Category Archives: Gene Medicine

The global market for precision medicine is projected to top more than $84.5 billion by 2024. Targeted therapies for rare, genetic diseases, cancer and chronic conditions come with the hope of a cure.

Companies such as Roche, Novartis, Spark Therapeutics (now owned by Roche), Pfizer, Editas Medicine, and BioMarin Pharmaceuticals are among the pharma players in this space. There seem to be new developments in precision medicine on almost a weekly basis.

So what do educational institutions need to do to create fertile ground for gene therapy research to produce the next generation of companies developing these therapies? And what needs to happen to facilitate data sharing, ensure access to genome sequencing and these promising therapies?

A new eBook highlights compelling conversations around a couple of events that took place during the JP Morgan Healthcare conference in January this year. One, hosted by the Penn Center for Innovation, offers a showcase of the latest biotech innovations emerging from Penn and the Perelman School of Medicine. Another, hosted by Deloitte and P4ML, drew attention to an initiative by the World Economic Forum to improve the way genomic data is shared to develop better treatments for rare diseases and ethical considerations for access to precision medicine.

Fill in the form below to download the eBook, The Pathway to Precision Medicine.

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A snapshot of the precision medicine landscape - MedCity News

AGN-151587 (EDIT-101) is the firstin vivoCRISPR medicine to be administered to patients

Additional patient enrollment to the BRILLIANCE Clinical Trial is ongoing

DUBLIN, Ireland and CAMBRIDGE, Mass., March 04, 2020 (GLOBE NEWSWIRE) -- Allergan plc (AGN), a leading global pharmaceutical company, and Editas Medicine, Inc. (EDIT), a leading genome editing company, today announced the treatment of the first patient in the BRILLIANCE clinical trial of AGN-151587 (EDIT-101) at Oregon Health & Science University (OHSU) Casey Eye Institute, a world-recognized academic eye center.

AGN-151587 (EDIT-101) is an experimental medicine delivered via sub-retinal injection under development for the treatment of Leber congenital amaurosis 10 (LCA10), an inherited form of blindness caused by mutations in the centrosomal protein 290 (CEP290) gene. The BRILLIANCE clinical trial is a Phase 1/2 study to evaluate AGN-151587 for the treatment of patients diagnosed with LCA10 and is the worlds first human study of an in vivo, or inside the body, CRISPR genome editing medicine. The trial will assess the safety, tolerability, and efficacy of AGN-151587 in approximately 18 patients with LCA10.

This dosing is a truly historic event for science, for medicine, and most importantly for people living with this eye disease, said Cynthia Collins, President and CEO, Editas Medicine. The first patient dosed in the BRILLIANCE clinical trial marks a significant milestone toward delivering on the promise and potential of CRISPR medicines to durably treat devastating diseases such as LCA10. We look forward to sharing future updates from this clinical trial and our ocular program.

Currently patients living with LCA10 have no approved treatment options. For years, Allergan has had an unwaveringcommitmentto advancingeyecare treatments. With the first patient treated in this historic clinical trial, we mark a significant step in advancing the AGN-151587 clinical program and move closer to our goal of developing a game-changing medicine for LCA10 patients, said Brent Saunders, Chairman and CEO, Allergan.

Our first treatment in this clinical trial is an important step toward bringing new and promising treatments to patients with disease-causing gene mutations. OHSU is honored to be involved in this effort to address previously untreatable diseases such as Leber congenital amaurosis 10, said Mark Pennesi, M.D., Ph.D., Associate Professor of Ophthalmology, Kenneth C. Swan Endowed Professor, Division Chief, Paul H. Casey Ophthalmic Genetics, Casey Eye Institute, Oregon Health & Science University, Principal Investigator and enrolling physician of the first patient treated with AGN-151587.

Eric A. Pierce, M.D., Ph.D., Director of the Inherited Retinal Disorders Service and Director of the Ocular Genomics Institute at Massachusetts Eye and Ear, and the William F. Chatlos Professor of Ophthalmology at Harvard Medical School, and a Principal Investigator for the BRILLIANCE clinical trial also commented, We have a long history at Massachusetts Eye and Ear of helping develop life-changing medicines for our patients, and we are thrilled to be a leader in the development of a CRISPR-based experimental medicine to treat CEP290-associated retinal disease with Allergan and Editas.

About the BRILLIANCE Phase 1/2 Clinical Trial of AGN-151587 (EDIT-101)The BRILLIANCE Phase 1/2 clinical trial of AGN-151587 (EDIT-101) for the treatment of Leber congenital amaurosis 10 (LCA10) will assess the safety, tolerability, and efficacy of AGN-151587 in approximately 18 patients with this disorder. Up to five cohorts of patients across three dose levels will be enrolled in this open label, multi-center, clinical trial. Both adult and pediatric patients (3 17 years old) with a range of baseline visual acuity assessments are eligible for enrollment. Patients will receive a single administration of AGN-151587 via subretinal injection in one eye. Additional details are available on http://www.clinicaltrials.gov (NCT#03872479).

About AGN-151587 (EDIT-101)AGN-151587 (EDIT-101) is a CRISPR-based experimental medicine under investigation for the treatment of Leber congenital amaurosis 10 (LCA10). AGN-151587 is administered via a subretinal injection to deliver the gene editing machinery directly to photoreceptor cells.

Story continues

About Leber Congenital AmaurosisLeber congenital amaurosis, or LCA, is a group of inherited retinal degenerative disorders caused by mutations in at least 18 different genes.It is the most common cause of inherited childhood blindness, with an incidence of two to three per 100,000 live births worldwide.Symptoms of LCA appear within the first years of life, resulting in significant vision loss and potentially blindness.The most common form of the disease, LCA10, is a monogenic disorder caused by mutations in the CEP290 gene and is the cause of disease in approximately 2030 percent of all LCA patients.

About the Editas Medicine-Allergan AllianceIn March 2017, Editas Medicine and Allergan Pharmaceuticals International Limited (Allergan) entered a strategic alliance and option agreement under which Allergan received exclusive access and the option to license up to five of Editas Medicines genome editing programs for ocular diseases, including AGN-151587 (EDIT-101).Under the terms of the agreement, Allergan is responsible for development and commercialization of optioned products, subject to Editas Medicines option to co-develop and share equally in the profits and losses of two optioned products in the United States. Editas Medicine is also eligible to receive development and commercial milestones, as well as royalty payments on a per-program basis.The agreement covers a range of first-in-class ocular programs targeting serious, vision-threatening diseases based on Editas Medicines unparalleled CRISPR genome editing platform, including CRISPR/Cas9 and CRISPR/Cpf1 (also known as Cas12a). In August 2018, Allergan exercised its option to develop and commercialize AGN-151587 globally for the treatment of LCA10. Additionally, Editas Medicine exercised its option to co-develop and share equally in the profits and losses from AGN-151587 in the United States.

About Allergan plcAllergan plc (AGN), headquartered in Dublin, Ireland, is a global pharmaceutical leader focused on developing, manufacturing and commercializing branded pharmaceutical, device, biologic, surgical and regenerative medicine products for patients around the world. Allergan markets a portfolio of leading brands and best-in-class products primarily focused on four key therapeutic areas including medical aesthetics, eye care, central nervous system and gastroenterology. As part of its approach to delivering innovation for better patient care, Allergan has built one of the broadest pharmaceutical and device research and development pipelines in the industry.

With colleagues and commercial operations located in approximately 100 countries, Allergan is committed to working with physicians, healthcare providers and patients to deliver innovative and meaningful treatments that help people around the world live longer, healthier lives every day.

For more information, visit Allergans website atwww.Allergan.com.

About Editas Medicine As a leading genome editing company,Editas Medicineis focused on translating the power and potential of the CRISPR/Cas9 and CRISPR/Cas12a (also known as Cpf1) genome editing systems into a robust pipeline of treatments for people living with serious diseases around the world.Editas Medicineaims to discover, develop, manufacture, and commercialize transformative, durable, precision genomic medicines for a broad class of diseases. For the latest information and scientific presentations, please visit http://www.editasmedicine.com.

Allergan Forward-Looking StatementsStatements contained in this press release that refer to future events or other non-historical facts are forward-looking statements that reflect Allergans current perspective on existing trends and information as of the date of this release. Actual results may differ materially from Allergans current expectations depending upon a number of factors affecting Allergans business. These factors include, among others, the difficulty of predicting the timing or outcome of FDA approvals or actions, if any; the impact of competitive products and pricing; market acceptance of and continued demand for Allergans products; the impact of uncertainty around timing of generic entry related to key products, including RESTASIS, on our financial results; risks associated with divestitures, acquisitions, mergers and joint ventures; risks related to impairments; uncertainty associated with financial projections, projected cost reductions, projected debt reduction, projected synergies, restructurings, increased costs, and adverse tax consequences; difficulties or delays in manufacturing; and other risks and uncertainties detailed in Allergans periodic public filings with the Securities and Exchange Commission, including but not limited to Allergan's Annual Report on Form 10-K for the year ended December 31, 2019. Except as expressly required by law, Allergan disclaims any intent or obligation to update these forward-looking statements.

