Your search keyword '"Niklason LE"' showing total 177 results

1. Lung regeneration: progress and challenges: KL-022

Author

Niklason, Le

Published

2011

2. Inhibition of Platelet Derived Growth Factor Receptor Tyrosine Kinase by Intracisternal Imatinib does not Prevent Subarachnoid Hemorrhage Associated Vascular Proliferation or Cerebral Vasospasm

Author

Boone, Frederick W. Lombard, Niklason Le, Cecil O. Borel, and Miller Ca

Subjects

Subarachnoid hemorrhage, biology, business.industry, Imatinib, medicine.disease, Anesthesiology and Pain Medicine, Cerebral vasospasm, Cancer research, biology.protein, Medicine, Surgery, Neurology (clinical), Vascular proliferation, business, Tyrosine kinase, Platelet-derived growth factor receptor, medicine.drug

Published

2005

3. Vascular Cellular Proliferation in Cerebral Vasospasm After Subarachnoid Hemorrhage in the Rabbit

Author

Miller Ca, Niklason Le, Ching-Tang Wu, Cecil O. Borel, David S. Warner, and Frederick W. Lombard

Subjects

Pathology, medicine.medical_specialty, Anesthesiology and Pain Medicine, Subarachnoid hemorrhage, Cerebral vasospasm, business.industry, Medicine, Surgery, Rabbit (nuclear engineering), Neurology (clinical), business, medicine.disease

Published

2004

4. Blood vessels engineered from human cells.

Author

Kassem M, Burns J, Abd-Allah B, Torensma R, Niklason LE, and Counter CM

Published

2005

5. Engineered vascular grafts lend unique insight to pathophysiology of aortic aneurysms.

Author

Naegeli KM and Niklason LE

Subjects

Humans, Animals, Induced Pluripotent Stem Cells metabolism, Myocytes, Smooth Muscle metabolism, Myocytes, Smooth Muscle pathology, Loeys-Dietz Syndrome genetics, Loeys-Dietz Syndrome pathology, Tissue Engineering, Aortic Aneurysm pathology, Aortic Aneurysm physiopathology, Blood Vessel Prosthesis

Abstract

Yang et al. 1 generate tissue engineered blood vessels from hiPSC-derived smooth muscle cells harboring a mutation found in Loeys-Dietz syndrome. In vitro and in vivo data from these vessels provide new insight into the molecular physiology of aortic aneurysms and may create a paradigm for understanding a suite of vascular diseases., Competing Interests: Declaration of interests L.E.N. is founder and CEO of Humacyte Global, Inc., and serves on its board of directors. K.M.N. is an employee and shareholder of Humacyte Global, Inc. Humacyte Global owns, co-owns, or exclusively licenses 111 patents (including 15 within the United States) within 17 patent families related to tissue-engineered constructs and blood vessels and derivations thereof., (Copyright © 2024 Elsevier Inc. All rights reserved.)

Published

2024

6. Mechano-inhibition of endocytosis sensitizes cancer cells to Fas-induced Apoptosis.

Author

Kural MH, Djakbarova U, Cakir B, Tanaka Y, Chan ET, Arteaga Muniz VI, Madraki Y, Qian H, Park J, Sewanan LR, Park IH, Niklason LE, and Kural C

Subjects

Humans, Animals, Mice, Cell Line, Tumor, 1-(5-Isoquinolinesulfonyl)-2-Methylpiperazine analogs & derivatives, 1-(5-Isoquinolinesulfonyl)-2-Methylpiperazine pharmacology, Xenograft Model Antitumor Assays, Glioblastoma pathology, Glioblastoma metabolism, Glioblastoma drug therapy, Endocytosis drug effects, Apoptosis drug effects, Fas Ligand Protein metabolism, fas Receptor metabolism

Abstract

The transmembrane death receptor Fas transduces apoptotic signals upon binding its ligand, FasL. Although Fas is highly expressed in cancer cells, insufficient cell surface Fas expression desensitizes cancer cells to Fas-induced apoptosis. Here, we show that the increase in Fas microaggregate formation on the plasma membrane in response to the inhibition of endocytosis sensitizes cancer cells to Fas-induced apoptosis. We used a clinically accessible Rho-kinase inhibitor, fasudil, that reduces endocytosis dynamics by increasing plasma membrane tension. In combination with exogenous soluble FasL (sFasL), fasudil promoted cancer cell apoptosis, but this collaborative effect was substantially weaker in nonmalignant cells. The combination of sFasL and fasudil prevented glioblastoma cell growth in embryonic stem cell-derived brain organoids and induced tumor regression in a xenograft mouse model. Our results demonstrate that sFasL has strong potential for apoptosis-directed cancer therapy when Fas microaggregate formation is augmented by mechano-inhibition of endocytosis., (© 2024. The Author(s).)

Published

2024

7. Organ Boundary Circuits Regulate Sox9+ Alveolar Tuft Cells During Post-Pneumonectomy Lung Regeneration.

Author

Obata T, Mizoguchi S, Greaney AM, Adams T, Yuan Y, Edelstein S, Leiby KL, Rivero R, Wang N, Kim H, Yang J, Schupp JC, Stitelman D, Tsuchiya T, Levchenko A, Kaminski N, Niklason LE, and Brickman Raredon MS

Abstract

Tissue homeostasis is controlled by cellular circuits governing cell growth, organization, and differentation. In this study we identify previously undescribed cell-to-cell communication that mediates information flow from mechanosensitive pleural mesothelial cells to alveolar-resident stem-like tuft cells in the lung. We find mesothelial cells to express a combination of mechanotransduction genes and lineage-restricted ligands which makes them uniquely capable of responding to tissue tension and producing paracrine cues acting on parenchymal populations. In parallel, we describe a large population of stem-like alveolar tuft cells that express the endodermal stem cell markers Sox9 and Lgr5 and a receptor profile making them uniquely sensitive to cues produced by pleural Mesothelium. We hypothesized that crosstalk from mesothelial cells to alveolar tuft cells might be central to the regulation of post-penumonectomy lung regeneration. Following pneumonectomy, we find that mesothelial cells display radically altered phenotype and ligand expression, in a pattern that closely tracks with parenchymal epithelial proliferation and alveolar tissue growth. During an initial pro-inflammatory stage of tissue regeneration, Mesothelium promotes epithelial proliferation via WNT ligand secretion, orchestrates an increase in microvascular permeability, and encourages immune extravasation via chemokine secretion. This stage is followed first by a tissue remodeling period, characterized by angiogenesis and BMP pathway sensitization, and then a stable return to homeostasis. Coupled with key changes in parenchymal structure and matrix production, the cumulative effect is a now larger organ including newly-grown, fully-functional tissue parenchyma. This study paints Mesothelial cells as a key orchestrating cell type that defines the boundary of the lung and exerts critical influence over the tissue-level signaling state regulating resident stem cell populations. The cellular circuits unearthed here suggest that human lung regeneration might be inducible through well-engineered approaches targeting the induction of tissue regeneration and safe return to homeostasis., Competing Interests: Competing Interest Statement JCS received lecture honoraria from Böhringer Ingelheim and Kinevant. LEN is a founder and shareholder in Humacyte, Inc, which is a regenerative medicine company. Humacyte produces engineered blood vessels from allogeneic smooth muscle cells for vascular surgery. LEN’s spouse has equity in Humacyte, and LEN serves on Humacyte’s Board of Directors. LEN is an inventor on patents that are licensed to Humacyte and that produce royalties for LEN. Humacyte did not influence the conduct, description or interpretation of the findings in this report. NK reports personal fees from Biogen Idec, Boehringer Ingelheim, Third Rock, Pliant, Numedii, Indalo, Theravance for consulting and non-financial support from Miragen, all outside the submitted work; In addition, NK has patents on new therapies in Pulmonary Fibrosis with royalties paid by biotech, and a patent on blood biomarkers in pulmonary fibrosis.

Published

2024

8. Evaluation of vascular repair by tissue-engineered human acellular vessels or expanded polytetrafluoroethylene grafts in a porcine model of limb ischemia and reperfusion.

Author

Kirkton RD, Watson JDB, Houston R 4th, Prichard HL, Niklason LE, and Rasmussen TE

Subjects

Animals, Blood Vessel Prosthesis, Ischemia surgery, Polytetrafluoroethylene, Prosthesis Design, Reperfusion, Swine, Vascular Patency, Humans, Blood Vessel Prosthesis Implantation, Reperfusion Injury

Abstract

Background: This study evaluated performance of a tissue-engineered human acellular vessel (HAV) in a porcine model of acute vascular injury and ischemia. The HAV is an engineered blood vessel consisted of human vascular extracellular matrix proteins. Limb reperfusion and vascular outcomes of the HAV were compared with those from synthetic expanded polytetrafluoroethylene (ePTFE) grafts., Methods: Thirty-six pigs were randomly assigned to four treatment groups, receiving either the HAV or a PTFE graft following a hind limb ischemia period of either 0 or 6 hours. All grafts were 3-cm-long interposition 6-mm diameter grafts implanted within the right iliac artery. Animals were not immunosuppressed and followed for up to 28 days after surgery. Assessments performed preoperatively and postoperatively included evaluation of graft patency, hind limb function, and biochemical markers of tissue ischemia or reperfusion injury. Histological analysis was performed on explants to assess host cell responses., Results: Postoperative gait assessment and biochemical analysis confirmed that ischemia and reperfusion injury were caused by 6-hour ischemia, regardless of vascular graft type. Hind limb function and tissue damage biomarkers improved in all groups postoperatively. Final patency rates at postoperative day 28 were higher for HAV than for ePTFE graft in both the 0-hour (HAV, 85.7%; ePTFE, 66.7%) and 6-hour (HAV, 100%; ePTFE, 75%) ischemia groups, but these differences were not statistically significant. Histological analyses identified some intimal hyperplasia and host reactivity to the xenogeneic HAV and also to the synthetic ePTFE graft. Positive host integration and vascular cell infiltration were identified in HAV but not ePTFE explants., Conclusion: Based on the functional performance and the histologic profile of explanted HAVs, this study supports further investigation to evaluate long-term performance of the HAV when used to repair traumatic vascular injuries., (Copyright © 2023 The Author(s). Published by Wolters Kluwer Health, Inc.)

Published

2023

9. Biological mechanisms of infection resistance in tissue engineered blood vessels compared to synthetic expanded polytetrafluoroethylene grafts.

