009 crisis, Cognitive Market Research has published a recent study which meticulously studies the impact of this crisis on Global Stem Cell Therapy for Osteoarthritis market and suggests possible measures to curtail them. This press release is a snapshot of the research study and further information can be gathered by accessing complete report.To Contact Research Advisor Mail us @ [emailprotected] or call us on +1-312-376-8303. As per the ongoing market, research finding says Stem Cell Therapy for Osteoarthritis Market is growing at a High CAGR during the forecast period 2020-2027. The increasing interest of the investors in the said market industry is one of the prominent reason for the growth and expansion of this market

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Major Key Players mentioned in the report are: Mesoblast, Regeneus, U.S. Stem Cell, Anterogen, Asterias Biotherapeutics

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Reasons Industries to Thrive Post-Pandemic! Stem Cell Therapy for Osteoarthritis Market Report xyz Answers it Analysis by Key Companies Mesoblast,...

Animal Stem Cell Therapy Market likely to touch new heights by end of forecast – News by aeresearch

N95 Respirator Mask Industry Market Competitive Landscape Analysis, Major Regions, Report 2020-2025 By Market Study Report

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Animal Stem Cell Therapy Market likely to touch new heights by end of forecast - News by aeresearch

Male Pattern Baldness gets longer effect QR678 therapy, more effective than Platelet-Rich Plasma (PRP): Journal of Cosmetic Dermatology Published…