Editas Medicine Forward-Looking StatementsThis press release contains forward-looking statements and information within the meaning of The Private Securities Litigation Reform Act of 1995. The words anticipate, believe, continue, could, estimate, expect, intend, may, plan, potential, predict, project, target, should, would, and similar expressions are intended to identify forward-looking statements, although not all forward-looking statements contain these identifying words. Forward-looking statements in this press release include statements regarding the Companies plans with respect to the Phase 1/2 clinical trial for AGN-151587 (EDIT-101).Editas Medicine may not actually achieve the plans, intentions, or expectations disclosed in these forward-looking statements, and you should not place undue reliance on these forward-looking statements. Actual results or events could differ materially from the plans, intentions and expectations disclosed in these forward-looking statements as a result of various factors, including: uncertainties inherent in the initiation and completion of preclinical studies and clinical trials and clinical development of Editas Medicines product candidates; availability and timing of results from preclinical studies and clinical trials; whether interim results from a clinical trial will be predictive of the final results of the trial or the results of future trials; expectations for regulatory approvals to conduct trials or to market products and availability of funding sufficient for Editas Medicines foreseeable and unforeseeable operating expenses and capital expenditure requirements. These and other risks are described in greater detail under the caption Risk Factors included in Editas Medicines most recent Annual Report on Form 10-K, which is on file with the Securities and Exchange Commission, and in other filings that Editas Medicine may make with the Securities and Exchange Commission in the future. Any forward-looking statements contained in this press release speak only as of the date hereof, and Editas Medicine expressly disclaims any obligation to update any forward-looking statements, whether because of new information, future events or otherwise.

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Allergan and Editas Medicine Announce Dosing of First Patient in Landmark Phase 1/2 Clinical Trial of CRISPR Medicine AGN-151587 (EDIT-101) for the...

March 5, 2020

Sysmex Corporation

Sysmex and the Kobe City Eye Hospital Sign a

Comprehensive Collaboration Agreement

-Reinforcing Collaboration toward the Realization of

Genomic Medicine in the Area of Ophthalmic Disorders-

Sysmex Corporation (HQ: Kobe, Japan; Chairman and CEO: Hisashi Ietsugu) and the Kobe City

Eye Hospital (Location: Kobe, Japan; Director: Yasuo Kurimoto) announce that they have entered into a comprehensive collaboration agreement related to the clinical implementation of genomic medicine for hereditary retinal degenerative diseases. The agreement was signed in February 2020.

Based on a decision by the Japanese Cabinet, the Ministry of Health, Labour and Welfare's Investigative Commission for the Promotion of Genomic Medicine in Relation to Intractable Diseases1 is deliberating on the "promotion of genomic medicine for cancer and intractable diseasesputting in place a system to facilitate genetic testing for intractable diseases with a view to achieving earlier-stage diagnosis, and promoting the development of therapeutic methods that leverage whole-genome information including gene therapy." For many hereditary and other intractable diseases, a significant amount of time elapses between disease onset and a confirmed diagnosis. The government's basic policy based on the Act on Medical Care for Patients with Intractable Diseases calls for "building systems to enable accurate diagnoses to be received as quickly as possible, and putting in place a system that facilitates appropriate medical treatment at nearby medical institutions once disease has been diagnosed."

To date, medical and scientific knowledge has been in short supply for hereditary diseases in particular. However, knowledge is being accumulated on the genes that cause disease by using next-generation sequencing (NGS) to conduct multigene analysis. In recent years, new inroads have been made on one type of hereditary disease-hereditary retinal degenerative diseases.2 In the United States, gene therapy3 drugs have been approved that target disease-causing genes.

As an ophthalmic core hospital and an ophthalmology research institute, the Kobe City Eye Hospital's outpatient services for retinal degeneration include proactive gene diagnosis research and genetic counseling. The hospital aims to serve as a one-stop center offering standard medical care and state-of-the-art treatment based on genetic information and providing support to help patients return to society. On hereditary retinal degenerative diseases, the hospital has been actively involved in both basic and clinical research connected to diagnosis and treatment.

Sysmex has identified the "resolution of medical issues through products and services" as a priority issue (materiality). We are moving forward in the area of personalized medicine, which provides healthcare optimized for individual patients, and are promoting R&D with a view to realizing testing that places a low physical burden on patients. Sysmex has received manufacturing and sales approval for the first time in Japan for a system to be used in cancer gene profiling, contributing to the clinical implementation of cancer genomic medicine.

In February 2020, Sysmex and the Kobe City Eye Hospital signed a comprehensive collaboration agreement toward the clinical implementation of genomic medicine in the area of ophthalmic disorders. This collaboration aims to leverage the Kobe City Eye Hospital's knowledge spanning genetic diagnosis and treatment, as well as in vitro diagnostic pharmaceuticals and expertise in the development of analytical programs possessed by Sysmex and its subsidiaries, RIKEN GENESIS Co., Ltd. (HQ: Tokyo, Japan; President & CEO: Naoto Kondo) and Oxford Gene Technology IP Limited (HQ: Oxfordshire County, United Kingdom; CEO: John Anson). We will start by focusing on the early clinical implementation of genetic testing required for the diagnosis and treatment of hereditary degenerative retinal diseases and gene counseling.

By creating treatment opportunities with respect to hereditary diseases, we aim to enhance patients' quality of life and contribute to the advancement of medicine.

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Sysmex Corporation published this content on 05 March 2020 and is solely responsible for the information contained therein. Distributed by Public, unedited and unaltered, on 05 March 2020 07:15:04 UTC

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Sysmex : and the Kobe City Eye Hospital Sign a Comprehensive Collaboration Agreement -Reinforcing Collaboration toward the Realization of Genomic...

Abstract

Mesenchymal stem cells (MSCs) encapsulation by three-dimensionally (3D) printed matrices were believed to provide a biomimetic microenvironment to drive differentiation into tissue-specific progeny, which made them a great therapeutic potential for regenerative medicine. Despite this potential, the underlying mechanisms of controlling cell fate in 3D microenvironments remained relatively unexplored. Here, we bioprinted a sweat gland (SG)like matrix to direct the conversion of MSC into functional SGs and facilitated SGs recovery in mice. By extracellular matrix differential protein expression analysis, we identified that CTHRC1 was a critical biochemical regulator for SG specification. Our findings showed that Hmox1 could respond to the 3D structure activation and also be involved in MSC differentiation. Using inhibition and activation assay, CTHRC1 and Hmox1 synergistically boosted SG gene expression profile. Together, these findings indicated that biochemical and structural cues served as two critical impacts of 3D-printed matrix on MSC fate decision into the glandular lineage and functional SG recovery.

Mesenchymal stem cells (MSCs) hold great promise for therapeutic tissue engineering and regenerative medicine, largely because of their capacity for self-renewal and multipotent properties (1). However, their uncertain fate has a major impact on their envisioned therapeutic use. Cell fate regulation requires specific transcription programs in response to environmental cues (2, 3). Once stem cells are removed from their microenvironment, their response to environmental cues, phenotype, and functionality could often be altered (4, 5). In contrast to growing information concerning transcriptional regulation, guidance from the extracellular matrix (ECM) governing MSC identity and fate determination is not well understood. It remains an active area of investigation and may provide previously unidentified avenues for MSC-based therapy.

Over the past decade, engineering three-dimensional (3D) ECM to direct MSC differentiation has demonstrated great potential of MSCs in regenerative medicine (6). 3D ECM has been found to be useful in providing both biochemical and biophysical cues and to stabilize newly formed tissues (7). Culturing cells in 3D ECM radically alters the interfacial interactions with the ECM as compared with 2D ECM, where cells are flattened and may lose their differentiated phenotype (8). However, one limitation of 3D materials as compared to 2D approaches was the lack of spatial control over chemistry with 3D materials. One possible solution to this limitation is 3D bioprinting, which could be used to design the custom scaffolds and tissues (9).

In contrast to traditional engineering techniques, 3D cell printing technology is especially advantageous because it can integrate multiple biophysical and biochemical cues spatially for cellular regulation and ensure complex structures with precise control and high reproducibility. In particular, for our final goal of clinical practice, extrusion-based bioprinting may be more appropriate for translational application. In addition, as a widely used bioink for extrusion bioprinting, alginate-based hydrogel could maintain stemness of MSC due to the bioinert property and improve biological activity and printability by combining gelatin (10).

Sweat glands (SGs) play a vital role in thermal regulation, and absent or malfunctioning SGs in a hot environment can lead to hyperthermia, stroke, and even death in mammals (11, 12). Each SG is a single tube consisting of a functionally distinctive duct and secretory portions. It has low regenerative potential in response to deep dermal injury, which poses a challenge for restitution of lost cells after wound (13). A major obstacle in SG regeneration, similar to the regeneration of most other glandular tissues, is the paucity of viable cells capable of regenerating multiple tissue phenotypes (12). Several reports have described SG regeneration in vitro; however, dynamic morphogenesis was not identified nor was the overall function of the formed tissues explored (1416). Recent advances in bioprinting and tissue engineering led to the complexities in the matrix design and fabrication with appropriate biochemical cues and biophysical guidance for SG regeneration (1719).

Here, we adopted 3D bioprinting technique to mimic the regenerative microenvironment that directed the specific SG differentiation of MSCs and ultimately guided the formation and function of glandular tissue. We used alginate/gelatin hydrogel as bioinks in this present study due to its good cytocompatibility, printability, and structural maintenance in long-time culture. Although the profound effects of ECM on cell differentiation was well recognized, the importance of biochemical and structural cues of 3D-printed matrix that determined the cell fate of MSCs remained unknown; thus, the present study demonstrated the role of 3D-printed matrix cues on cellular behavior and tissue morphogenesis and might help in developing strategies for MSC-based tissue regeneration or directing stem cell lineage specification by 3D bioprinting.