Author

Wang J, Blalock SKF, Levitan GS, Prichard HL, Niklason LE, and Kirkton RD

Abstract

Objective: Synthetic expanded polytetrafluoroethylene (ePTFE) grafts are known to be susceptible to bacterial infection. Results from preclinical and clinical studies of bioengineered human acellular vessels (HAVs) have shown relatively low rates of infection. This study evaluates the interactions of human neutrophils and bacteria with ePTFE and HAV vascular conduits to determine whether there is a correlation between neutrophil-conduit interactions and observed differences of their infectivity in vivo., Methods: A phase III comparative clinical study between investigational HAVs (n = 177) and commercial ePTFE grafts (n = 178) used for hemodialysis access (ClinicalTrials.gov Identifier: NCT02644941) was evaluated for conduit infection rates followed by histological analyses of HAV and ePTFE tissue explants. The clinical histopathology of HAV and ePTFE conduits reported to be infected was compared with immunohistochemistry of explanted materials from a preclinical model of bacterial contamination. Mechanistic in vitro studies were then conducted using isolated human neutrophils seeded directly onto HAV and ePTFE materials to analyze neutrophil viability, morphology, and function., Results: Clinical trial results showed that the HAV had a significantly lower (0.93%; P  = .0413) infection rate than that of ePTFE (4.54%). Histological analysis of sections from infected grafts explanted approximately 1 year after implantation revealed gram-positive bacteria near cannulation sites. Immunohistochemistry of HAV and ePTFE implanted in a well-controlled rodent infection model suggested that the ePTFE matrix permitted bacterial infiltration and colonization but may be inaccessible to neutrophils. In the same model, the HAV showed host recellularization and lacked detectable bacteria at the 2-week explant. In vitro results demonstrated that the viability of human neutrophils decreased significantly upon exposure to ePTFE, which was associated with neutrophil elastase release in the absence of bacteria. In contrast, neutrophils exposed to the HAV material retained high viability and native morphology. Cocultures of neutrophils and Staphylococcus aureus on the conduit materials demonstrated that neutrophils were more effective at ensnaring and degrading bacteria on the HAV than on ePTFE., Conclusions: The HAV material seems to demonstrate a resistance to bacterial infection. This infection resistance is likely due to the HAV's native-like material composition, which may be more biocompatible with host neutrophils than synthetic vascular graft material., (© 2023 by the Society for Vascular Surgery. Published by Elsevier Inc.)

Published

2023

10. Use of bioengineered human acellular vessels to treat traumatic injuries in the Ukraine-Russia conflict.

Author

Sokolov O, Shaprynskyi V, Skupyy O, Stanko O, Yurets S, Yurkova Y, and Niklason LE

Abstract

Competing Interests: LEN: LEN is the founder and CEO of Humacyte, has stock, is a Board member, and receives salary from Humacyte. LEN performed most of the writing of the first draft and the subsequent drafts of this Correspondence. LEN is the inventor on multiple patents that are either owned by Humacyte, or licensed by Humacyte, has an Officer and fiduciary role at Humacyte in her capacity as CEO, and has stock and options in Humacyte. YY: YY is an employee of Humacyte and has stock. VS: VS has no conflict of interest to disclose. OSk: OS has received honoraria from Bayer and Servier in the past 36 months; no conflict of interest for this manuscript. SY: SY has received honoraria from Bayer and Servier in the past 36 months; no conflict of interest for this manuscript. OSo: OSo has no conflict of interest to disclose. OSt: OSt has no conflict of interest to disclose.

Published

2023

11. Rational engineering of lung alveolar epithelium.

Author

Leiby KL, Yuan Y, Ng R, Raredon MSB, Adams TS, Baevova P, Greaney AM, Hirschi KK, Campbell SG, Kaminski N, Herzog EL, and Niklason LE

Abstract

Engineered whole lungs may one day expand therapeutic options for patients with end-stage lung disease. However, the feasibility of ex vivo lung regeneration remains limited by the inability to recapitulate mature, functional alveolar epithelium. Here, we modulate multimodal components of the alveolar epithelial type 2 cell (AEC2) niche in decellularized lung scaffolds in order to guide AEC2 behavior for epithelial regeneration. First, endothelial cells coordinate with fibroblasts, in the presence of soluble growth and maturation factors, to promote alveolar scaffold population with surfactant-secreting AEC2s. Subsequent withdrawal of Wnt and FGF agonism synergizes with tidal-magnitude mechanical strain to induce the differentiation of AEC2s to squamous type 1 AECs (AEC1s) in cultured alveoli, in situ. These results outline a rational strategy to engineer an epithelium of AEC2s and AEC1s contained within epithelial-mesenchymal-endothelial alveolar-like units, and highlight the critical interplay amongst cellular, biochemical, and mechanical niche cues within the reconstituting alveolus., (© 2023. The Author(s).)

Published

2023

12. SARS-CoV-2 leverages airway epithelial protective mechanism for viral infection.

Author

Greaney AM, Raredon MSB, Kochugaeva MP, Niklason LE, and Levchenko A

Abstract

Despite much concerted effort to better understand severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) viral infection, relatively little is known about the dynamics of early viral entry and infection in the airway. Here we analyzed a single-cell RNA sequencing dataset of early SARS-CoV-2 infection in a humanized in vitro model, to elucidate key mechanisms by which the virus triggers a cell-systems-level response in the bronchial epithelium. We find that SARS-CoV-2 virus preferentially enters the tissue via ciliated cell precursors, giving rise to a population of infected mature ciliated cells, which signal to basal cells, inducing further rapid differentiation. This feedforward loop of infection is mitigated by further cell-cell communication, before interferon signaling begins at three days post-infection. These findings suggest hijacking by the virus of potentially beneficial tissue repair mechanisms, possibly exacerbating the outcome. This work both elucidates the interplay between barrier tissues and viral infections and may suggest alternative therapeutic approaches targeting non-immune response mechanisms., Competing Interests: L.E.N. is the CEO, founder, and shareholder in Humacyte, Inc, which is a regenerative medicine company. Humacyte produces engineered blood vessels from allogeneic smooth muscle cells for vascular surgery. L.E.N.’s spouse has equity in Humacyte, and L.E.N. serves on Humacyte’s Board of Directors. L.E.N. is an inventor on patents that are licensed to Humacyte and that produce royalties for L.E.N. L.E.N. has received an unrestricted research gift to support research in her laboratory at Yale. Humacyte did not influence the conduct, description, or interpretation of the findings in this report., (© 2023 The Authors.)

Published

2023

13. Decellularization compromises mechanical and structural properties of the native trachea.

Author

Greaney AM, Ramachandra AB, Yuan Y, Korneva A, Humphrey JD, and Niklason LE

Abstract

Tracheal replacement using tissue engineering technologies offers great potential to improve previously intractable clinical interventions, and interest in this area has increased in recent years. Many engineered airway constructs currently rely on decellularized native tracheas to serve as the scaffold for tissue repair. Yet, mechanical failure leading to airway narrowing and collapse remains a major cause of morbidity and mortality following clinical implantation of decellularized tracheal grafts. To understand better the factors contributing to mechanical failure in vivo , we characterized the histo-mechanical properties of tracheas following two different decellularization protocols, including one that has been used clinically. All decellularized tracheas deviated from native mechanical behavior, which may provide insights into observed in vivo graft failures. We further analyzed protein content by western blot and analyzed microstructure by histological staining and found that the specific method of decellularization resulted in significant differences in the depletion of proteoglycans and degradation of collagens I, II, III, and elastin. Taken together, this work demonstrates that the heterogeneous architecture and mechanical behavior of the trachea is severely compromised by decellularization. Such structural deterioration may contribute to graft failure clinically and limit the potential of decellularized native tracheas as viable long-term orthotopic airway replacements., Competing Interests: L.E.N. is the CEO, founder and shareholder in Humacyte, Inc., a regenerative medicine company. Humacyte produces engineered blood vessels from allogeneic smooth muscle cells for vascular surgery. L.E.N.’s spouse has equity in Humacyte, and L.E.N. serves on Humacyte's Board of Directors. L.E.N. is an inventor on patents that are licensed to Humacyte and that produce royalties for L.E.N. L.E.N. has received an unrestricted research gift to support research in her laboratory at Yale. Humacyte did not influence the conduct, description or interpretation of the findings in this report., (© 2023 The Authors.)

Published

2023

14. Comprehensive visualization of cell-cell interactions in single-cell and spatial transcriptomics with NICHES.

Author

Raredon MSB, Yang J, Kothapalli N, Lewis W, Kaminski N, Niklason LE, and Kluger Y

Subjects

Ligands, Gene Expression Profiling, Cell Communication, Transcriptome, Software

Abstract

Motivation: Recent years have seen the release of several toolsets that reveal cell-cell interactions from single-cell data. However, all existing approaches leverage mean celltype gene expression values, and do not preserve the single-cell fidelity of the original data. Here, we present NICHES (Niche Interactions and Communication Heterogeneity in Extracellular Signaling), a tool to explore extracellular signaling at the truly single-cell level., Results: NICHES allows embedding of ligand-receptor signal proxies to visualize heterogeneous signaling archetypes within cell clusters, between cell clusters and across experimental conditions. When applied to spatial transcriptomic data, NICHES can be used to reflect local cellular microenvironment. NICHES can operate with any list of ligand-receptor signaling mechanisms, is compatible with existing single-cell packages, and allows rapid, flexible analysis of cell-cell signaling at single-cell resolution., Availability and Implementation: NICHES is an open-source software implemented in R under academic free license v3.0 and it is available at http://github.com/msraredon/NICHES. Use-case vignettes are available at https://msraredon.github.io/NICHES/., Supplementary Information: Supplementary data are available at Bioinformatics online., (© The Author(s) 2022. Published by Oxford University Press.)

Published

2023

15. Six-year outcomes of a phase II study of human-tissue engineered blood vessels for peripheral arterial bypass.

Author

Gutowski P, Guziewicz M, Ilzecki M, Kazimierczak A, Lawson JH, Prichard HL, Przywara S, Samad R, Tente W, Turek J, Witkiewicz W, Zapotoczny N, Zubilewicz T, and Niklason LE

Abstract

Objective: The human acellular vessel (HAV) was evaluated for surgical bypass in a phase II study. The primary results at 24 months after implantation have been reported, and the patients will be evaluated for ≤10 years., Methods: In the present report, we have described the 6-year results of a prospective, open-label, single-treatment arm, multicenter study. Patients with advanced peripheral artery disease (PAD) requiring above-the-knee femoropopliteal bypass surgery without available autologous graft options had undergone implantation with the HAV, a bioengineered human tissue replacement blood vessel. The patients who completed the 24-month primary portion of the study will be evaluated for ≤10 years after implantation. The present mid-term analysis was performed at the 6-year milestone (72 months) for patients followed up for 24 to 72 months., Results: HAVs were implanted in 20 patients at three sites in Poland. Seven patients had discontinued the study before completing the 2-year portion of the study: four after graft occlusion had occurred and three who had died of causes deemed unrelated to the conduit, with the HAV reported as functional at their last visit. The primary results at 24 months showed primary, primary assisted, and secondary patency rates of 58%, 58%, and 74%, respectively. One vessel had developed a pseudoaneurysm deemed possibly iatrogenic; no other signs of structural failure were reported. No rejections or infections of the HAV occurred, and no patient had required amputation of the implanted limb. Of the 20 patients, 13 had completed the primary portion of the study; however, 1 patient had died shortly after 24 months. Of the remaining 12 patients, 3 died of causes unrelated to the HAV. One patient had required thrombectomy twice, with secondary patency achieved. No other interventions were recorded between 24 and 72 months. At 72 months, five patients had a patent HAV, including four patients with primary patency. For the entire study population from day 1 to month 72, the overall primary, primary assisted, and secondary patency rate estimated using Kaplan-Meier analysis was 44%, 45%, and 60% respectively, with censoring for death. No patient had experienced rejection or infection of the HAV, and no patient had required amputation of the implanted limb., Conclusions: The infection-resistant, off-the-shelf HAV could provide a durable alternative conduit in the arterial circuit setting to restore the lower extremity blood supply in patients with PAD, with remodeling into the recipient's own vessel over time. The HAV is currently being evaluated in seven clinical trials to treat PAD, vascular trauma, and as a hemodialysis access conduit., (Copyright © 2023 Published by Elsevier Inc.)