(Eds: Disclaimer: The following content is a press release. PTI takes no editorial responsibility for the same.) Mumbai, 8th September 2020: QR 678, a patented treatment for hair regrowth therapy for men and women, has proven to be more effective than PRP as a hair loss treatment. This study was published in an iconic and much respected American Journal called the Journal of Cosmetic Dermatology. It showed that as compared to the Platelet Rich Plasma (PRP) therapy, QR 678showed significant improvement in hair regrowth with almost 100% reduction in hair fall. QR 678 was invented by Dr.Debraj Shome and Dr.Rinky Kapoor, celebrity cosmetic surgeons from India. They observed that male pattern baldness, known as Androgenic Alopecia characterised by progressive hair loss in men growing at a rampant rate of 58% in males aged 30-50 years which initiated their urge to research and find a solution to this cosmetic issue leading to the invention of QR 678. The therapy curbs hair fall and increases the thickness, the number and density of existing hair follicles, offering greaterhair coverage to the ones with alopecia.The formulation has received patents in the United States and in India. Dr.Debraj Shome, Cosmetic Surgeon and Director, at The Esthetic Clinics, said, The hair-regrowth treatments available currently have many limitations; they cannot revive hair beyond a certain stage. QR678 is a process where growth factors are injected in the hair follicles, which not only arrests hair fall but also stimulates hair growth. QR678 is a non-surgical, pain-free and non-invasive procedure for the hair regrowth treatment which has shown very good results in over 10,000 patients. Practicing from the Esthetics Clinics, Dr Shome says that, from my experience as a cosmetic surgeon dealing with hair loss patients on a daily basis the treatment has responded very well, especially in India. QR 678 has had a success rate of 90% in India and this is the highest success rate achieved by any hair fall treatment in a shortest treatment time of 6-8 sessions. Comparing the two treatments in question, Dr. Rinky Kapoor partner to Dr Shome and one of leading Dermatologists in India adds, PRP is used by all Dermatologists and plastic surgeons for hair growth. PRP involves extracting platelets from human blood and injecting it into the scalp to cause hair growth. But, the truth of the matter is that this therapy is more based on hope than actual science. There has never been a randomised controlled trial showing that PRP actually causes hair growth. That is why we conducted a comparative trial between the QR678 and PRP treatments and no surprises that the QR678 treatment caused almost 300% better results than the PRP". The trial was a split head trial, comparing the PRP treatment efficacy with the QR678 treatments. While PRP is supposed to have growth factors for hair growth, the QR 678 treatment is a bioengineered, first in class hair therapy, with six hair growth factors and biomimetic peptides, administered to the scalp via mesotherapy. With Alopecia and hair loss becoming more and more common and affecting more than 40% males and 30% Females over the age of 30 globally, having a new age, proven therapy is very important for the world. More than 12000 patients have already experienced amazing results with the QR 678 treatment, which has an USA and an Indian patent and is now being exported to multiple countries from India. Dr. Kapoor says, "We, as Doctors need to decide whether the treatments we offer are indeed backed by science or not. Just because hair loss is so common and we didn''t have too many solutions prior to the QR678 doesn''t mean that we use treatments like the PRP which have no strong evidence based data for hair growth. Ultimately, science must win!" The acceptance of the Journal of Cosmetic Dermatology of the QR678 hair growth treatment will change the execution and delivery of hair loss treatment, as PRP was rampantly and randomly used by dermatologists, plastic surgeons and cosmetic surgeons alike, in India and globally. India through the ''Made in India'' top class hair innovation the QR678, may have pioneered a way forward for cosmetology at an international level. Dr.Debraj Shome has been a global pioneer in developing new techniques and solutions for facial plastic surgery and facial cosmetic surgery for more than a decade, he is amongst the few super specialists India has in this area of cosmetology. Dr. Shome is also a celebrated, best-selling, and internationally acclaimed author of Dear People, With Love & Care, Your Doctors. Maintained its position as a bestseller for weeks in a row this book is an anthology of short stories based on the real-life doctor-patient relationship. He has written more than 50 peer-reviewed international papers in top International research journals. Dr. Shome is also the patent holder for the invention of the QR678 hair growth factor injections. This hair growth formulation has received patents in multiple locations, including the USA and India. Dr.Rinky Kapoor is one of the best dermatologists in India today. She is also an expert in the field of non-invasive and non-surgical skin rejuvenation treatments. She has a unique ability to use a mixture of treatments for correct results making her the one of the finest dermatologist in India.What sets Dr Rinky Kapoor apart is the fact that she uses the world''s best and latest technological advances to give the most natural looking results. She says, Its the joy of seeing the look of wonder and contentment on the faces of my patients and this is what keeps me going daily. About The Esthetic Clinics: (https://www.theestheticclinic.com/) The Esthetic Clinics is a group of world-class centresdedicated to plastic surgery & skin care. They are currently located at Mumbai, New Delhi, Ahmedabad, Hyderabad, Bangalore and Kolkata in India. The Esthetic Clinics practice evidence-based medicine and perform cosmetic surgery for beauty, plastic surgery for birth abnormalities; plastic surgery for fractures, trauma & cancer induced facial deformities. They also provide laser surgery & many cosmetic solutions for many skin diseases. The Esthetic Clinicswas voted as the Most Promising & Innovative Cosmetic Clinics 2016 at the Pharma Leaders Summit & Awards 2016. The Esthetic Clinics was rated by the Times Health Survey 2019 as being one of the Top Clinics in Plastic Surgery & Cosmetic Surgery, Dermatology & Trichology, in Mumbai, India. PWR PWR Disclaimer :- This story has not been edited by Outlook staff and is auto-generated from news agency feeds. Source: PTI More from Outlook Magazine

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Male Pattern Baldness gets longer effect QR678 therapy, more effective than Platelet-Rich Plasma (PRP): Journal of Cosmetic Dermatology Published...

Transcriptional Regulation in Embryonic Stem Cells …

Abstract

Transcriptional regulation is a pivotal process that confers cellular identity and modulates the biological activities within a cell. In embryonic stem cells (ESCs), the intricate interplay between transcription factors and their targets on the genomic template serves as building blocks for the transcriptional network that governs self-renewal and pluripotency. At the heart of this complex network is the transcription factor trio, Oct4, Sox2 and Nanog, which constitute the ESC transcriptional core. Regulatory mechanisms such as autoregulatory and feedforward loops support the ESC transcriptional framework and serve as homeostatic control for ESC maintenance. Large-scale studies such as loss of function RNAi screens and transcriptome analysis have led to the identification of more players that support pluripotency. In addition, genome-wide localization studies of transcription factors have further unraveled the interconnectivity within the ESC transcriptional circuitry. Transcription factors also work in concert with epigenetic factors and together, this crosstalk between transcriptional and epigenetic regulation maintains the homeostasis of ESC. This chapter provides an overview of the significance of transcriptional regulation in ESC and traces the recent advances made in dissecting the ESC transcriptional regulatory network.

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