The procedure for printing the 3D MSC-loaded construct incorporating a specific SG ECM (mouse plantar region dermis, PD) was shown schematically in Fig. 1A. A 3D cellular construct with cross section 30 mm 30 mm and height of 3 mm was fabricated by using the optimized process parameter (20). The 3D construct demonstrated a macroporous grid structure with hydrogel fibers evenly distributed according to the computer design. Both the width of the fibers and the gap between the fibers were homogeneous, and MSCs were embedded uniformly in the hydrogel matrix fibers to result in a specific 3D microenvironment. (Fig. 1B).

(A) Schematic description of the approach. (B) Full view of the cellular construct and representative microscopic and fluorescent images and the quantitative parameters of 3D-printed construct (scale bars, 200 m). Photo credit: Bin Yao, Wound Healing and Cell Biology Laboratory, Institute of Basic Medical Sciences, General Hospital of PLA. (C) Representative microscopy images of cell aggregates and tissue morphology at 3, 7, and 14 days of culture (scale bars, 50 m) and scanning electron microscopy (sem) images of 3D structure (scale bars, 20 m). PD+/PD, 3D construct with and without PD. (D) DNA contents, collagen, and GAGs of native tissue and PD. (E) Proliferating cells were detected through Ki67 stain at 3, 7, and 14 days of culture. (F) Live/dead assay show cell viability at days 3, 7, and 14. *P < 0.05.

During the maintenance of constructs for stem cell expansion, MSCs proliferated to form aggregates of cells but self-assembled to an SG-like structure only with PD administration (Fig. 1C and fig. S1, A to C). We carried out DNA quantification assay to evaluate the cellular content in PD and found the cellular matrix with up to 90% reduction, only 3.4 0.7 ng of DNA per milligram tissue remaining in the ECM. We also estimated the proportions of collagen and glycosaminoglycans (GAGs) in ECM through hydroxyproline assay and dimethylmethylene blue assay, the collagen contents could increase to 112.6 11.3%, and GAGs were well retained to 81 9.6% (Fig. 1D). Encapsulated cells were viable, with negligible cell death apparent during extrusion and ink gelation by ionic cross-linking, persisting through extended culture in excess of 14 days. The fluorescence intensity of Ki67 of MSCs cultured in 2D condition decreased from days 3 (152.7 13.4) to 14 (29.4 12.9), while maintaining higher intensity of MSCs in 3D construct (such as 211.8 19.4 of PD+3D group and 209.1 22.1 of PD3D group at day 14). And the cell viability in 3D construct was found to be sufficiently high (>80%) when examined on days 3, 7, and 14. The phenomenon of cell aggregate formation and increased cell proliferation implied the excellent cell compatibility of the hydrogel-based construct and promotion of tissue development of 3D architectural guides, which did not depend on the presence or absence of PD (Fig. 1, E and F).

The capability of 3D-printed construct with PD directing MSC to SGs in vitro was investigated. The 3D construct was dissolved, and cells were isolated at days 3, 7, and 14 for transcriptional analysis. Expression of the SG markers K8 and K18 was higher from the 3D construct with (3D/PD+) than without PD (3D/PD); K8 and K18 expression in the 3D/PD construct was similar to with control that MSCs cultured in 2D condition, which implied the key role of PD in SG specification. As compared with the 2D culture condition, 3D administration (PD+) up-regulated SG markers, which indicated that the 3D structure synergistically boosted the MSC differentiation (Fig. 2A).

(A) Transcriptional expression of K8, K18, Fxyd2, Aqp5, and ATP1a1 in 3D-bioprinted cells with and without PD in days 3, 7, and 14 culture by quantitative real-time polymerase chain reaction (qRT-PCR). Data are means SEM. (B) Comparison of SG-specific markers K8 and K18 in 3D-bioprinted cells with and without PD (K8 and K18, red; DAPI, blue; scale bars, 50 m). (C and D) Comparison of SG secretion-related markers ATP1a1 (C) and Ca2+ (D) in 3D-bioprinted cells with and without PD [ATP1a1 and Ca2+, red; 4,6-diamidino-2-phenylindole (DAPI), blue; scale bars, 50 m].

In addition, we tested secretion-related genes to evaluate the function of induced SG cells (iSGCs). Although levels of the ion channel factors of Fxyd2 and ATP1a1 were increased notably in 2D culture with PD and ATP1a1 up-regulated in the 3D/PD construct, all the secretory genes of Fxyd2, ATP1a1, and water transporter Aqp5 showed the highest expression level in the 3D/PD+ construct (Fig. 2A). Considering the remarkable impact, further analysis focused on 3D constructs.

Immunofluorescence staining confirmed the progression of MSC differentiation. At day 7, cells in the 3D/PD+ construct began to express K8 and K18, which was increased at day 14, whereas cells in the 3D/PD construct did not express K8 and K18 all the time (Fig. 2B and fig. S2A). However, the expression of ATP1a1 (ATPase Na+/K+ transporting subunit alpha 1) and free Ca2+ concentration did not differ between cells in the 3D/PD+ and 3D/PD constructs (Fig. 2, C and D). By placing MSCs in such a 3D environment, secretion might be stimulated by rapid cell aggregation without the need for SG lineage differentiation. Cell aggregationimproved secretion might be due to the benefit of cell-cell contact (fig. S2B) (21, 22).

To map the cell fate changes during the differentiation between MSCs and SG cells, we monitored the mRNA levels of epithelial markers such as E-cadherin, occludin, Id2, and Mgat3 and mesenchymal markers N-cadherin, vimentin, Twist1, and Zeb2. The cells transitioned from a mesenchymal status to a typical epithelial-like status accompanied by mesenchymal-epithelial transition (MET), then epithelial-mesenchymal transition (EMT) occurred during the further differentiation of epithelial lineages to SG cells (fig. S3A). In addition, MET-related genes were dynamically regulated during the SG differentiation of MSCs. For example, the mesenchymal markers N-cadherin and vimentin were down-regulated from days 1 to 7, which suggested cells losing their mesenchymal phenotype, then were gradually up-regulated from days 7 to 10 in their response to the SG phenotype and decreased at day 14. The epithelial markers E-cadherin and occludin showed an opposite expression pattern: up-regulated from days 1 to 5, then down-regulated from days 7 to 10 and up-regulated again at day 14. The mesenchymal transcriptional factors ZEB2 and Twist1 and epithelial transcriptional factors Id2 and Mgat3 were also dynamically regulated.

We further analyzed the expression of these genes at the protein level by immunofluorescence staining (figs. S3B and S4). N-cadherin was down-regulated from days 3 to 7 and reestablished at day 14, whereas E-cadherin level was increased from days 3 to 7 and down-regulated at day 14. Together, these results indicated that a sequential and dynamic MET-EMT process underlie the differentiation of MSCs to an SG phenotype, perhaps driving differentiation more efficiently (23). However, the occurrence of the MET-EMT process did not depend on the presence of PD. Thus, a 3D structural factor might also participate in the MSC-specific differentiation (fig. S3C).

To investigate the underlying mechanism of biochemical cues in lineage-specific cell fate, we used quantitative proteomics analysis to screen the ECM factors differentially expressed between PD and dorsal region dermis (DD) because mice had eccrine SGs exclusively present in the pads of their paws, and the trunk skin lacks SGs. In total, quantitative proteomics analyses showed higher expression levels of 291 proteins in PD than DD. Overall, 66 were ECM factors: 23 were significantly up-regulated (>2-fold change in expression). We initially determined the level of proteins with the most significant difference after removing keratins and fibrin: collagen triple helix repeat containing 1 (CTHRC1) and thrombospondin 1 (TSP1) (fig. S5). Western blotting was performed to further confirm the expression level of CTHRC1 and TSP1, and we then confirmed that immunofluorescence staining at different developmental stages in mice revealed increased expression of CTHRC1 in PD with SG development but only slight expression in DD at postnatal day 28, while TSP1 was continuously expressed in DD and PD during development (Fig. 3, A to C). Therefore, TSP1 was required for the lineage-specific function during the differentiation in mice but was not dispensable for SG development.

(A and B) Differential expression of CTHRC1 and TSP1in PD and back dermis (DD) ECM of mice by proteomics analysis (A) and Western blotting (B). (C) CTHRC1 and TSP1 expression in back and plantar skin of mice at different developmental times. (Cthrc1/TSP1, red; DAPI, blue; scale bars, 50 m).