Published

2022

16. Lung Tissue Engineering: Toward a More Deliberate Approach.

Author

Leiby KL and Niklason LE

Subjects

Lung, Stem Cells, Tissue Engineering, Tissue Scaffolds

Abstract

Chronic lung disease remains a leading cause of morbidity and mortality. Given the dearth of definitive therapeutic options, there is an urgent need to augment the pool of donor organs for transplantation. One strategy entails building a lung ex vivo in the laboratory. The past decade of whole lung tissue engineering has laid a foundation of systems and strategies for this approach. Meanwhile, tremendous progress in lung stem cell biology is elucidating cues contributing to alveolar repair, and speaks to the potential of whole lung regeneration in the future. This perspective discusses the key challenges facing the field and highlights opportunities to combine insights from biology with engineering strategies to adopt a more deliberate, and ultimately successful, approach to lung engineering.

Published

2022

17. Bioengineering Human Tissues and the Future of Vascular Replacement.

Author

Naegeli KM, Kural MH, Li Y, Wang J, Hugentobler EA, and Niklason LE

Subjects

Animals, Bioengineering, Biomedical Engineering, Blood Vessel Prosthesis, Humans, Cardiovascular System, Tissue Engineering

Abstract

Cardiovascular defects, injuries, and degenerative diseases often require surgical intervention and the use of implantable replacement material and conduits. Traditional vascular grafts made of synthetic polymers, animal and cadaveric tissues, or autologous vasculature have been utilized for almost a century with well-characterized outcomes, leaving areas of unmet need for the patients in terms of durability and long-term patency, susceptibility to infection, immunogenicity associated with the risk of rejection, and inflammation and mechanical failure. Research to address these limitations is exploring avenues as diverse as gene therapy, cell therapy, cell reprogramming, and bioengineering of human tissue and replacement organs. Tissue-engineered vascular conduits, either with viable autologous cells or decellularized, are the forefront of technology in cardiovascular reconstruction and offer many benefits over traditional graft materials, particularly in the potential for the implanted material to be adopted and remodeled into host tissue and thus offer safer, more durable performance. This review discusses the key advances and future directions in the field of surgical vascular repair, replacement, and reconstruction, with a focus on the challenges and expected benefits of bioengineering human tissues and blood vessels.

Published

2022

18. Pressure-Regulated Ventilator Splitting for Disaster Relief: Design, Testing, and Clinical Experience.

Author

Raredon MSB, Fisher C, Heerdt PM, Schonberger RB, Nargi A, Nivison S, Fajardo E, Deshpande R, Akhtar S, Greaney AM, Belter J, Raredon T, Zinter J, McKee A, Michalski M, Baevova P, and Niklason LE

Subjects

Humans, Positive-Pressure Respiration, Respiration, Artificial, Ventilators, Mechanical, COVID-19 therapy, Pandemics

Abstract

The coronavirus disease 2019 (COVID-19) pandemic has revealed that even the best-resourced hospitals may lack sufficient ventilators to support patients under surge conditions. During a pandemic or mass trauma, an affordable, low-maintenance, off-the-shelf device that would allow health care teams to rapidly expand their ventilator capacity could prove lifesaving, but only if it can be safely integrated into a complex and rapidly changing clinical environment. Here, we define an approach to safe ventilator sharing that prioritizes predictable and independent care of patients sharing a ventilator. Subsequently, we detail the design and testing of a ventilator-splitting circuit that follows this approach and describe our clinical experience with this circuit during the COVID-19 pandemic. This circuit was able to provide individualized and titratable ventilatory support with individualized positive end-expiratory pressure (PEEP) to 2 critically ill patients at the same time, while insulating each patient from changes in the other's condition. We share insights from our experience using this technology in the intensive care unit and outline recommendations for future clinical applications., Competing Interests: Conflicts of Interest: See Disclosures at the end of the article., (Copyright © 2021 International Anesthesia Research Society.)

Published

2022

19. Readily Available Tissue-Engineered Vascular Grafts Derived From Human Induced Pluripotent Stem Cells.

Author

Luo J, Qin L, Park J, Kural MH, Huang Y, Shi X, Riaz M, Wang J, Ellis MW, Anderson CW, Yuan Y, Ren Y, Yoder MC, Tellides G, Niklason LE, and Qyang Y

Subjects

Blood Vessel Prosthesis, Cell Differentiation, Humans, Tissue Engineering, Tissue Scaffolds, Induced Pluripotent Stem Cells

Published

2022

20. Computation and visualization of cell-cell signaling topologies in single-cell systems data using Connectome.

Author

Raredon MSB, Yang J, Garritano J, Wang M, Kushnir D, Schupp JC, Adams TS, Greaney AM, Leiby KL, Kaminski N, Kluger Y, Levchenko A, and Niklason LE

Subjects

Brain diagnostic imaging, Brain physiology, Ligands, RNA, Signal Transduction, Connectome

Abstract

Single-cell RNA-sequencing data has revolutionized our ability to understand of the patterns of cell-cell and ligand-receptor connectivity that influence the function of tissues and organs. However, the quantification and visualization of these patterns in a way that informs tissue biology are major computational and epistemological challenges. Here, we present Connectome, a software package for R which facilitates rapid calculation and interactive exploration of cell-cell signaling network topologies contained in single-cell RNA-sequencing data. Connectome can be used with any reference set of known ligand-receptor mechanisms. It has built-in functionality to facilitate differential and comparative connectomics, in which signaling networks are compared between tissue systems. Connectome focuses on computational and graphical tools designed to analyze and explore cell-cell connectivity patterns across disparate single-cell datasets and reveal biologic insight. We present approaches to quantify focused network topologies and discuss some of the biologic theory leading to their design., (© 2022. The Author(s).)

Published

2022

21. SARS-CoV-2 leverages airway epithelial protective mechanism for viral infection.

Author

Greaney AM, Raredon MSB, Kochugaeva MP, Niklason LE, and Levchenko A

Abstract

Despite much concerted effort to better understand SARS-CoV-2 viral infection, relatively little is known about the dynamics of early viral entry and infection in the airway. Here we analyzed a single-cell RNA sequencing dataset of early SARS-CoV-2 infection in a humanized in vitro model, to elucidate key mechanisms by which the virus triggers a cell-systems-level response in the bronchial epithelium. We find that SARS-CoV-2 virus preferentially enters the tissue via ciliated cell precursors, giving rise to a population of infected mature ciliated cells, which signal to basal cells, inducing further rapid differentiation. This feed-forward loop of infection is mitigated by further cell-cell communication, before interferon signaling begins at three days post-infection. These findings suggest hijacking by the virus of potentially beneficial tissue repair mechanisms, possibly exacerbating the outcome. This work both elucidates the interplay between barrier tissues and viral infections, and may suggest alternative therapeutic approaches targeting non-immune response mechanisms.

Published

2022

22. Characterization of the COPD alveolar niche using single-cell RNA sequencing.

Author

Sauler M, McDonough JE, Adams TS, Kothapalli N, Barnthaler T, Werder RB, Schupp JC, Nouws J, Robertson MJ, Coarfa C, Yang T, Chioccioli M, Omote N, Cosme C Jr, Poli S, Ayaub EA, Chu SG, Jensen KH, Gomez JL, Britto CJ, Raredon MSB, Niklason LE, Wilson AA, Timshel PN, Kaminski N, and Rosas IO

Subjects

A549 Cells, Alveolar Epithelial Cells classification, Animals, Cells, Cultured, Cluster Analysis, Epithelial Cells metabolism, Female, Gene Expression Profiling methods, Gene Regulatory Networks, Humans, Lung cytology, Male, Mice, Inbred C57BL, Mice, Transgenic, Pulmonary Disease, Chronic Obstructive pathology, Signal Transduction genetics, Mice, Alveolar Epithelial Cells metabolism, Lung metabolism, Pulmonary Disease, Chronic Obstructive genetics, RNA-Seq methods, Single-Cell Analysis methods

Abstract

Chronic obstructive pulmonary disease (COPD) is a leading cause of death worldwide, however our understanding of cell specific mechanisms underlying COPD pathobiology remains incomplete. Here, we analyze single-cell RNA sequencing profiles of explanted lung tissue from subjects with advanced COPD or control lungs, and we validate findings using single-cell RNA sequencing of lungs from mice exposed to 10 months of cigarette smoke, RNA sequencing of isolated human alveolar epithelial cells, functional in vitro models, and in situ hybridization and immunostaining of human lung tissue samples. We identify a subpopulation of alveolar epithelial type II cells with transcriptional evidence for aberrant cellular metabolism and reduced cellular stress tolerance in COPD. Using transcriptomic network analyses, we predict capillary endothelial cells are inflamed in COPD, particularly through increased CXCL-motif chemokine signaling. Finally, we detect a high-metallothionein expressing macrophage subpopulation enriched in advanced COPD. Collectively, these findings highlight cell-specific mechanisms involved in the pathobiology of advanced COPD., (© 2022. The Author(s).)

Published

2022

23. Single-cell multi-omics reveals dyssynchrony of the innate and adaptive immune system in progressive COVID-19.

Author

Unterman A, Sumida TS, Nouri N, Yan X, Zhao AY, Gasque V, Schupp JC, Asashima H, Liu Y, Cosme C Jr, Deng W, Chen M, Raredon MSB, Hoehn KB, Wang G, Wang Z, DeIuliis G, Ravindra NG, Li N, Castaldi C, Wong P, Fournier J, Bermejo S, Sharma L, Casanovas-Massana A, Vogels CBF, Wyllie AL, Grubaugh ND, Melillo A, Meng H, Stein Y, Minasyan M, Mohanty S, Ruff WE, Cohen I, Raddassi K, Niklason LE, Ko AI, Montgomery RR, Farhadian SF, Iwasaki A, Shaw AC, van Dijk D, Zhao H, Kleinstein SH, Hafler DA, Kaminski N, and Dela Cruz CS

Subjects

Adaptive Immunity drug effects, Adaptive Immunity genetics, Aged, Antibodies, Monoclonal, Humanized therapeutic use, CD4-Positive T-Lymphocytes drug effects, CD4-Positive T-Lymphocytes immunology, CD4-Positive T-Lymphocytes metabolism, CD8-Positive T-Lymphocytes drug effects, CD8-Positive T-Lymphocytes immunology, CD8-Positive T-Lymphocytes metabolism, COVID-19 genetics, Cells, Cultured, Female, Gene Expression Regulation drug effects, Gene Expression Regulation immunology, Humans, Immunity, Innate drug effects, Immunity, Innate genetics, Male, RNA-Seq methods, Receptors, Antigen, B-Cell genetics, Receptors, Antigen, B-Cell immunology, Receptors, Antigen, T-Cell genetics, Receptors, Antigen, T-Cell immunology, SARS-CoV-2 drug effects, SARS-CoV-2 physiology, COVID-19 Drug Treatment, Adaptive Immunity immunology, COVID-19 immunology, Gene Expression Profiling methods, Immunity, Innate immunology, SARS-CoV-2 immunology, Single-Cell Analysis methods

Abstract

Dysregulated immune responses against the SARS-CoV-2 virus are instrumental in severe COVID-19. However, the immune signatures associated with immunopathology are poorly understood. Here we use multi-omics single-cell analysis to probe the dynamic immune responses in hospitalized patients with stable or progressive course of COVID-19, explore V(D)J repertoires, and assess the cellular effects of tocilizumab. Coordinated profiling of gene expression and cell lineage protein markers shows that S100A hi /HLA-DR lo classical monocytes and activated LAG-3 hi T cells are hallmarks of progressive disease and highlights the abnormal MHC-II/LAG-3 interaction on myeloid and T cells, respectively. We also find skewed T cell receptor repertories in expanded effector CD8 + clones, unmutated IGHG + B cell clones, and mutated B cell clones with stable somatic hypermutation frequency over time. In conclusion, our in-depth immune profiling reveals dyssynchrony of the innate and adaptive immune interaction in progressive COVID-19., (© 2022. The Author(s).)

Published

2022

24. Engineered Lung Tissues Prepared from Decellularized Lung Slices.

Author

Leiby KL, Ng R, Campbell SG, and Niklason LE

Subjects

Animals, Extracellular Matrix chemistry, Lung, Mice, Pulmonary Alveoli, Rats, Endothelial Cells, Tissue Scaffolds chemistry

Abstract

There is a need for improved 3-dimensional (3D) lung models that recapitulate the architectural and cellular complexity of the native lung alveolus ex vivo. Recently developed organoid models have facilitated the expansion and study of lung epithelial progenitors in vitro, but these platforms typically rely on mouse tumor-derived matrix and/or serum, and incorporate just one or two cellular lineages. Here, we describe a protocol for generating engineered lung tissues (ELTs) based on the multi-lineage recellularization of decellularized precision-cut lung slices (PCLS). ELTs contain alveolar-like structures comprising alveolar epithelium, mesenchyme, and endothelium, within an extracellular matrix (ECM) substrate closely resembling that of native lung. To generate the tissues, rat lungs are inflated with agarose, sliced into 450 µm-thick slices, cut into strips, and decellularized. The resulting acellular ECM scaffolds are then reseeded with primary endothelial cells, fibroblasts, and alveolar epithelial type 2 cells (AEC2s). AEC2s can be maintained in ELT culture for at least 7 days with a serum-free, chemically-defined growth medium. Throughout the tissue preparation and culture process, the slices are clipped into a cassette system that facilitates handling and standardized cell seeding of multiple ELTs in parallel. These ELTs represent an organotypic culture platform that should facilitate investigations of cell-cell and cell-matrix interactions within the alveolus as well as biochemical signals regulating AEC2s and their niche.

Published

2022

25. Expression of the transcription factor PU.1 induces the generation of microglia-like cells in human cortical organoids.

Author

Cakir B, Tanaka Y, Kiral FR, Xiang Y, Dagliyan O, Wang J, Lee M, Greaney AM, Yang WS, duBoulay C, Kural MH, Patterson B, Zhong M, Kim J, Bai Y, Min W, Niklason LE, Patra P, and Park IH

Subjects

Alzheimer Disease genetics, Alzheimer Disease pathology, Amyloid beta-Peptides toxicity, Animals, CRISPR-Cas Systems genetics, Cell Lineage drug effects, Cells, Cultured, Green Fluorescent Proteins metabolism, Human Embryonic Stem Cells metabolism, Human Embryonic Stem Cells ultrastructure, Humans, Mice, Microglia drug effects, Microglia ultrastructure, Organoids metabolism, Phagocytosis drug effects, Single-Cell Analysis, Cerebral Cortex metabolism, Microglia metabolism, Organoids cytology, Proto-Oncogene Proteins metabolism, Trans-Activators metabolism

Abstract

Microglia play a role in the emergence and preservation of a healthy brain microenvironment. Dysfunction of microglia has been associated with neurodevelopmental and neurodegenerative disorders. Investigating the function of human microglia in health and disease has been challenging due to the limited models of the human brain available. Here, we develop a method to generate functional microglia in human cortical organoids (hCOs) from human embryonic stem cells (hESCs). We apply this system to study the role of microglia during inflammation induced by amyloid-β (Aβ). The overexpression of the myeloid-specific transcription factor PU.1 generates microglia-like cells in hCOs, producing mhCOs (microglia-containing hCOs), that we engraft in the mouse brain. Single-cell transcriptomics reveals that mhCOs acquire a microglia cell cluster with an intact complement and chemokine system. Functionally, microglia in mhCOs protect parenchyma from cellular and molecular damage caused by Aβ. Furthermore, in mhCOs, we observed reduced expression of Aβ-induced expression of genes associated with apoptosis, ferroptosis, and Alzheimer's disease (AD) stage III. Finally, we assess the function of AD-associated genes highly expressed in microglia in response to Aβ using pooled CRISPRi coupled with single-cell RNA sequencing in mhCOs. In summary, we provide a protocol to generate mhCOs that can be used in fundamental and translational studies as a model to investigate the role of microglia in neurodevelopmental and neurodegenerative disorders., (© 2022. The Author(s).)

Published

2022

26. Five Year Outcomes in Patients with End Stage Renal Disease Who Received a Bioengineered Human Acellular Vessel for Dialysis Access.

Author

Jakimowicz T, Przywara S, Turek J, Pilgrim A, Macech M, Zapotoczny N, Zubilewicz T, Lawson JH, and Niklason LE

Abstract

Objective: Patients with end stage renal failure who require haemodialysis suffer morbidity and mortality due to vascular access. Bioengineered human acellular vessels (HAVs) may provide a haemodialysis access option with fewer complications than other grafts. In a prospective phase II trial from 2012 to 2014 (NCT01744418), HAVs were implanted into 40 haemodialysis patients at three sites in Poland. The trial protocol for this "first in man" use of the HAV contemplated only two years of follow up, and the trial results were initially reported in 2016. In light of the retained HAV function seen in many of the patients at the two year time point, follow up for patients who were still alive was extended to a total of 10 years. This interim follow up report, at the long term time point of five years, assessed patient and conduit status in those who continued routine dialysis with the HAV., Methods: HAVs are bioengineered by culturing human vascular smooth muscle cells on a biodegradable polymer matrix. In this study, patients with patent HAV implants at 24 months were followed every three months, starting at month 27 through to month 60, or at least five years post-implantation. This report contains the follow up functional and histological data on 29 of the original 40 patients who demonstrated HAV function at the 24 month time point., Results: Eleven patients completed at month 60. One patient maintained primary patency, and 10 maintained secondary patency. Secondary patency was estimated at 58.2% (95% confidence interval 39.2-73.1) at five years, after censoring for deaths ( n  = 8) and withdrawals ( n  = 1). No HAV conduit infections were reported during the follow up period., Conclusion: This phase II long term follow up shows that the human acellular vessel (HAV) may provide durable and functional haemodialysis access for patients with end stage renal disease., (© 2022 The Authors.)

Published

2022

27. A Pulmonary Vascular Model From Endothelialized Whole Organ Scaffolds.

Author

Yuan Y, Leiby KL, Greaney AM, Raredon MSB, Qian H, Schupp JC, Engler AJ, Baevova P, Adams TS, Kural MH, Wang J, Obata T, Yoder MC, Kaminski N, and Niklason LE

Abstract

The development of an in vitro system for the study of lung vascular disease is critical to understanding human pathologies. Conventional culture systems fail to fully recapitulate native microenvironmental conditions and are typically limited in their ability to represent human pathophysiology for the study of disease and drug mechanisms. Whole organ decellularization provides a means to developing a construct that recapitulates structural, mechanical, and biological features of a complete vascular structure. Here, we developed a culture protocol to improve endothelial cell coverage in whole lung scaffolds and used single-cell RNA-sequencing analysis to explore the impact of decellularized whole lung scaffolds on endothelial phenotypes and functions in a biomimetic bioreactor system. Intriguingly, we found that the phenotype and functional signals of primary pulmonary microvascular revert back-at least partially-toward native lung endothelium. Additionally, human induced pluripotent stem cell-derived endothelium cultured in decellularized lung systems start to gain various native human endothelial phenotypes. Vascular barrier function was partially restored, while small capillaries remained patent in endothelial cell-repopulated lungs. To evaluate the ability of the engineered endothelium to modulate permeability in response to exogenous stimuli, lipopolysaccharide (LPS) was introduced into repopulated lungs to simulate acute lung injury. After LPS treatment, proinflammatory signals were significantly increased and the vascular barrier was impaired. Taken together, these results demonstrate a novel platform that recapitulates some pulmonary microvascular functions and phenotypes at a whole organ level. This development may help pave the way for using the whole organ engineering approach to model vascular diseases., Competing Interests: LEN is a founder and shareholder in Humacyte, Inc. The remaining authors declare that the research was conducted in the Q14 absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2021 Yuan, Leiby, Greaney, Raredon, Qian, Schupp, Engler, Baevova, Adams, Kural, Wang, Obata, Yoder, Kaminski and Niklason.)

Published

2021

28. Microvascular fluid flow in ex vivo and engineered lungs.

Author

Raredon MSB, Engler AJ, Yuan Y, Greaney AM, and Niklason LE

Subjects

Capillaries, Perfusion, Lung, Microvessels

Abstract

In recent years, it has become common to experiment with ex vivo perfused lungs for organ transplantation and to attempt regenerative pulmonary engineering using decellularized lung matrices. However, our understanding of the physiology of ex vivo organ perfusion is imperfect; it is not currently well understood how decreasing microvascular barrier affects the perfusion of pulmonary parenchyma. In addition, protocols for lung perfusion and organ culture fluid-handling are far from standardized, with widespread variation on both basic methods and on ideally controlled parameters. To address both of these deficits, a robust, noninvasive, and mechanistic model is needed which is able to predict microvascular resistance and permeability in perfused lungs while providing insight into capillary recruitment. Although validated mathematical models exist for fluid flow in native pulmonary tissue, previous models generally assume minimal intravascular leak from artery to vein and do not assess capillary bed recruitment. Such models are difficult to apply to both ex vivo lung perfusions, in which edema can develop over time and microvessels can become blocked, and to decellularized ex vivo organomimetic cultures, in which microvascular recruitment is variable and arterially perfused fluid enters into the alveolar space. Here, we develop a mathematical model of pulmonary microvascular fluid flow which is applicable in both instances, and we apply our model to data from native, decellularized, and regenerating lungs under ex vivo perfusion. The results provide substantial insight into microvascular pressure-flow mechanics, while producing previously unknown output values for tissue-specific capillary-alveolar hydraulic conductivity, microvascular recruitment, and total organ barrier resistance. NEW & NOTEWORTHY We present a validated model of pulmonary microvascular fluid mechanics and apply this model to study the effects of increased capillary permeability in decellularized and regenerating lungs. We find that decellularization alters microvascular steady-state mechanics and that re-endothelialization partially rescues key biologic parameters. The described model provides powerful insight into intraorgan microvascular dynamics and may be used to guide regenerative engineering experiments. We include all data and derivations necessary to replicate this work.