According to previous results of the changes of SG markers, 3D structure and PD were both critical to SG fate. Then, we focused on elucidating the mechanisms that underlie the significant differences observed in 2D and 3D conditions with or without PD treatment. To this end, we performed transcriptomics analysis of MSCs, MSCs treated with PD, MSCs cultured in 3D construct, and MSC cultured in 3D construct with PD after 3-day treatment. We noted that the expression profiles of MSCs treated with 3D, PD, or 3D/PD were distinct from the profiles of MSCs (Fig. 4A). Through Gene Ontology (GO) enrichment analysis of differentially expressed genes, it was shown that PD treatment in 2D condition induced up-regulation of ECM and inflammatory response term, and the top GO term for MSCs in 3D construct was ECM organization and extracellular structure organization. However, for the MSCs with 3D/PD treatment, we found very significant overrepresentation of GO term related to branching morphogenesis of an epithelial tube and morphogenesis of a branching structure, which suggested that 3D structure cues and biochemical cues synergistically initiate the branching of gland lineage (fig S6). Heat maps of differentially expressed ECM organization, cell division, gland morphogenesis, and branch morphogenesis-associated genes were shown in fig. S7. To find the specific genes response to 3D structure cues facilitating MSC reprogramming, we analyzed the differentially expressed genes of four groups of cells (Fig. 4B). The expression of Vwa1, Vsig1, and Hmox1 were only up-regulated with 3D structure stimulation, especially the expression of Hmox1 showed a most significant increase and even showed a higher expression addition with PD, which implied that Hmox1 might be the transcriptional driver of MSC differentiation response to 3D structure cues. Differential expression of several genes was confirmed by quantitative polymerase chain reaction (qPCR): Mmp9, Ptges, and Il10 were up-regulated in all the treated groups. Likewise, genes involving gland morphogenesis and branch morphogenesis such as Bmp2, Tgm2, and Sox9 showed higher expression in 3D/PD-treated group. Bmp2 was up-regulated only in 3D/PD-treated group, combined with the results of GO analysis, we assumed that Bmp2 initiated SG fate through inducing branch morphogenesis and gland differentiation (Fig. 4C).

(A) Gene expression file of four groups of cells (R2DC, MSCs; R2DT, MSC with PD treatment; R3DC, MSC cultured in 3D construct; and R3DT, MSC treated with 3D/PD). (B) Up-regulated genes after treatment (2DC, MSCs; 2DT, MSC with PD treatment; 3DC, MSC cultured in 3D construct; and 3DT, MSC treated with 3D/PD). (C) Differentially expressed genes were further validated by RT-PCR analysis. [For all RT-PCR analyses, gene expression was normalized to glyceraldehyde-3-phosphate dehydrogenase (GAPDH) with 40 cycles, data are represented as the means SEM, and n = 3].

To validate the role of HMOX1 and CTHRC1 in the differentiation of MSCs to SG lineages, we analyzed the gene expression of Bmp2 by regulating the expression of Hmox1 and CTHRC1 based on the 3D/PD-treated MSCs. The effects of caffeic acid phenethyl ester (CAPE) and tin protoporphyrin IX dichloride (Snpp) on the expression of Hmox1 were evaluated by quantitative real-time (qRT)PCR. Hmox1 expression was significantly activated by CAPE and reduced by Snpp. Concentration of CTHRC1 was increased with recombinant CTHRC1 and decreased with CTHRC1 antibody. That is, it was negligible of the effects of activator and inhibitor of Hmox1 and CTHRC1 on cell proliferation (fig. S8, A and B). Hmox1 inhibition or CTHRC1 neutralization could significantly reduce the expression of Bmp2, while Hmox1 activation or increased CTHRC1 both activated Bmp2 expression. Furthermore, Bmp2 showed highest expression by up-regulation of Hmox1 and CTHRC1 simultaneously and sharply decreased with down-regulation of Hmox1 and CTHRC1 at the same time (Fig. 5A). Immunofluorescent staining revealed that the expression of bone morphogenetic protein 2 (BMP2) at the translational level with CTHRC1 and Hmox1 regulation showed a similar trend with transcriptional changes (Fig. 5B). Likewise, the expression of K8 and K18 at transcriptional and translational level changed similarly with CTHRC1 and Hmox1 regulation (fig. S9, A and B). These results suggested that CTHRC1 and Hmox1 played an essential role in SG fate separately, and they synergistically induced SG direction from MSCs (Fig. 5C).

(A and B) Transcriptional analysis (A) and translational analysis (PD, MSCs; PD+, MSCs with 3D/PD treatment; CAPE, MSCs treated with 3D/PD and Hmox1 activator; Snpp, MSCs treated with 3D/PD and Hmox1 inhibitor; Cthrc1, MSCs treated with 3D/PD and recombinant CTHRC1; anti, MSCs treated with 3D/PD and CTHRC1 antibody: +/+, MSCs treated with 3D/PD and Hmox1 activator and recombinant CTHRC1; and /, MSCs treated with 3D/PD and Hmox1 inhibitor and CTHRC1 antibody. Data are represented as the means SEM and n = 3) (B) of bmp2 with regulation of CTHRC1 and Hmox1. (C) The graphic illustration of 3D-bioprinted matrix directed MSC differentiation. CTHRC1 is the main biochemical cues during SG development, and structural cues up-regulated the expression of Hmox1 synergistically initiated branching morphogenesis of SG. *P < 0.05.

Next, we sought to assess the repair capacity of iSGCs for in vivo implications, the 3D-printed construct with green fluorescent protein (GFP)labeled MSCs was transplanted in burned paws of mice (Fig. 6A). We measured the SG repair effects by iodine/starch-based sweat test at day 14. Only mice with 3D/PD treatment showed black dots on foot pads (representing sweating), and the number increased within 10 min; however, no black dots were observed on untreated and single MSC-transplanted mouse foot pads even after 15 min (Fig. 6B). Likewise, hematoxylin and eosin staining analysis revealed SG regeneration in 3D/PD-treated mice (Fig. 6C). GFP-positive cells were characterized as secretory lumen expressing K8, K18, and K19. Of note, the GFP-positive cells were highly distributed in K14-positive myoepithelial cells of SGs but were absent in K14-positive repaired epidermal wounds (Fig. 6, D and E). Thus, differentiated MSCs enabled directed restitution of damaged SG tissues both at the morphological and functional level.

(A) Schematic illustration of approaches for engineering iSGCs and transplantation. (B) Sweat test of mice treated with different cells. Photo credit: Bin Yao, Wound Healing and Cell Biology Laboratory, Institute of Basic Medical Sciences, General Hospital of PLA. (C) Histology of plantar region without treatment and transplantation of MSCs and iSGCs (scale bars, 200 m). (D) Involvement of GFP-labeled iSGCs in directed regeneration of SG tissue in thermal-injured mouse model (K14, red; GFP, green; DAPI, blue; scale bar, 200 m). (E) SG-specific markers K14, K19, K8, and K18 detected in regenerated SG tissue (arrows). (K14, K19, K8, and K18, red; GFP, green; scale bars, 50 m).

A potential gap in MSC-based therapy still exists between current understandings of MSC performance in vivo in their microenvironment and their intractability outside of that microenvironment (24). To regulate MSCs differentiation into the right phenotype, an appropriate microenvironment should be created in a precisely controlled spatial and temporal manner (25). Recent advances in innovative technologies such as bioprinting have enabled the complexities in the matrix design and fabrication of regenerative microenvironments (26). Our findings demonstrated that directed differentiation of MSCs into SGs in a 3D-printed matrix both in vitro and in vivo was feasible. In contrast to conventional tissue-engineering strategies of SG regeneration, the present 3D-printing approach for SG regeneration with overall morphology and function offered a rapid and accurate approach that may represent a ready-to-use therapeutic tool.

Furthermore, bioprinting MSCs successfully repaired the damaged SG in vivo, suggesting that it can improve the regenerative potential of exogenous differentiated MSCs, thereby leading to translational applications. Notably, the GFP-labeled MSC-derived glandular cells were highly distributed in K14-positive myoepithelial cells of newly formed SGs but were absent in K14-positive repaired epidermal wounds. Compared with no black dots were observed on single MSC-transplanted mouse foot pads, the black dots (representing sweating function) can be observed throughout the entire examination period, and the number increased within 10 min on MSC-bioprinted mouse foot pads. Thus, differentiated MSCs by 3D bioprinting enabled exclusive restitution of damaged SG tissues morphologically and functionally.

Although several studies indicated that engineering 3D microenvironments enabled better control of stem cell fates and effective regeneration of functional tissues (2730), there were no studies concerning the establishment of 3D-bioprinted microenvironments that can preferentially induce MSCs differentiating into glandular cells with multiple tissue phenotypes and overall functional tissue. To find an optimal microenvironment for promoting MSC differentiation into specialized progeny, biochemical properties are considered as the first parameter to ensure SG specification. In this study, we used mouse PD as the main composition of a tissue-specific ECM. As expected, this 3D-printed PD+ microenvironment drove the MSC fate decision to enhance the SG phenotypic profile of the differentiated cells. By ECM differential protein expression analysis, we identified that CTHRC1 was a critical biochemical regulator of 3D-printed matrix for SG specification. TSP1 was required for the lineage-specific function during the differentiation in mice but was not dispensable for SG development. Thus, we identified CTHRC1 as a specific factor during SG development. To our knowledge, this is the first demonstration of CTHRC1 involvement in dictating MSC differentiation to SG, highlighting a potential therapeutic tool for SG injury.

The 3D-printed matrix also provided architectural guides for further SG morphogenesis. Our results clearly show that the 3D spatial dimensionality allows for better cell proliferation and aggregation and affect the characteristics of phenotypic marker expression. Notably, the importance of 3D structural cues on MSC differentiation was further proved by MET-EMT process during differentiation, where the influences did not depend on the presence of biochemical cues. To fully elucidate the underlying mechanisms, we first examined how 3D structure regulating stem cell fate choices. According to our data, Hmox1 is highly up-regulated in 3D construct, which were supposed to response to hypoxia, with a previously documented role in MSC differentiation (31, 32). It is suggested that 3D microenvironment induced rapid cell aggregation leading to hypoxia and then activated the expression of Hmox1.