Published

2021

29. An ex vivo physiologic and hyperplastic vessel culture model to study intra-arterial stent therapies.

Author

Wang J, Kural MH, Wu J, Leiby KL, Mishra V, Lysyy T, Li G, Luo J, Greaney A, Tellides G, Qyang Y, Huang N, and Niklason LE

Subjects

Absorbable Implants, Animals, Hyperplasia pathology, Rabbits, Swine, Tunica Intima pathology, Coronary Vessels, Stents

Abstract

Conventional in vitro methods for biological evaluation of intra-arterial devices such as stents fail to accurately predict cytotoxicity and remodeling events. An ex vivo flow-tunable vascular bioreactor system (VesselBRx), comprising intra- and extra-luminal monitoring capabilities, addresses these limitations. VesselBRx mimics the in vivo physiological, hyperplastic, and cytocompatibility events of absorbable magnesium (Mg)-based stents in ex vivo stent-treated porcine and human coronary arteries, with in-situ and real-time monitoring of local stent degradation effects. Unlike conventional, static cell culture, the VesselBRx perfusion system eliminates unphysiologically high intracellular Mg 2+ concentrations and localized O 2 consumption resulting from stent degradation. Whereas static stented arteries exhibited only 20.1% cell viability and upregulated apoptosis, necrosis, metallic ion, and hypoxia-related gene signatures, stented arteries in VesselBRx showed almost identical cell viability to in vivo rabbit models (~94.0%). Hyperplastic intimal remodeling developed in unstented arteries subjected to low shear stress, but was inhibited by Mg-based stents in VesselBRx, similarly to in vivo. VesselBRx represents a critical advance from the current static culture standard of testing absorbable vascular implants., (Copyright © 2021 Elsevier Ltd. All rights reserved.)

Published

2021

30. The History of Engineered Tracheal Replacements: Interpreting the Past and Guiding the Future.

Author

Greaney AM and Niklason LE

Subjects

Humans, Tissue Scaffolds, Tissue Engineering, Trachea

Abstract

The development of a tracheal graft to replace long-segment defects has thwarted clinicians and engineers alike for over 100 years. To better understand the challenges facing this field today, we have consolidated all published reports of engineered tracheal grafts used to repair long-segment circumferential defects in humans, from the first in 1898 to the most recent in 2018, totaling 290 clinical cases. Distinct trends emerge in the types of grafts used over time, including repair using autologous fascia, rigid tubes of various inert materials, and pretreated cadaveric allografts. Our analysis of maximum clinical follow-up, as a proxy for graft performance, revealed that the Leuven protocol has a significantly longer clinical follow-up time than all other methods of airway reconstruction. This method involves transplanting a cadaveric tracheal allograft that is first prevascularized heterotopically in the recipient. We further quantified graft-related causes of mortality, revealing failure modes that have been resolved, and those that remain a hurdle, such as graft mechanics. Finally, we briefly summarize recent preclinical work in tracheal graft development. In conclusion, we synthesized top clinical care priorities and design criteria to inform and inspire collaboration between engineers and clinicians toward the development of a functional tracheal replacement graft. Impact statement The field of tracheal engineering has floundered in recent years due to multiple article retractions. However, with recent advances in biofabrication and tissue analysis techniques, the field remains ripe for advancement through collaboration between engineers and clinicians. With a long history of clinical application of tracheal replacements, engineered tracheas are arguably the regenerative technology with the greatest potential for translation. This work describes the many phases of engineered tracheal replacements that have been applied in human patients over the past 100 years with the goal of carrying forward critical lessons into development of the next generation of engineered tracheal graft.

Published

2021

31. Critical Considerations for Regeneration of Vascularized Composite Tissues.

Author

Shah Mohammadi M, Buchen JT, Pasquina PF, Niklason LE, Alvarez LM, and Jariwala SH

Subjects

Forecasting, Humans, Printing, Three-Dimensional, Regeneration, Tissue Engineering, Tissue Scaffolds, Bioprinting, Endothelial Cells

Abstract

Effective vascularization is vital for survival and functionality of complex tissue-engineered organs. The formation of the microvasculature, composed of endothelial cells (ECs) alone, has been mostly used to restore the vascular networks in organs. However, recent heterocellular studies demonstrate that co-culturing is a more effective approach in revascularization of engineered organs. This review presents key considerations for manufacturing of artificial vascularized composite tissues. We summarize the importance of co-cultures and the multicellular interactions with ECs, as well as design and use of bioreactors, as critical considerations for tissue vascularization. In addition, as an emerging scaffolding technique, this review also highlights the current caveats and hurdles associated with three-dimensional bioprinting and discusses recent developments in bioprinting strategies such as four-dimensional bioprinting and its future outlook for manufacturing of vascularized tissue constructs. Finally, the review concludes with addressing the critical challenges in the regulatory pathway and clinical translation of artificial composite tissue grafts. Impact statement Regeneration of composite tissues is critical as biophysical and biochemical characteristics differ between various types of tissues. Engineering a vascularized composite tissue has remained unresolved and requires additional evaluations along with optimization of methodologies and standard operating procedures. To this end, the main hurdle is creating a viable vascular endothelium that remains functional for a longer duration postimplantation, and can be manufactured using clinically appropriate source of cell lines that are scalable in vitro for the fabrication of human-scale organs. This review presents key considerations for regeneration and manufacturing of vascularized composite tissues as the field advances.

Published

2021

32. A therapeutic vascular conduit to support in vivo cell-secreted therapy.

Author

Han EX, Qian H, Jiang B, Figetakis M, Kosyakova N, Tellides G, Niklason LE, and Chang WG

Abstract

A significant barrier to implementation of cell-based therapies is providing adequate vascularization to provide oxygen and nutrients. Here we describe an approach for cell transplantation termed the Therapeutic Vascular Conduit (TVC), which uses an acellular vessel as a scaffold for a hydrogel sheath containing cells designed to secrete a therapeutic protein. The TVC can be directly anastomosed as a vascular graft. Modeling supports the concept that the TVC allows oxygenated blood to flow in close proximity to the transplanted cells to prevent hypoxia. As a proof-of-principle study, we used erythropoietin (EPO) as a model therapeutic protein. If implanted as an arteriovenous vascular graft, such a construct could serve a dual role as an EPO delivery platform and hemodialysis access for patients with end-stage renal disease. When implanted into nude rats, TVCs containing EPO-secreting fibroblasts were able to increase serum EPO and hemoglobin levels for up to 4 weeks. However, constitutive EPO expression resulted in macrophage infiltration and luminal obstruction of the TVC, thus limiting longer-term efficacy. Follow-up in vitro studies support the hypothesis that EPO also functions to recruit macrophages. The TVC is a promising approach to cell-based therapeutic delivery that has the potential to overcome the oxygenation barrier to large-scale cellular implantation and could thus be used for a myriad of clinical disorders. However, a complete understanding of the biological effects of the selected therapeutic is absolutely essential., (© 2021. The Author(s).)

Published

2021

33. Integrated Single-Cell Atlas of Endothelial Cells of the Human Lung.

Author

Schupp JC, Adams TS, Cosme C Jr, Raredon MSB, Yuan Y, Omote N, Poli S, Chioccioli M, Rose KA, Manning EP, Sauler M, DeIuliis G, Ahangari F, Neumark N, Habermann AC, Gutierrez AJ, Bui LT, Lafyatis R, Pierce RW, Meyer KB, Nawijn MC, Teichmann SA, Banovich NE, Kropski JA, Niklason LE, Pe'er D, Yan X, Homer RJ, Rosas IO, and Kaminski N

Subjects

Capillaries, Computational Biology methods, Databases, Genetic, Disease Susceptibility, Gene Expression Profiling, High-Throughput Nucleotide Sequencing, Humans, Lung blood supply, Lung cytology, Microcirculation, Organ Specificity, Pulmonary Artery, Pulmonary Veins, Transcriptome, Biomarkers, Endothelial Cells metabolism, Lung metabolism, Single-Cell Analysis methods

Abstract

Background: Cellular diversity of the lung endothelium has not been systematically characterized in humans. We provide a reference atlas of human lung endothelial cells (ECs) to facilitate a better understanding of the phenotypic diversity and composition of cells comprising the lung endothelium., Methods: We reprocessed human control single-cell RNA sequencing (scRNAseq) data from 6 datasets. EC populations were characterized through iterative clustering with subsequent differential expression analysis. Marker genes were validated by fluorescent microscopy and in situ hybridization. scRNAseq of primary lung ECs cultured in vitro was performed. The signaling network between different lung cell types was studied. For cross-species analysis or disease relevance, we applied the same methods to scRNAseq data obtained from mouse lungs or from human lungs with pulmonary hypertension., Results: Six lung scRNAseq datasets were reanalyzed and annotated to identify >15 000 vascular EC cells from 73 individuals. Differential expression analysis of EC revealed signatures corresponding to endothelial lineage, including panendothelial, panvascular, and subpopulation-specific marker gene sets. Beyond the broad cellular categories of lymphatic, capillary, arterial, and venous ECs, we found previously indistinguishable subpopulations; among venous EC, we identified 2 previously indistinguishable populations: pulmonary-venous ECs (COL15A1 neg ) localized to the lung parenchyma and systemic-venous ECs (COL15A1 pos ) localized to the airways and the visceral pleura; among capillary ECs, we confirmed their subclassification into recently discovered aerocytes characterized by EDNRB , SOSTDC1 , and TBX2 and general capillary EC. We confirmed that all 6 endothelial cell types, including the systemic-venous ECs and aerocytes, are present in mice and identified endothelial marker genes conserved in humans and mice. Ligand-receptor connectome analysis revealed important homeostatic crosstalk of EC with other lung resident cell types. scRNAseq of commercially available primary lung ECs demonstrated a loss of their native lung phenotype in culture. scRNAseq revealed that endothelial diversity is maintained in pulmonary hypertension. Our article is accompanied by an online data mining tool (www.LungEndothelialCellAtlas.com)., Conclusions: Our integrated analysis provides a comprehensive and well-crafted reference atlas of ECs in the normal lung and confirms and describes in detail previously unrecognized endothelial populations across a large number of humans and mice.

Published

2021

34. Development of a Bioartificial Vascular Pancreas.

Author

Han EX, Wang J, Kural M, Jiang B, Leiby KL, Chowdhury N, Tellides G, Kibbey RG, Lawson JH, and Niklason LE

Abstract

Transplantation of pancreatic islets has been shown to be effective, in some patients, for the long-term treatment of type 1 diabetes. However, transplantation of islets into either the portal vein or the subcutaneous space can be limited by insufficient oxygen transfer, leading to islet loss. Furthermore, oxygen diffusion limitations can be magnified when islet numbers are increased dramatically, as in translating from rodent studies to human-scale treatments. To address these limitations, an islet transplantation approach using an acellular vascular graft as a vascular scaffold has been developed, termed the BioVascular Pancreas (BVP). To create the BVP, islets are seeded as an outer coating on the surface of an acellular vascular graft, using fibrin as a hydrogel carrier. The BVP can then be anastomosed as an arterial (or arteriovenous) graft, which allows fully oxygenated arterial blood with a pO 2 of roughly 100 mmHg to flow through the graft lumen and thereby supply oxygen to the islets. In silico simulations and in vitro bioreactor experiments show that the BVP design provides adequate survivability for islets and helps avoid islet hypoxia. When implanted as end-to-end abdominal aorta grafts in nude rats, BVPs were able to restore near-normoglycemia durably for 90 days and developed robust microvascular infiltration from the host. Furthermore, pilot implantations in pigs were performed, which demonstrated the scalability of the technology. Given the potential benefits provided by the BVP, this tissue design may eventually serve as a solution for transplantation of pancreatic islets to treat or cure type 1 diabetes., Competing Interests: Declaration of conflicting interests: The author(s) declared the following potential conflicts of interest with respect to the research, authorship, and/or publication of this article: L.E.N. is a founder and shareholder in Humacyte, Inc., which is a regenerative medicine company. J.H.L is a shareholder in Humacyte Inc. Humacyte produces engineered blood vessels from allogeneic smooth muscle cells for vascular surgery. L.E.N.’s spouse has equity in Humacyte, and L.E.N. and J.H.L serve on Humacyte’s Board of Directors. L.E.N. and J.H.L are inventors on patents that are licensed to Humacyte and that produce royalties for L.E.N. and J.H.L. L.E.N. has received an unrestricted research gift to support research in her laboratory at Yale. Humacyte did not influence the description or interpretation of the findings in this report. The other authors report no conflicts., (© The Author(s) 2021.)

Published

2021

35. Single-cell longitudinal analysis of SARS-CoV-2 infection in human airway epithelium identifies target cells, alterations in gene expression, and cell state changes.

Author

Ravindra NG, Alfajaro MM, Gasque V, Huston NC, Wan H, Szigeti-Buck K, Yasumoto Y, Greaney AM, Habet V, Chow RD, Chen JS, Wei J, Filler RB, Wang B, Wang G, Niklason LE, Montgomery RR, Eisenbarth SC, Chen S, Williams A, Iwasaki A, Horvath TL, Foxman EF, Pierce RW, Pyle AM, van Dijk D, and Wilen CB

Subjects

Adult, Bronchi virology, COVID-19 immunology, COVID-19 pathology, COVID-19 virology, Cells, Cultured, Epithelium pathology, Epithelium virology, Humans, Immunity, Innate, Longitudinal Studies, SARS-CoV-2 genetics, Transcriptome, Viral Tropism, Bronchi pathology, COVID-19 diagnosis, Gene Expression, SARS-CoV-2 isolation & purification, Single-Cell Analysis methods

Abstract

There are currently limited Food and Drug Administration (FDA)-approved drugs and vaccines for the treatment or prevention of Coronavirus Disease 2019 (COVID-19). Enhanced understanding of Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2) infection and pathogenesis is critical for the development of therapeutics. To provide insight into viral replication, cell tropism, and host-viral interactions of SARS-CoV-2, we performed single-cell (sc) RNA sequencing (RNA-seq) of experimentally infected human bronchial epithelial cells (HBECs) in air-liquid interface (ALI) cultures over a time course. This revealed novel polyadenylated viral transcripts and highlighted ciliated cells as a major target at the onset of infection, which we confirmed by electron and immunofluorescence microscopy. Over the course of infection, the cell tropism of SARS-CoV-2 expands to other epithelial cell types including basal and club cells. Infection induces cell-intrinsic expression of type I and type III interferons (IFNs) and interleukin (IL)-6 but not IL-1. This results in expression of interferon-stimulated genes (ISGs) in both infected and bystander cells. This provides a detailed characterization of genes, cell types, and cell state changes associated with SARS-CoV-2 infection in the human airway., Competing Interests: Yale University (CBW) has a patent pending related to this work entitled: “Compounds and Compositions for Treating, Ameliorating, and/or Preventing SARS-CoV-2 Infection and/or Complications Thereof.” Yale University has committed to rapidly executable non-exclusive royalty-free licenses to intellectual property rights for the purpose of making and distributing products to prevent, diagnose and treat COVID-19 infection during the pandemic and for a short period thereafter.

Published

2021

36. Xenogeneic-free generation of vascular smooth muscle cells from human induced pluripotent stem cells for vascular tissue engineering.

Author

Luo J, Lin Y, Shi X, Li G, Kural MH, Anderson CW, Ellis MW, Riaz M, Tellides G, Niklason LE, and Qyang Y

Subjects

Animals, Cell Differentiation, Humans, Mice, Muscle, Smooth, Vascular, Myocytes, Smooth Muscle, Tissue Engineering, Induced Pluripotent Stem Cells

Abstract

Development of mechanically advanced tissue-engineered vascular grafts (TEVGs) from human induced pluripotent stem cell (hiPSC)-derived vascular smooth muscle cells (hiPSC-VSMCs) offers an innovative approach to replace or bypass diseased blood vessels. To move current hiPSC-TEVGs toward clinical application, it is essential to obtain hiPSC-VSMC-derived tissues under xenogeneic-free conditions, meaning without the use of any animal-derived reagents. Many approaches in VSMC differentiation of hiPSCs have been reported, although a xenogeneic-free method for generating hiPSC-VSMCs suitable for vascular tissue engineering has yet to be established. Based on our previously established standard method of xenogeneic VSMC differentiation, we have replaced all animal-derived reagents with functional counterparts of human origin and successfully derived functional xenogeneic-free hiPSC-VSMCs (XF-hiPSC-VSMCs). Next, our group developed tissue rings via cellular self-assembly from XF-hiPSC-VSMCs, which exhibited comparable mechanical strength to those developed from xenogeneic hiPSC-VSMCs. Moreover, by seeding XF-hiPSC-VSMCs onto biodegradable polyglycolic acid (PGA) scaffolds, we generated engineered vascular tissues presenting effective collagen deposition which were suitable for implantation into an immunodeficient mice model. In conclusion, our xenogeneic-free conditions for generating hiPSC-VSMCs produce cells with the comparable capacity for vascular tissue engineering as standard xenogeneic protocols, thereby moving the hiPSC-TEVG technology one step closer to safe and efficacious clinical translation., Competing Interests: Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2020 Acta Materialia Inc. Published by Elsevier Ltd. All rights reserved.)

Published

2021

37. Efficient Differentiation of Human Induced Pluripotent Stem Cells into Endothelial Cells under Xenogeneic-free Conditions for Vascular Tissue Engineering.

Author

Luo J, Shi X, Lin Y, Yuan Y, Kural MH, Wang J, Ellis MW, Anderson CW, Zhang SM, Riaz M, Niklason LE, and Qyang Y

Subjects

Animals, Blood Vessel Prosthesis, Cell Differentiation, Endothelial Cells, Humans, Tissue Engineering, Induced Pluripotent Stem Cells

Abstract

Tissue engineered vascular grafts (TEVGs) represent a promising therapeutic option for emergency vascular intervention. Although the application of small-diameter TEVGs using patient-specific primary endothelial cells (ECs) to prevent thrombosis and occlusion prior to implantation could be hindered by the long time course required for in vitro endothelialization, human induced pluripotent stem cells (hiPSCs) provide a robust source to derive immunocompatible ECs (hiPSC-ECs) for immediate TEVG endothelialization. To achieve clinical application, hiPSC-ECs should be derived under culture conditions without the use of animal-derived reagents (xenogeneic-free conditions), to avoid unwanted host immune responses from xenogeneic reagents. However, a completely xenogeneic-free method of hiPSC-EC generation has not previously been established. Herein, we substituted animal-derived reagents used in a standard method of xenogeneic hiPSC-EC differentiation with functional counterparts of human origin. As a result, we generated xenogeneic-free hiPSC-ECs (XF-hiPSC-ECs) with similar marker expression and function to those of human primary ECs. Furthermore, XF-hiPSC-ECs functionally responded to shear stress with typical cell alignment and gene expression. Finally, we successfully endothelialized decellularized human vessels with XF-hiPSC-ECs in a dynamic bioreactor system. In conclusion, we developed xenogeneic-free conditions for generating functional hiPSC-ECs suitable for vascular tissue engineering, which will further move TEVG therapy toward clinical application., Competing Interests: Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2020. Published by Elsevier Ltd.)

Published

2021

38. Bioengineered human blood vessels.

Author

Niklason LE and Lawson JH

Subjects

Cell Culture Techniques, Humans, Arteries, Blood Vessel Prosthesis, Tissue Engineering methods, Vascular Diseases surgery

Abstract

Since the advent of the vascular anastomosis by Alexis Carrel in the early 20th century, the repair and replacement of blood vessels have been key to treating acute injuries, as well as chronic atherosclerotic disease. Arteries serve diverse mechanical and biological functions, such as conducting blood to tissues, interacting with the coagulation system, and modulating resistance to blood flow. Early approaches for arterial replacement used artificial materials, which were supplanted by polymer fabrics in recent decades. With recent advances in the engineering of connective tissues, including arteries, we are on the cusp of seeing engineered human arteries become mainstays of surgical therapy for vascular disease. Progress in our understanding of physiology, cell biology, and biomanufacturing over the past several decades has made these advances possible., (Copyright © 2020 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works.)

Published

2020

39. Challenges and novel therapies for vascular access in haemodialysis.

Author

Lawson JH, Niklason LE, and Roy-Chaudhury P

Subjects

Central Venous Catheters adverse effects, Humans, Renal Dialysis instrumentation, Inventions, Renal Dialysis methods, Vascular Access Devices adverse effects

Abstract

Advances in standards of care have extended the life expectancy of patients with kidney failure. However, options for chronic vascular access for haemodialysis - an essential part of kidney replacement therapy - have remained unchanged for decades. The high morbidity and mortality associated with current vascular access complications highlights an unmet clinical need for novel techniques in vascular access and is driving innovation in vascular access care. The development of devices, biological approaches and novel access techniques has led to new approaches to controlling fistula geometry and manipulating the underlying cellular and molecular pathways of the vascular endothelium, and influencing fistula maturation and formation through the use of external mechanical methods. Innovations in arteriovenous graft materials range from small modifications to the graft lumen to the creation of completely novel bioengineered grafts. Steps have even been taken to create new devices for the treatment of patients with central vein stenosis. However, these emerging therapies face difficult hurdles, and truly creative approaches to vascular access need resources that include well-designed clinical trials, frequent interaction with regulators, interventionalist education and sufficient funding. In addition, the heterogeneity of patients with kidney failure suggests it is unlikely that a 'one-size-fits-all' approach for effective vascular access will be feasible in the current environment.

Published

2020

40. Arterial reconstruction with human bioengineered acellular blood vessels in patients with peripheral arterial disease.