Through regulation of the expression of Hmox1 and addition or of CTHRC1 in the matrix, we confirmed that each of them is critical for SG reprogramming, respectively. Thus, biochemical and structural cues of 3D-printed matrix synergistically creating a microenvironment could enhance the accuracy and efficiency of MSC differentiation, thereby leading to resulting SG formation. Although we further need a more extensive study examining the role of other multiple cues and their possible overlap function in regulating MSC differentiation, our findings suggest that CTHRC1 and Hmox1 provide important signals that cooperatively modulate MSC lineage specification toward sweat glandular lineage. The 3D structure combined with PD stimulated the GO functional item of branch morphogenesis and gland formation, which might be induce by up-regulation of Bmp2 based on the verification of qPCR results. Although our results could not rule out the involvement of other factors and their possible overlapping role in regulating MSC lineage specification toward SGs, our findings together with several literatures suggested that BMP2 plays a critical role in inducing branch morphogenesis and gland formation (3335).

In summary, our findings represented a novel strategy of directing MSC differentiation for functional SG regeneration by using 3D bioprinting and pave the way for a potential therapeutic tool for other complex glandular tissues as well as further investigation into directed differentiation in 3D conditions. Specifically, we showed that biochemical and structural cues of 3D-printed matrix synergistically direct MSC differentiation, and our results highlighted the importance of 3D-printed matrix cues as regulators of MSC fate decisions. This avenue opens up the intriguing possibility of shifting from genetic to microenvironmental manipulations of cell fate, which would be of particular interest for clinical applications of MSC-based therapies.

The main aim and design of the study was first to determine whether by using 3D-printed microenvironments, MSCs can be directed to differentiate and regenerate SGs both morphologically and functionally. Then, to investigate the underlying molecular mechanism of biochemical and structural cues of 3D-printed matrix involved in MSCs reprogramming. The primary aims of the study design were as follows: (i) cell aggregation and proliferation in a 3D-bioprinted construct; (ii) differentiation of MSCs at the cellular phenotype and functional levels in the 3D-bioprinted construct; (iii) the MET-EMT process during differentiation; (iv) differential protein expression of the SG niche in mice; (v) differential genes expression of MSCs in 3D-bioprinted construct; (vi) the key role of CTHRC1 and HMOX1 in MSCs reprogramming to SGCs; and (vii) functional properties of regenerated SG in vivo.

Gelatin (Sigma-Aldrich, USA) and sodium alginate (Sigma-Aldrich, USA) were dissolved in phosphate-buffered saline (PBS) at 15 and 1% (w/v), respectively. Both solutions were sterilized under 70C for 30 min three times at an interval of 30 min. The sterilized solutions were packed into 50-ml centrifuge tubes, stored at 4C, and incubated at 37C before use.

From wild-type C57/B16 mice (Huafukang Co., Beijing) aged 5 days old, dermal homogenates were prepared by homogenizing freshly collected hairless mouse PD with isotonic phosphate buffer (pH 7.4) for 20 min in an ice bath to obtain 25% (w/v) tissue suspension. The supernatant was obtained after centrifugation at 4C for 20 min at 10,000g. The DNA content was determined using Hoechst 33258 assay (Beyotime, Beijing). The fluorescence intensity was measured to assess the amount of remaining DNA within the decellularized ECMs and the native tissue using a fluorescence spectrophotometer (Thermo Scientific, Evolution 260 Bio, USA). The GAGs content was estimated via 1,9-dimethylmethylene blue solution staining. The absorbance was measured with microplate reader at wavelength of 492 nm. The standard curve was made using chondroitin sulfate A. The total COL (Collagen) content was determined via hydroxyproline assay. The absorbance of the samples was measured at 550 nm and quantified by referring to a standard curve made with hydroxyproline.

MSCs were bioprinted with matrix materials by using an extrusion-based 3D bioprinter (Regenovo Co., Bio-Architect PRO, Hangzhou). Briefly, 10 ml of gelatin solution (10% w/v) and 5 ml of alginate solution (2% w/v) were warmed under 37C for 20 min, gently mixed as bioink and used within 30 min. MSCs were collected from 100-mm dishes, dispersed into single cells, and 200 l of cell suspension was gently mixed with matrix material under room temperature with cell density 1 million ml1. PD (58 g/ml) was then gently mixed with bioink. Petri dishes at 60 mm were used as collecting plates in the 3D bioprinting process. Within a temperature-controlled chamber of the bioprinter, with temperature set within the gelation region of gelatin, the mixture of MSCs and matrix materials was bioprinted into a cylindrical construct layer by layer. The nozzle-insulation temperature and printing chamber temperature were set at 18 and 10C, respectively; nozzles with an inner diameter of 260 m were chosen for printing. The diameter of the cylindrical construct was 30 mm, with six layers in height. After the temperature-controlled bioprinting process, the printed 3D constructs were immersed in 100-mM calcium chloride (Sigma-Aldrich, USA) for 3 min for cross-linking, then washed with Dulbeccos modified Eagle medium (DMEM) (Gibco, USA) medium for three times. The whole printing process was finished in 10 min. The 3D cross-linked construct was cultured in DMEM in an atmosphere of 5% CO2 at 37C. The culture medium was changed to SG medium [contains 50% DMEM (Gibco, New York, NY) and 50% F12 (Gibco) supplemented with 5% fetal calf serum (Gibco), 1 ml/100 ml penicillin-streptomycin solution, 2 ng/ml liothyronine sodium (Gibco), 0.4 g/ml hydrocortisone succinate (Gibco), 10 ng/ml epidermal growth factor (PeproTech, Rocky Hill, NJ), and 1 ml/100 ml insulin-transferrin-selenium (Gibco)] 2 days later. The cell morphology was examined and recorded under an optical microscope (Olympus, CX40, Japan).

Fluorescent live/dead staining was used to determine cell viability in the 3D cell-loaded constructs according to the manufacturers instructions (Sigma-Aldrich, USA). Briefly, samples were gently washed in PBS three times. An amount of 1 M calcein acetoxymethyl (calcein AM) ester (Sigma-Aldrich, USA) and 2 M propidium iodide (Sigma-Aldrich, USA) was used to stain live cells (green) and dead cells (red) for 15 min while avoiding light. A laser scanning confocal microscopy system (Leica, TCSSP8, Germany) was used for image acquisition.

The cell-printed structure was harvested and fixed with a solution of 4% paraformaldehyde. The structure was embedded in optimal cutting temperature (OCT) compound (Sigma-Aldrich, USA) and sectioned 10-mm thick by using a cryotome (Leica, CM1950, Germany). The sliced samples were washed repeatedly with PBS solution to remove OCT compound and then permeabilized with a solution of 0.1% Triton X-100 (Sigma-Aldrich, USA) in PBS for 5 min. To reduce nonspecific background, sections were treated with 0.2% bovine serum albumin (Sigma-Aldrich, USA) solution in PBS for 20 min. To visualize iSGCs, sections were incubated with primary antibody overnight at 4C for anti-K8 (1:300), anti-K14 (1:300), anti-K18 (1:300), anti-K19 (1:300), anti-ATP1a1 (1:300), anti-Ki67 (1:300), antiN-cadherin (1:300), antiE-cadherin (1:300), anti-CTHRC1 (1:300), or anti-TSP1 (1:300; all Abcam, UK) and then incubated with secondary antibody for 2 hours at room temperature: Alexa Fluor 594 goat anti-rabbit (1:300), fluorescein isothiocyanate (FITC) goat anti-rabbit (1:300), FITC goat anti-mouse (1:300), or Alexa Fluor 594 goat anti-mouse (1:300; all Invitrogen, CA). Sections were also stained with 4,6-diamidino-2-phenylindole (Beyotime, Beijing) for 15 min. Stained samples were visualized, and images were captured under a confocal microscope.

To harvest the cells in the construct, the 3D constructs were dissolved by adding 55 mM sodium citrate and 20 mM EDTA (Sigma-Aldrich, USA) in 150 mM sodium chloride (Sigma-Aldrich, USA) for 5 min while gently shaking the petri dish for better dissolving. After transfer to 15-ml centrifuge tubes, the cell suspensions were centrifuged at 200 rpm for 3 min, and the supernatant liquid was removed to harvest cells for further analysis.

Total RNA was isolated from cells by using TRIzol reagent (Invitrogen, USA) following the manufacturers protocol. RNA concentration was measured by using a NanoPhotometer (Implen GmbH, P-330-31, Germany). Reverse transcription involved use of a complementary DNA synthesis kit (Takara, China). Gene expression was analyzed quantitatively by using SYBR green with the 7500 Real-Time PCR System (Takara, China). The primers and probes for genes were designed on the basis of published gene sequences (table S1) (National Center for Biotechnology Information and PubMed). The expression of each gene was normalized to that for glyceraldehyde-3-phosphate dehydrogenase and analyzed by the 2-CT method. Each sample was assessed in triplicate.

The culture medium was changed to SG medium with 2 mM CaCl2 for at least 24 hours, and cells were loaded with fluo-3/AM (Invitrogen, CA) at a final concentration of 5 M for 30 min at room temperature. After three washes with calcium-free PBS, 10 M acetylcholine (Sigma-Aldrich, USA) was added to cells. The change in the Fluo 3 fluorescent signal was recorded under a laser scanning confocal microscopy.

Cell proliferation was evaluated through CCK-8 (Cell counting kit-8) assay. Briefly, cells were seeded in 96-well plates at the appropriate concentration and cultured at 37C in an incubator for 4 hours. When cells were adhered, 10 l of CCK-8 working buffer was added into the 96-well plates and incubated at 37C for 1 hour. Absorbance at 450 nm was measured with a microplate reader (Tecan, SPARK 10M, Austria).

Proteomics of mouse PD and DD involved use of isobaric tags for relative and absolute quantification (iTRAQ) in BGI Company, with differentially expressed proteins detected in PD versus DD. Twofold greater difference in expression was considered significant for further study.

Tissues were grinded and lysed in radioimmunoprecipitation assay buffer (Beyotime, Nanjing). Proteins were separated by 12% SDSpolyacrylamide gel electrophoresis and transferred to a methanol-activated polyvinylidene difluoride membrane (GE Healthcare, USA). The membrane was blocked for 1 hour in PBS with Tween 20 containing 5% bovine serum albumin (Sigma-Aldrich, USA) and probed with the antibodies anti-CTHRC1 (1:1000) and anti-TSP1 (1:1000; both Abcam, UK) overnight at 4C. After 2 hours of incubation with goat anti-rabbit horseradish peroxidaseconjugated secondary antibody (Santa Cruz Biotechnology, CA), the protein bands were detected by using luminal reagent (GE Healthcare, ImageQuant LAS 4000, USA).

Total RNA was prepared with TRIzol (Invitrogen), and RNA sequencing was performed using HiSeq 2500 (Illumina). Genes with false discovery rate < 0.05, fold difference > 2.0, and mean log intensity > 2.0 were considered to be significant.

CAPE or Snpp was gently mixed with bioink at a concentration of 10 M. Physiological concentration of CTHRC1 was measured by enzyme linked immunosorbent assay (ELISA) (80 ng/ml), and then recombinant CTHRC1 or CTHRC1 antibody was added into the bioink at a concentration of 0.4 g/ml. The effect of inhibitor and activator was estimated by qRT-PCR or ELISA.

Mice were anesthetized with pentobarbital (100 mg/kg) and received subcutaneous buprenorphine (0.1 mg/kg) preoperatively. Full-thickness scald injuries were created on paw pads with soldering station (Weller, WSD81, Germany). Mice recovered in clean cages with paper bedding to prevent irritation or infection. Mice were monitored daily and euthanized at 30 days after wounding. Mice were maintained in an Association for Assessment and Accreditation of Laboratory Animal Careaccredited animal facility, and procedures were performed with Institutional Animal Care and Use Committeeapproved protocols.

MSCs in 3D-printed constructs with PD were cultured with DMEM for 2 days and then replaced with SG medium. The SG medium was changed every 2 days, and cells were harvested on day 12. The K18+ iSGCs were sorting through flow cytometry and injected into the paw pads (1 106 cells/50 l) of the mouse burn model by using Microliter syringes (Hamilton, 7655-01, USA). Then, mice were euthanized after 14 days; feet were excised and fixed with 10% formalin (Sigma-Aldrich, USA) overnight for paraffin sections and immunohistological analysis.

The foot pads of anesthetized treated mice were first painted with 2% (w/v) iodine/ethanol solution then with starch/castor oil solution (1 g/ml) (Sigma-Aldrich, USA). After drying, 50 l of 100 M acetylcholine (Sigma-Aldrich, USA) was injected subcutaneously into paws of mice. Pictures of the mouse foot pads were taken after 5, 10, and 15 min.

All data were presented as means SEM. Statistical analyses were performed using GraphPad Prism7 statistical software (GraphPad, USA). Significant differences were calculated by analysis of variance (ANOVA), followed by the Bonferroni test when performing multiple comparisons between groups. P < 0.05 was considered as a statistically significant difference.

Supplementary material for this article is available at http://advances.sciencemag.org/cgi/content/full/6/10/eaaz1094/DC1

Fig. S1. Biocompatibility of 3D-bioprinted construct and cellular morphology in 2D monolayer culture.

Fig. S2. Expression of SG-specific and secretion-related markers in MSCs and SG cells in vitro.

Fig. S3. Transcriptional and translational expression of epithelial and mesenchymal markers in 3D-bioprinted cells with and without PD.

Fig. S4. Expression of N- and E-cadherin in MSCs and SG cells in 2D monolayer culture.

Fig. S5. Proteomic microarray assay of differential gene expression between PD and DD ECM in postnatal mice.

Fig. S6. GO term analysis of differentially expressed pathways.

Fig. S7. Heat maps illustrating differential expression of genes implicated in ECM organization, cell division, and gland and branch morphogenesis.

Fig. S8. The expression of Hmox1 and the concentration of CTHRC1 on treatment and the related effects on cell proliferation.

Fig. S9. The expression of K8 and K18 with Hmox1 and CTHRC1 regulation.

Table S1. Primers for qRT-PCR of all the genes.

This is an open-access article distributed under the terms of the Creative Commons Attribution-NonCommercial license, which permits use, distribution, and reproduction in any medium, so long as the resultant use is not for commercial advantage and provided the original work is properly cited.

Acknowledgments: Funding: This study was supported in part by the National Nature Science Foundation of China (81571909, 81701906, 81830064, and 81721092), the National Key Research Development Plan (2017YFC1103300), Military Logistics Research Key Project (AWS17J005), and Fostering Funds of Chinese PLA General Hospital for National Distinguished Young Scholar Science Fund (2017-JQPY-002). Author contributions: B.Y. and S.H. were responsible for the design and primary technical process, conducted the experiments, collected and analyzed data, and wrote the manuscript. Y.W. and R.W. helped perform the main experiments. Y.Z. and T.H. participated in the 3D printing. W.S. and Z.L. participated in cell experiments and postexamination. S.H. and X.F. collectively oversaw the collection of data and data interpretation and revised 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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Biochemical and structural cues of 3D-printed matrix synergistically direct MSC differentiation for functional sweat gland regeneration - Science...

BERKELEY, Calif.--(BUSINESS WIRE)--GenEdit, Inc., a developer of a novel polymer nanoparticle technology platform for non-viral- and non-lipid-based delivery of gene therapies, today announced that it has entered into a worldwide, exclusive license and collaboration agreement with Editas Medicine, Inc., a leading genome editing company. GenEdit has developed a comprehensive delivery system for CRISPR-based therapeutics, including gene knockout and gene repair therapies, to enable safer delivery options with improved efficiency.

"This license and collaboration agreement further validates the strength of our intellectual property portfolio and the potential of GenEdits technology," said Kunwoo Lee, Ph.D., co-founder and chief executive officer of GenEdit. "We are pleased to establish our relationship with Editas Medicine as they leverage our technology to develop potential genomic medicines."

Under the terms of the agreement, GenEdit has granted Editas Medicine an exclusive worldwide license, with rights to sublicense, to GenEdits Cpf1-based technologies. In return for these rights, GenEdit will receive undisclosed upfront and development milestone payments, including royalties on net sales of products incorporating the licensed intellectual property. In addition, GenEdit and Editas Medicine will collaborate on evaluating delivery of Cpf1-based technologies with GenEdits nanoparticle platform. Editas Medicine will provide research funding and have an option to continue development after the initial collaboration period.

GenEdits nanoparticle platform consists of a proprietary non-viral, non-lipid library of polymers that efficiently encapsulate and deliver cargo [RNA, DNA, protein and/or ribonucleic acid-protein complexes (RNP)] to specific tissues. The company screens the library to identify initial hits and then uses computational analysis and medicinal chemistry for iterative lead optimization. The company has used this platform to identify multiple candidate polymers for efficient and specific delivery of gene editing to a range of tissues.

"Compared to viral vectors and lipid-based nanoparticles, our approach has the potential for better targeting, more cargo, and lower manufacturing cost," said Timothy Fong, Ph.D., chief scientific officer of GenEdit. "In particular, our approach has the potential to enable in vivo gene editing of multiple tissues with CRISPR and expand the potential of gene therapies to treat more diverse sets of diseases."

About GenEdit

GenEdit was founded to transform the delivery of gene and gene editing therapies. We have synthesized the NanoGalaxy library of polymers that can encapsulate RNA, DNA, protein and/or RNP. Through advanced screening methods, computational analysis and iterative medicinal chemistry, we have demonstrated efficient delivery of gene editing cargo to specific tissues. We seek development partnerships for specific tissues and/or gene targets while advancing our internal pipeline of gene editing therapies.

For more information, please visit http://www.genedit.com.

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GenEdit and Editas Medicine Enter into Exclusive License and Collaboration Agreement for Nanoparticle Gene Therapy Delivery - Business Wire

Three investigative therapies by Proteostasis Therapeutics PTI-801, PTI-808, and PTI-428 showed potential to treat cystic fibrosis (CF) patients ineligible for approved CFTR modulators after patient-specific lab models produced promising results that support a future clinical trial.

Funded by the EUs initiative HIT-CF (Human Individualized Therapy of CF), this early study was conducted on patient organoids, which are miniaturized organ models derived from patient cells.

Based on the positive results, a clinical trial in adult CF patients is expected to start in 2020. If successful, the trial results may serve as the basis for a marketing authorization applicationin Europe in 2021.

With the help of CF-Europe (a patient organization) and the European Cystic Fibrosis Society Clinical Trial Network (ECFS-CTN), HIT-CF has been recruiting adult CF patients to collect tissue samples and create organoids, three-dimensional organ models grown in the lab.

Organoids mimic several characteristics of the organ from which they are derived, and are genetically identical to the donor. As such, they allow researchers to study biological processes and response to treatments in an environment that closely resembles human organs. As organoids are basically human cells cultured outside the body, they are said to be ex-vivo models.