Author

Gutowski P, Gage SM, Guziewicz M, Ilzecki M, Kazimierczak A, Kirkton RD, Niklason LE, Pilgrim A, Prichard HL, Przywara S, Samad R, Tente B, Turek J, Witkiewicz W, Zapotoczny N, Zubilewicz T, and Lawson JH

Subjects

Aged, Bioengineering, Bioreactors, Female, Femoral Artery surgery, Follow-Up Studies, Humans, Intermittent Claudication etiology, Male, Middle Aged, Myocytes, Smooth Muscle physiology, Peripheral Arterial Disease complications, Popliteal Artery surgery, Prospective Studies, Treatment Outcome, Vascular Patency, Vascular Remodeling, Blood Vessel Prosthesis, Blood Vessel Prosthesis Implantation instrumentation, Intermittent Claudication surgery, Peripheral Arterial Disease surgery, Tissue Scaffolds

Abstract

Objective: Vascular conduit is essential for arterial reconstruction for a number of conditions, including trauma and atherosclerotic occlusive disease. We have developed a tissue-engineered human acellular vessel (HAV) that can be manufactured, stored on site at hospitals, and be immediately available for arterial vascular reconstruction. Although the HAV is acellular when implanted, extensive preclinical and clinical testing has demonstrated that the HAV subsequently repopulates with the recipient's own vascular cells. We report a first-in-man clinical experience using the HAV for arterial reconstruction in patients with symptomatic peripheral arterial disease., Methods: HAVs were manufactured using human vascular smooth muscle cells grown on a biodegradable scaffold. After the establishment of adequate cell growth and extracellular matrix deposition, the vessels were decellularized to remove human cellular antigens. Manufactured vessels were implanted in 20 patients with symptomatic peripheral arterial disease as above-knee, femoral-to-popliteal arterial bypass conduits. After HAV implantation, all patients were assessed for safety, HAV durability, freedom from conduit infection, and bypass patency for 2 years., Results: Twenty HAVs were placed in the arterial, above-knee, femoral-to-popliteal position in patients with rest pain (n = 3) or symptomatic claudication (n = 17). All HAVs functioned as intended and had no evidence of structural failure or rejection by the recipient. No acute HAV infections were reported, but three surgical site infections were documented during the study period. Three non-HAV-related deaths were reported. One vessel developed a pseudoaneurysm after suspected iatrogenic injury during a balloon thrombectomy. No amputations of the HAV implanted limb occurred over the 2-year period, and no HAV infections were reported in approximately 34 patient-years of continuous patient follow-up., Conclusions: Human tissue engineered blood vessels can be manufactured and readily available for peripheral arterial bypass surgery. Early clinical experience with these vessels, in the arterial position, suggest that they are safe, have acceptable patency, a low incidence of infection, and do not require the harvest of autologous vein or any cells from the recipient. Histologic examination of tissue biopsies revealed vascular remodeling and repopulation by host cells. This first-in-man arterial bypass study supports the continued development of human tissue engineered blood vessels for arterial reconstruction, and potential future expansion to clinical indications including vascular trauma and repair of other size-appropriate peripheral arteries., (Copyright © 2019 Society for Vascular Surgery. Published by Elsevier Inc. All rights reserved.)

Published

2020

41. Reduced patency in left-sided arteriovenous grafts in a porcine model.

Author

Liu S, Wang T, Wang J, Isaji T, Ono S, Fereydooni A, Taniguchi R, Matsubara Y, Niklason LE, and Dardik A

Subjects

Animals, Arteriovenous Shunt, Surgical instrumentation, Blood Vessel Prosthesis, Blood Vessel Prosthesis Implantation instrumentation, Carotid Artery, Common pathology, Carotid Artery, Common physiopathology, Graft Occlusion, Vascular pathology, Graft Occlusion, Vascular physiopathology, Jugular Veins pathology, Jugular Veins physiopathology, Male, Models, Animal, Polytetrafluoroethylene, Prosthesis Design, Risk Factors, Sus scrofa, Time Factors, Arteriovenous Shunt, Surgical adverse effects, Blood Vessel Prosthesis Implantation adverse effects, Carotid Artery, Common surgery, Graft Occlusion, Vascular etiology, Jugular Veins surgery, Vascular Patency

Abstract

Objective: The porcine arteriovenous graft model is commonly used to study hemodialysis vascular access failure, with most studies using a bilateral, paired-site approach in either the neck or femoral vessels. In humans, left- and right-sided central veins have different anatomy and diameters, and left-sided central vein catheters have worse outcomes. We assessed the effect of laterality on arteriovenous prosthetic graft patency and hypothesized that left-sided carotid-jugular arteriovenous prosthetic grafts have reduced patency in the porcine model., Methods: Arteriovenous polytetrafluoroethylene grafts were placed ipsilaterally or bilaterally in 10 Yorkshire male pigs from the common carotid artery to the internal jugular vein. Ultrasound measurements of blood flow velocities and diameters were assessed before graft placement. Animals were sacrificed at 1 week, 2 weeks, or 3 weeks. Patency was determined clinically; grafts and perianastomotic vessels were excised and analyzed with histology and immunostaining., Results: At baseline, left- and right-sided veins and arteries had similar blood flow velocities. Although internal jugular veins had similar diameters at baseline, left-sided carotid arteries had 11% smaller outer diameters (P = .0354). There were 10 left-sided and 8 right-sided polytetrafluoroethylene grafts placed; only 4 of 10 (40%) grafts were patent on the left compared with 7 of 8 (88%) grafts patent on the right (P = .04). Left-sided grafts had increased macrophages at the arterial anastomosis (P = .0007). Left-sided perianastomotic arteries had thicker walls (0.74 vs 0.60 mm; P = .0211) with increased intima-media area (1.14 vs 0.77 mm 2 ; P = .0169) as well as a trend toward 38% smaller luminal diameter (1.6 vs 2.5 mm; P = .0668) and 20% smaller outer diameter (3.0 vs 3.7 mm; P = .0861). Left- and right-sided perianastomotic veins were similar histologically, but left-sided veins had decreased expression of phosphorylated endothelial nitric oxide synthase (P = .0032) and increased numbers of α-actin-positive smooth muscle cells (P = .0022)., Conclusions: Left-sided arteriovenous grafts are associated with reduced short-term patency compared with right-sided grafts in the Yorkshire pig preclinical model of arteriovenous prosthetic grafts. Laterality must be considered in planning and interpreting surgical preclinical models., (Published by Elsevier Inc.)

Published

2020

42. Microvessel Network Formation and Interactions with Pancreatic Islets in Three-Dimensional Chip Cultures.

Author

Rambøl MH, Han E, and Niklason LE

Subjects

Animals, Cells, Cultured, Female, Fibrin chemistry, Humans, Induced Pluripotent Stem Cells cytology, Induced Pluripotent Stem Cells metabolism, Islets of Langerhans metabolism, Male, Mesenchymal Stem Cells metabolism, Rats, Islets of Langerhans cytology, Mesenchymal Stem Cells cytology

Abstract

The pancreatic islet is a highly vascularized micro-organ, and rapid revascularization postislet transplantation is important for islet survival and function. However, the various mechanisms involved in islet revascularization are not fully understood, and we currently lack good in vitro platforms to explore this. Our aim for this study was to generate perfusable microvascular networks in a microfluidic chip device, in which islets could be easily integrated, to establish an in vitro platform for investigations on islet-microvasculature interactions. We compared the ability of mesenchymal stem cells (MSCs) and fibroblasts to support microvascular network formation by human umbilical vein endothelial cells (HUVECs) and human induced pluripotent stem cell-derived endothelial colony-forming cell in two-dimensional and three-dimensional models of angiogenesis, and tested the effect of different culture media on microvessel formation. HUVECs that were supported by MSCs formed patent and perfusable networks in a fibrin gel, whereas networks supported by fibroblasts rapidly regressed. Network morphology could be controlled by adjusting relative cell numbers and densities. Incorporation of isolated rat islets demonstrated that islets recruit local microvasculature in vitro , but that the microvessels did not invade islets, at least during the course of these studies. This in vitro microvascularization platform can provide a useful tool to study how various parameters affect islet integration with microvascular networks and could also be utilized for studies of vascularization of other organ systems. Impact statement To improve pancreatic islet graft survival and function posttransplantation, rapid and adequate revascularization is critical. Efforts to improve islet revascularization are demanding due to an insufficient understanding of the mechanisms involved in the process. We have applied a microfluidics platform to generate microvascular networks, and by incorporating pancreatic islets, we were able to study microvasculature-islet interactions in real time. This platform can provide a useful tool to study islet integration with microvascular networks, and could be utilized for studies of vascularization of other organ systems. Moreover, this work may be adapted toward developing a prevascularized islet construct for transplantation.

Published

2020

43. Platform Effects on Regeneration by Pulmonary Basal Cells as Evaluated by Single-Cell RNA Sequencing.

Author

Greaney AM, Adams TS, Brickman Raredon MS, Gubbins E, Schupp JC, Engler AJ, Ghaedi M, Yuan Y, Kaminski N, and Niklason LE

Subjects

Animals, Cell Differentiation, Epithelial Cells cytology, Epithelial Cells metabolism, Epithelium physiology, Male, Rats, Rats, Sprague-Dawley, Tissue Engineering, Trachea cytology, Transcriptome genetics, Lung cytology, RNA-Seq, Regeneration, Single-Cell Analysis

Abstract

Cell-based therapies have shown promise for treating myriad chronic pulmonary diseases through direct application of epithelial progenitors or by way of engineered tissue grafts or whole organs. To elucidate environmental effects on epithelial regenerative outcomes in vitro, here, we isolate and culture a population of pharmacologically expanded basal cells (peBCs) from rat tracheas. At peak basal marker expression, we simultaneously split peBCs into four in vitro platforms: organoid, air-liquid interface (ALI), engineered trachea, and engineered lung. Following differentiation, these samples are evaluated using single-cell RNA sequencing (scRNA-seq) and computational pipelines are developed to compare samples both globally and at the population level. A sample of native rat tracheal epithelium is also evaluated by scRNA-seq as a control for engineered epithelium. Overall, this work identifies platform-specific effects that support the use of engineered models to achieve the most physiologic differential outcomes in pulmonary epithelial regenerative applications., Competing Interests: Declaration of Interests L.E.N. is a founder of and shareholder in Humacyte, which is a regenerative medicine company. Humacyte produces engineered blood vessels from allogeneic smooth muscle cells for vascular surgery. L.E.N.’s spouse has equity in Humacyte, and L.E.N. serves on Humacyte’s board of directors. L.E.N. is listed as an inventor on patents that are licensed to Humacyte and that produce royalties for L.E.N. L.E.N. has received an unrestricted research gift to support research in her laboratory at Yale University. Humacyte did not fund these studies and Humacyte did not influence the conduct, description, or interpretation of the findings in this article. N.K. served as a consultant to Boehringer Ingelheim, Third Rock, Pliant, Samumed, NuMedii, Indaloo, Theravance, LifeMax, Three Lake Partners, Optikira, and CohBar over the last 3 years and received non-financial support from MiRagen. N.K. is listed as an inventor on several patents and patent applications, none of which are relevant to this manuscript., (Copyright © 2020 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2020

44. Bioengineering the Blood-gas Barrier.

Author

Leiby KL, Raredon MSB, and Niklason LE

Subjects

Animals, Humans, Lung metabolism, Lung Diseases metabolism, Lung Diseases pathology, Lung Diseases therapy, Pulmonary Circulation, Bioengineering methods, Blood-Air Barrier, Lung physiology, Pulmonary Gas Exchange

Abstract

The pulmonary blood-gas barrier represents a remarkable feat of engineering. It achieves the exquisite thinness needed for gas exchange by diffusion, the strength to withstand the stresses and strains of repetitive and changing ventilation, and the ability to actively maintain itself under varied demands. Understanding the design principles of this barrier is essential to understanding a variety of lung diseases, and to successfully regenerating or artificially recapitulating the barrier ex vivo. Many classical studies helped to elucidate the unique structure and morphology of the mammalian blood-gas barrier, and ongoing investigations have helped to refine these descriptions and to understand the biological aspects of blood-gas barrier function and regulation. This article reviews the key features of the blood-gas barrier that enable achievement of the necessary design criteria and describes the mechanical environment to which the barrier is exposed. It then focuses on the biological and mechanical components of the barrier that preserve integrity during homeostasis, but which may be compromised in certain pathophysiological states, leading to disease. Finally, this article summarizes recent key advances in efforts to engineer the blood-gas barrier ex vivo, using the platforms of lung-on-a-chip and tissue-engineered whole lungs. © 2020 American Physiological Society. Compr Physiol 10:415-452, 2020., (Copyright © 2020 American Physiological Society. All rights reserved.)

Published

2020

45. Tissue-Engineered Vascular Grafts with Advanced Mechanical Strength from Human iPSCs.

Author

Luo J, Qin L, Zhao L, Gui L, Ellis MW, Huang Y, Kural MH, Clark JA, Ono S, Wang J, Yuan Y, Zhang SM, Cong X, Li G, Riaz M, Lopez C, Hotta A, Campbell S, Tellides G, Dardik A, Niklason LE, and Qyang Y

Subjects

Humans, Myocytes, Smooth Muscle, Tissue Engineering, Blood Vessel Prosthesis, Induced Pluripotent Stem Cells

Abstract

Vascular smooth muscle cells (VSMCs) can be derived in large numbers from human induced pluripotent stem cells (hiPSCs) for producing tissue-engineered vascular grafts (TEVGs). However, hiPSC-derived TEVGs are hampered by low mechanical strength and significant radial dilation after implantation. Here, we report generation of hiPSC-derived TEVGs with mechanical strength comparable to native vessels used in arterial bypass grafts by utilizing biodegradable scaffolds, incremental pulsatile stretching, and optimal culture conditions. Following implantation into a rat aortic model, hiPSC-derived TEVGs show excellent patency without luminal dilation and effectively maintain mechanical and contractile function. This study provides a foundation for future production of non-immunogenic, cellularized hiPSC-derived TEVGs composed of allogenic vascular cells, potentially serving needs to a considerable number of patients whose dysfunctional vascular cells preclude TEVG generation via other methods., Competing Interests: Declaration of Interests L.E.N. is a founder and shareholder in Humacyte. Humacyte produces engineered blood vessels from allogeneic smooth muscle cells for vascular surgery. L.E.N.’s spouse has equity in Humacyte, and L.E.N. serves on Humacyte’s Board of Directors. L.E.N. is an inventor on patents that are licensed to Humacyte and produce royalties for L.E.N. Humacyte neither funded current studies nor influenced the conduct, description, or interpretation of the findings in this report. The authors declare a patent filed related to this work., (Copyright © 2020 Elsevier Inc. All rights reserved.)

Published

2020

46. Single-cell connectomic analysis of adult mammalian lungs.

Author

Raredon MSB, Adams TS, Suhail Y, Schupp JC, Poli S, Neumark N, Leiby KL, Greaney AM, Yuan Y, Horien C, Linderman G, Engler AJ, Boffa DJ, Kluger Y, Rosas IO, Levchenko A, Kaminski N, and Niklason LE

Subjects

Animals, Cell Line, Extracellular Space metabolism, Genes, Homeostasis, Humans, Ligands, Pulmonary Alveoli metabolism, Receptors, Cell Surface metabolism, Semaphorins metabolism, Signal Transduction, Species Specificity, Vascular Endothelial Growth Factor A metabolism, Connectome, Lung cytology, Mammals metabolism, Single-Cell Analysis

Abstract

Efforts to decipher chronic lung disease and to reconstitute functional lung tissue through regenerative medicine have been hampered by an incomplete understanding of cell-cell interactions governing tissue homeostasis. Because the structure of mammalian lungs is highly conserved at the histologic level, we hypothesized that there are evolutionarily conserved homeostatic mechanisms that keep the fine architecture of the lung in balance. We have leveraged single-cell RNA sequencing techniques to identify conserved patterns of cell-cell cross-talk in adult mammalian lungs, analyzing mouse, rat, pig, and human pulmonary tissues. Specific stereotyped functional roles for each cell type in the distal lung are observed, with alveolar type I cells having a major role in the regulation of tissue homeostasis. This paper provides a systems-level portrait of signaling between alveolar cell populations. These methods may be applicable to other organs, providing a roadmap for identifying key pathways governing pathophysiology and informing regenerative efforts., (Copyright © 2019 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works. Distributed under a Creative Commons Attribution NonCommercial License 4.0 (CC BY-NC).)

Published

2019

47. Engineering of human brain organoids with a functional vascular-like system.

Author

Cakir B, Xiang Y, Tanaka Y, Kural MH, Parent M, Kang YJ, Chapeton K, Patterson B, Yuan Y, He CS, Raredon MSB, Dengelegi J, Kim KY, Sun P, Zhong M, Lee S, Patra P, Hyder F, Niklason LE, Lee SH, Yoon YS, and Park IH

Subjects

Animals, Blood-Brain Barrier, Cells, Cultured, Humans, Mice, Single-Cell Analysis, Transcription Factors physiology, Brain blood supply, Human Embryonic Stem Cells cytology, Organoids blood supply, Tissue Engineering methods

Abstract

Human cortical organoids (hCOs), derived from human embryonic stem cells (hESCs), provide a platform to study human brain development and diseases in complex three-dimensional tissue. However, current hCOs lack microvasculature, resulting in limited oxygen and nutrient delivery to the inner-most parts of hCOs. We engineered hESCs to ectopically express human ETS variant 2 (ETV2). ETV2-expressing cells in hCOs contributed to forming a complex vascular-like network in hCOs. Importantly, the presence of vasculature-like structures resulted in enhanced functional maturation of organoids. We found that vascularized hCOs (vhCOs) acquired several blood-brain barrier characteristics, including an increase in the expression of tight junctions, nutrient transporters and trans-endothelial electrical resistance. Finally, ETV2-induced endothelium supported the formation of perfused blood vessels in vivo. These vhCOs form vasculature-like structures that resemble the vasculature in early prenatal brain, and they present a robust model to study brain disease in vitro.

Published

2019

48. Non-invasive and real-time measurement of microvascular barrier in intact lungs.

Author

Engler AJ, Raredon MSB, Le AV, Yuan Y, Oczkowicz YA, Kan EL, Baevova P, and Niklason LE

Subjects

Animals, Bioreactors, Endothelium pathology, Lung ultrastructure, Lung Injury pathology, Male, Rats, Sprague-Dawley, Tissue Culture Techniques, Tissue Engineering, Computer Systems, Lung blood supply, Microvessels pathology

Abstract

Microvascular leak is a phenomenon witnessed in multiple disease states. In organ engineering, regaining a functional barrier is the most crucial step towards creating an implantable organ. All previous methods of measuring microvascular permeability were either invasive, lengthy, introduced exogenous macromolecules, or relied on extrapolations from cultured cells. We present here a system that enables real-time measurement of microvascular permeability in intact rat lungs. Our unique system design allows direct, non-invasive measurement of average alveolar and capillary pressures, tracks flow paths within the organ, and enables calculation of lumped internal resistances including microvascular barrier. We first describe the physiology of native and decellularized lungs and the inherent properties of the extracellular matrix as functions of perfusion rate. We next track changing internal resistances and flows in injured native rat lungs, resolving the onset of microvascular leak, quantifying changing vascular resistances, and identifying distinct phases of organ failure. Finally, we measure changes in permeability within engineered lungs seeded with microvascular endothelial cells, quantifying cellular effects on internal vascular and barrier resistances over time. This system marks considerable progress in bioreactor design for intact organs and may be used to monitor and garner physiological insights into native, decellularized, and engineered tissues., (Copyright © 2019 Elsevier Ltd. All rights reserved.)

Published

2019

49. Utilization of Natural Detergent Potassium Laurate for Decellularization in Lung Bioengineering.

Author

Obata T, Tsuchiya T, Akita S, Kawahara T, Matsumoto K, Miyazaki T, Masumoto H, Kobayashi E, Niklason LE, and Nagayasu T

Subjects

Animals, Epithelial Cells cytology, Lung cytology, Lung metabolism, Male, Rats, Rats, Inbred F344, Epithelial Cells metabolism, Extracellular Matrix chemistry, Extracellular Matrix Proteins chemistry, Lauric Acids chemistry, Lung chemistry, Tissue Engineering, Tissue Scaffolds chemistry

Abstract

Impact Statement: Recent advances in tissue engineering using decellularized organ scaffolds have expanded the possibilities for organ replacement therapy. However, detergent-based decellularization itself damages the extracellular matrix (ECM), which results in failure associated with the transplanted bioengineered organ. This study determined that potassium laurate (PL), a natural detergent, significantly reduces lung ECM damage during the decellularization process compared with protocols using sodium dodecyl sulfate. PL-decellularized lungs showed better microarchitecture preservation and low biological reactions after subcutaneous implantation. PL-decellularized scaffolds supported rat lung endothelial cell attachment/proliferation and the bioengineered lungs significantly reduced lung congestion after transplantation.

Published

2019

50. Fas ligand and nitric oxide combination to control smooth muscle growth while sparing endothelium.

Author

Kural MH, Wang J, Gui L, Yuan Y, Li G, Leiby KL, Quijano E, Tellides G, Saltzman WM, and Niklason LE

Subjects

Animals, Bioreactors, Cell Proliferation drug effects, Cell Survival drug effects, Cells, Cultured, Coronary Vessels cytology, Endothelial Cells drug effects, Everolimus pharmacology, Gene Expression Regulation drug effects, Humans, Kinetics, Myocytes, Smooth Muscle drug effects, Nitroso Compounds pharmacology, Polymers chemistry, Swine, Endothelial Cells cytology, Fas Ligand Protein pharmacology, Myocytes, Smooth Muscle cytology, Nitric Oxide pharmacology, Sirolimus pharmacology

Abstract

Metallic stents cause vascular wall damage with subsequent smooth muscle cell (SMC) proliferation, neointimal hyperplasia, and treatment failure. To combat in-stent restenosis, drug-eluting stents (DES) delivering mTOR inhibitors such as sirolimus or everolimus have become standard for coronary stenting. However, the relatively non-specific action of mTOR inhibitors prevents efficient endothelium recovery and mandates dual antiplatelet therapy to prevent thrombosis. Unfortunately, long-term dual antiplatelet therapy leads to increased risk of bleeding/stroke and, paradoxically, myocardial infarction. Here, we took advantage of the fact that nitric oxide (NO) increases Fas receptors on the SMC surface. Fas forms a death-inducing complex upon binding to Fas ligand (FasL), while endothelial cells (ECs) are relatively resistant to this pathway. Selected doses of FasL and NO donor synergistically increased SMC apoptosis and inhibited SMC growth more potently than did everolimus or sirolimus, while having no significant effect on EC viability and proliferation. This differential effect was corroborated in ex vivo pig coronaries, where the neointimal formation was inhibited by the drug combination, but endothelial viability was retained. We also deployed FasL-NO donor-releasing ethylene-vinyl acetate copolymer (EVAc)-coated stents into pig coronary arteries, and cultured them in perfusion bioreactors for one week. FasL and NO donor, released from the stent coating, killed SMCs close to the stent struts, even in the presence of flow rates mimicking those of native arteries. Thus, the FasL-NO donor-combination has a potential to prevent intimal hyperplasia and in-stent restenosis, without harming endothelial restoration, and hence may be a superior drug delivery strategy for DES., (Copyright © 2019. Published by Elsevier Ltd.)

Published

2019