The idea is to screen treatment candidates in the lab using intestinal organoids, or mini-intestines, obtained from rectal tissue (biopsies) of patients, which are collected through a quick and painless procedure. Then, based on how the organoids respond to each therapeutic candidate, a group of patients will be selected to enroll in a clinical trial.

Because the organoids can help determine the therapeutic candidate most likely to give the best results, researchers can personalize treatments for each patient before starting the trial.

So far, intestinal organoids from more than 300 patients have been created, of which 65 have been used to test Proteostasis potential CFTR modulators.

Proteostasis is honored to have been invited to participate in the HIT-CF project, and is the only company in the group with a combination of novel CFTR modulators being testedex-vivo. We are very enthusiastic about the progress of the study, Geoffrey Gilmartin, MD, chief medical officer of Proteostasis, said in a press release.

The positive results obtained on organoids support the launch of a clinical trial called CHOICES Crossover trial based on HumanOrganoidIndividual response inCF EfficacyStudy that will test the potential treatments on patients whose organoids responded favorably to the agents.

The study will also evaluate if organoids are good models to identify promising CF therapies, that is, if the responses measured on organoids translate to potential clinical benefits in patients, as reflected by lung function tests (FEV1) or sweat tests.

CHOICES will be a placebo-controlled, double-blind study that includes an eight-week treatment period, plus six months of constant dosing.

The study includes Proteostasis three candidate CFTR modulators, specially intended for patients who carry rarer CFTR genetic defects. All three compounds have different modes of action. PTI-801 works as a CFTR corrector, PTI-808 is a CFTR potentiator, and PTI-428 is a CFTR amplifier.

The trial is planned to start in mid-2020, with its first data anticipated for the end of 2020.

If moving forward, CHOICES will become the first trial based on personalized medicine for CF patients.

The inequality in access to CFTR modulators is an acute problem across Europe where 1 in 5 individuals do not have a F508del mutation [the most common CF-causing mutation]. In addition, drug reimbursement policies are leading to an ever-growing gap between patients who do, and those who do not have effective treatment options, said Christiane De Boeck, Work Package Leader at HIT-CF.

At HIT-CF Europe, we believe that novel strategies such as personalized medicine and development of new treatment options are central to addressing the inequality of access across the continent. We are thrilled with these initial results and look forward to providing additional updates, De Boeck added.

Gilmartin said that in Europe more than 2,300 adult CF patients are ineligible for approved CFTR modulators, and therefore excluded from participating in clinical trials.

This projects proposed personalized medicine approach is paving a potential new way to develop and provide access to novel CFTR modulators for patients with the most dire need for treatment options that target the cause of the disease. Additionally, based on an individual patients disease phenotype, and not just the genetic designation, this approach could also create a new path towards more effective treatment for all people with CF, Gilmartin said.

Proteostasis is also running a clinical trial evaluating a combination of the three candidate therapies for the treatment of CF patients who have at least one copy of the F508del mutation in the CFTR gene.

Ana is a molecular biologist enthusiastic about innovation and communication. In her role as a science writer she wishes to bring the advances in medical science and technology closer to the public, particularly to those most in need of them. Ana holds a PhD in Biomedical Sciences from the University of Lisbon, Portugal, where she focused her research on molecular biology, epigenetics and infectious diseases.

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Patrcia holds her PhD in Medical Microbiology and Infectious Diseases from the Leiden University Medical Center in Leiden, The Netherlands. She has studied Applied Biology at Universidade do Minho and was a postdoctoral research fellow at Instituto de Medicina Molecular in Lisbon, Portugal. Her work has been focused on molecular genetic traits of infectious agents such as viruses and parasites.

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Personalized CF Medicine to be Tested for Rare Genetic Defects in Europe - Cystic Fibrosis News Today

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Innovation being synonymous with Mayo Clinic is nothing new. But now, thanks to Rochesters massive, multiyear undertaking to present the entire city as a beacon for innovators and entrepreneurs, the whole region 75 miles south of the Twin Cities is poised for a technological and economic renaissance.

Finance & Commerce recently hosted a panel discussion about what Rochesters future might hold in those regards. The chat took place at One Discovery Square in Rochester.

The panelists included:

Executive director, Collider Foundation

Traci Downs

President and CEO, Medical Alley Association

Shaye Mandle

Medical director of business development and dermatologic surgeon, Mayo Clinic

Dr. Clark Otley

President and CEO, Vyriad; professor, Mayo Clinic

Dr. Stephen Russell

Director of business development, Discovery Square

Chris Schad

Co-founder and general partner of Capita3

Pam York

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Experts Forum: Creating a cluster of innovation in Rochester - Finance and Commerce

CAMBRIDGE, Mass., Dec. 13, 2019 (GLOBE NEWSWIRE) -- Sarepta Therapeutics, Inc. (NASDAQ:SRPT), the leader in precision genetic medicine for rare diseases, announced today that it has entered into an agreement with funds managed by Pharmakon Advisors, LP, that provides Sarepta with up to $500 million of borrowing capacity in two tranches. The first $250 million (Tranche A) is available shortly after closing in December 2019, with an additional $250 million (Tranche B) available at Sareptas option by Dec. 31, 2020, subject to certain conditions. Both tranches are available at a rate of 8.5% annually, payable quarterly. The facility will mature 48 months from the Tranche A closing date. Additional information on the agreement will be set forth in a Form 8-K to be filed by the Company with theSecurities and Exchange Commission.

Pharmakon Advisors, LP, is the investment manager of the BioPharma Credit funds including BioPharma Credit Investments V LP and BioPharma Credit PLC (LON:BPCR), the only listed investor specialized in life sciences debt.

AboutSarepta TherapeuticsSarepta is at the forefront of precision genetic medicine, having built an impressive and competitive position in Duchenne muscular dystrophy (DMD) and more recently in gene therapies for Limb-girdle muscular dystrophy diseases (LGMD), Charcot-Marie-Tooth (CMT), MPS IIIA and other CNS-related disorders, totaling over 20 therapies in various stages of development. The Companys programs and research focus span several therapeutic modalities, including RNA, gene therapy and gene editing. Sarepta is fueled by an audacious but important mission: to profoundly improve and extend the lives of patients with rare genetic-based diseases. For more information, please visit http://www.sarepta.com.

Forward-Looking StatementThis press release contains "forward-looking statements." Any statements contained in this press release that are not statements of historical fact may be deemed to be forward-looking statements. Words such as "believes," "anticipates," "plans," "expects," "will," "intends," "potential," "possible" and similar expressions are intended to identify forward-looking statements. These forward-looking statements include statements regarding Sareptas ability to borrow funds under the agreement with Pharmakon Advisors, L.P., and the timing and terms of the borrowing; and Sareptas mission to profoundly improve and extend the lives of patients with rare genetic-based diseases.

These forward-looking statements involve risks and uncertainties, many of which are beyond Sarepta's control. Known risk factors include, among others, market conditions, Sareptas market capitalization, any refusal by Pharmakon Advisors, L.P. to fund and other Company factors or circumstances that could negatively impact Sareptas ability to satisfy its obligations or borrow under the terms of the agreement with Pharmakon Advisors, L.P. There can be no assurance that Sarepta will be able to comply with the terms of the agreement with Pharmakon Advisors, L.P., which may result in an event of default under such agreement that could give Pharmakon Advisors, L.P. the right to require immediate payment of any amounts borrowed under such agreement or to exercise its rights with respect to the assets of Sarepta that are collateral or have been pledged by Sarepta as security or other assets of Sarepta; Sarepta may not be able to execute on its business plans, including meeting its expected or planned regulatory milestones and timelines, research and clinical development plans, and bringing its product candidates to market, for various reasons, some of which may be outside of Sareptas control, including possible limitations of company financial and other resources, manufacturing limitations that may not be anticipated or resolved for in a timely manner, and regulatory, court or agency decisions, such as decisions by the United States Patent and Trademark Office with respect to patents that cover Sareptas product candidates; and those risks identified under the heading Risk Factors in Sareptas most recent Annual Report on Form 10-K for the year ended December 31, 2018 and most recent Quarterly Report on Form 10-Q filed with the Securities and Exchange Commission (SEC) as well as other SEC filings made by the Company which you are encouraged to review.

Any of the foregoing risks could materially and adversely affect the Companys business, results of operations and the trading price of Sareptas common stock. We caution investors not to place considerable reliance on the forward-looking statements contained in this press release. Sarepta does not undertake any obligation to publicly update its forward-looking statements based on events or circumstances after the date hereof.

Internet Posting of Information

We routinely post information that may be important to investors in the 'For Investors' section of our website atwww.sarepta.com. We encourage investors and potential investors to consult our website regularly for important information about us.

Source: Sarepta Therapeutics, Inc.

Sarepta Therapeutics, Inc.

Investors:Ian Estepan, 617-274-4052iestepan@sarepta.com

Media:Tracy Sorrentino, 617-301-8566tsorrentino@sarepta.com

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Sarepta Therapeutics Announces $250 Million of Non-Dilutive Senior Secured Loan Financing - GlobeNewswire

December 12, 2019 -Payers are using coordinated care and precision medicine to make diagnoses more quickly and ensure a strong treatment plan for severe and chronic disease management.

Early detection of chronic and severe diseases can mean the difference between life and death. It can also mean the difference between affordable therapies and crippling medical bills.

A March 2018 study found that early cancer diagnosis could result in significant cost savings nationally. Researchers looked at 17 types of cancer and estimated that early detection could save, conservatively, $26 billion nationally.

Recognizing what is at stake, payers take different approaches to catching severe or chronic illnesses in their formative stages.

Coordinated care is a simple, well-tested method for both chronic disease prevention and chronic disease management.

READ MORE: Chronic Disease Coordinated Care May Not Impact Pediatric Spending

Humana recently announced that it would pursue a traditional approach to ensure that patients in danger of chronic kidney and end of life renal disease find out early and get the support they need.

Humana will task skilled provider teams with catching these diseases earlier and implementing personalized treatments.

This coordinated care strategy builds a team of nephrologists, nurses, dietitians, and social workers from one of Humanas two partnerseither Monogram Health or Somatus, depending on geographic location.

The providers will work with the patients primary care physician to determine the best treatments and provide home healthcare options, patient education, and mental healthcare support through counseling.

This multidisciplinary approach will focus on detecting kidney disease earlier, slowing disease progression, and utilizing therapies that enable members to receive care in the convenience of their own home, said William Shrank, MD, MPHS, Humanas chief medical and corporate affairs officer.

READ MORE: Cigna and MSK Start Value-Based, Coordinated Cancer Care Program

Through this collaboration, we will strengthen care coordination for Humana members with kidney disease. Our partnerships will offer customized care options, and will empower patients with education and engagement tools to better manage their condition.

In February, Humana took a similar approach with its oncology program, enhancing its coordinated care strategy and using analytics to ensure quality care.

With new advancements every day in genetic therapies, precision medicine is another method payers use to ensure that patients receive a quick diagnosis and the best treatment plan.

CVS Health launched an oncology care program called Transform Oncology Care, which uses precision medicine to identify and treat cancer patients. The program is rolling out to Aetna members in 12 states but is also available for use by other payers.

Due to CVS Healths geographic and data footprint, it can assess the likelihood that a patient will get cancer. With that information, the patients provider can intervene early on to pursue preventive care, screenings, or therapies.

READ MORE: Precision Medicine Challenges Persist, Aetna Leads Response

When it comes to identifying the appropriate therapies, the program allows providers to use genetics to identify the best course of treatment for a patient recently diagnosed with cancer.

Timing in cancer care is everything and when a patient does not get started on the right treatment it can result in progression and higher costs, said Alan Lotvin, MD, executive vice president and chief transformation officer at CVS Health.

We are the first company working to make the latest in precision medicine accessible to more patients and further empower informed treatment decision-making based on a patient's genetic profile to give them the best chance for successful treatment and improved quality-of-life.

Working in coordination with its third-party vendor, Tempus, CVS Healths new program will enable patients to undergo a broad-panel gene sequencing test once diagnosed to determine the best treatment. This is ideal not only for patients in early stages of cancer, but especially for patients in more advanced stages who need to start treatment as soon as possible.

Because genomic sequencing has certain eligibility requirements, providers are not always aware that gene sequencing is an option open to their patient.

In order to ensure that oncologists prescribe gene sequencing to eligible patients, CVS Health introduced a web-based provider portal into its e-prescribing software which allows oncologists to see the patients eligibility for the broad-panel gene sequencing tests among other functions.

For those who qualify, the program identifies the best treatment options based on genetic makeup. It also alerts providers to potential clinical trials that patients can enroll in and makes the enrollment process easier and faster.

The program integrates National Comprehensive Cancer Network guidelines which are constantly updated for the most recent suggested prescribing and treatment options.

Critically, this service can be employed at the point of detection, so treatments can be identified immediately, and a therapeutic strategy quickly determined.

CVS Health combines this digital solution with a nurse-led coordinated care team to continue quality of care after the diagnosis.

This service is available for only fully insured commercial members.

Among its other chronic disease management developments, earlier this year, CVS Health used preventive care to improve diabetes treatment.

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Care Coordination and Precision Medicine Improve Early Diagnoses - HealthPayerIntelligence.com

SAN DIEGO, Dec. 12, 2019 /PRNewswire/ -- Aspen Neuroscience, Inc. today announced its launch following a $6.5 million seed round led by Domain Associates and Axon Ventures and including Alexandria Venture Investments,Arch Venture Partners,OrbiMedand Section 32 to develop the first autologous cell therapies for Parkinson's disease. Aspen's proprietary approach was developed by the company's co-founders, Jeanne F. Loring, Ph.D., Professor Emeritus and founding director of the Center for Regenerative Medicine at The Scripps Research Institute, and Andres Bratt-Leal, Ph.D., a former post-doctoral researcher in Dr. Loring's lab. The company was initially supported by Summit for Stem Cell, a founding partner and non-profit organization which provides a variety of services for people with Parkinson's disease. Aspen is led by industry veteran Howard J. Federoff, M.D., Ph.D., as Chief Executive Officer.

Parkinson's disease is characterized by the loss of specific brain cells that make the chemical dopamine. Without dopamine, nerve cells cannot communicate with muscles and people are left with debilitating motor problems. Aspen is focusing on human pluripotent stem cells, cultured cells that can become any cell type in the human body. The company's research is specific to induced pluripotent stem cells (iPSCs), which it develops by taking a skin biopsy from a person with Parkinson's disease and turning the tissue into pluripotent stem cells using genetic engineering. Aspen then differentiates the pluripotent stem cells into dopamine-releasing neurons that can be transplanted into that same person (autologous), thereby restoring the types of neurons lost in Parkinson's disease.

As an autologous cell therapy for Parkinson's disease, Aspen's treatment would eliminate the need for immunosuppression because the neurons are transplanted back into the same patient from which they were generated. The use of immunosuppression is necessary with currently available cell therapies for Parkinson's disease and when transplanting cells from one patient to another (allogeneic) to prevent rejection but can pre-dispose the patient to life-threatening complications including infection and add cost to the patient and health system. Aspen is the only company in the world offering an autologous neuron replacement therapy for Parkinson's disease.

Aspen encompasses a powerful executive leadership team including Dr. Federoff who, in addition to his leadership roles at the UC Irvine Health System, was the Executive Vice President for Health Sciences and the Executive Dean of Medicine at Georgetown University. Dr. Federoff also has significant biotech industry experience including co-founding MedGenesis Therapeutix and Brain Neurotherapy Bio, as well as leading the U.S. Parkinson's Disease Gene Therapy Study Group. The company is also proud to announce the addition of several experienced and well-known members to its leadership team including Edward Wirth, M.D., Ph.D., as Chief Medical Officer.

Dr. Wirth currently serves as the Chief Medical Ofcer for Lineage Cell Therapeutics where he oversees clinical development of its two therapeutic programs for spinal cord injuries and lung cancer. He received his M.D. and Ph.D. from the University of Florida in 1994 and remained to conduct postdoctoral research including leading the University of Florida team that performed the rst human embryonic spinal cord transplant in the U.S. Dr. Wirth went on to serve as the Medical Director for Regenerative Medicine at Geron Corporation where the world's rst clinical trial of human embryonic stem cell (hESC)-derived product occurred which demonstrated initial clinical safety.

Drs. Federoff and Wirth are joined by Dr. Loring, as Chief Scientific Officer; Jay Sial, as Chief Financial Officer; Andres Bratt-Leal, Ph.D., as Vice President of Research and Development; Thorsten Gorba, Ph.D., as Senior Director of Manufacturing and Naveen M. Krishnan, M.D., M.Phil., as Senior Director of Corporate Development.

"Aspen is developing a restorative, disease modifying autologous neuron therapy for people suffering from Parkinson's disease," said Dr. Federoff. "We are fortunate to have such a high-caliber scientific and medical leadership team to make our treatments a reality. Our cell replacement therapy, which originated in the laboratory of Dr. Jeanne Loring and was later supported by Summit for Stem Cell and its President, Ms. Jenifer Raub, has the potential to release dopamine and reconstruct neural networks where no disease-modifying therapies exist."

Aspen's lead product (ANPD001) is currently undergoing investigational new drug (IND)-enabling studies for the treatment of sporadic Parkinson's disease. Aspen is also developing a gene-edited autologous neuron therapy (ANPD002) that is in the research stage and targeted toward familial forms of Parkinson's disease beginning with the most common genetic variant in the gene encoding glucocerebrosidase (GBA). Aspen leverages proprietary machine-learning tools and artificial intelligence to ensure quality control during manufacturing and to deliver a safe and reproducible product for each cell line.

"Aspen's financial backing, combined with its experienced and proven leadership team, positions it well for future success," said Kim P. Kamdar, Ph.D., Partner at Domain Associates, one of Aspen's seed investors. "Domain prides itself on investing in companies that can translate scientific research into innovative medicines and therapies that make a difference in people's lives. We clearly see Aspen as fitting into that category, as it is the only company using a patient's own cells for replacement therapy in Parkinson's disease."

About Aspen Neuroscience

Aspen Neuroscience Inc. is a development stage, private biotechnology company that uses innovative genomic approaches combined with stem cell biology to deliver patient-specific, restorative cell therapies that modify the course of Parkinson's disease. Aspen's therapies are based upon the scientific work of world-renowned stem cell scientist, Dr. Jeanne Loring, who has developed a novel method for autologous neuron replacement. For more information and important updates, please visithttp://www.aspenneuroscience.com.

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Aspen Neuroscience Launches With $6.5 Million Seed Funding to Advance First-of-its-Kind Personalized Cell Therapy for Parkinson's Disease - P&T...