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1. Dental, Oral, and Craniofacial Regenerative Medicine: Transforming Biotechnologies for Innovating Patient Care

Author

Giannobile, WV, Chai, Y, Chen, Y, Healy, KE, Klein, O, Lane, N, Longaker, MT, Lotz, JC, Mooney, DJ, Sfeir, CS, Urata, M, Wagner, WR, Wu, BM, and Kohn, DH

Subjects
Medical Biotechnology, Biomedical and Clinical Sciences, Dentistry, Regenerative Medicine, Dental/Oral and Craniofacial Disease, Bioengineering, Congenital Structural Anomalies, Pediatric, Oral and gastrointestinal, Dental Care, Diffusion of Innovation, Humans, Multi-Institutional Systems, Oral Surgical Procedures, Organizational Objectives, Tissue Engineering, United States, Universities, tissue engineering, regeneration, bioengineering, craniofacial research, translational research, research innovation
Published
2018

2. Abstracts of Original Contributions Cardiovascular Molecular Imaging Symposium May 3–4, 2004 Bethesda, Maryland

Author

Lahoutte, T, Vanhove, C, Caveliers, V, Defrise, M, Everaert, H, Bossuyt, A, Franken, P. R., Schäfers, K. P., Kriens, M., Barnard, C., Schober, O., Schäfers, M., Kopka, K, Wagner, S, Law, MP, Riemann, B, Pike, VW, Herrero, P, Dence, CS, Kisrieva-Ware, Z, Eisenbeis, P, Welch, MJ, Gropler, RJ, Bucerius, J, Joe, AY, Schmaliohann, J, Gündisch, D, Reinhardt, MJ, Biersack, H-J, Wüllner, U, Ranney, DF, Peshock, RM, McDonald, GG, Slomka, PJ, deKemp, RA, Beanlands, RSB, Nishina, H, Abidov, A, Berman, DS, Germano, G, Riou, LM, Goode, AR, Hatada, K, Ruiz, M, Lima, R, Harris, TD, Beller, GA, Glover, DK, Kim, H, Miceli, MH, Delbeke, D, Bhargava, P, Jackson, LB Jones, Walker, RC, Anaissie, E, Alavi, A, Hanrahan, SM, Janabi, M, Taylor, SE, Rychak, JJ, Klibanov, AL, Leppanen, A, Cummings, RD, Ley, K, Rychak, JJ, Klibanov, AL, Hossack, J, Dence, CS, Herrero, P, Gropler, RJ, Welch, MJ, Veress, AI, Feng, B, Yang, Y, Weiss, JA, Huesman, RH, Gullberg, GT, Sharp, TL, Herrero, P, Englebach, JA, Fettig, NM, Gropler, RJ, Welch, MJ, Dobrucki, LW, Hua, J, Bourke, BN, Sadeghi, MM, Cavaliere, P, Mendizabal, M, VanRoyen, N, Buschmann, IR, Sinusas, AJ, Sadeghi, MM, Zhang, J, Fassaei, HR, Krassilnikova, S, Esmailzadeh, L, Gharaei, AA, Kooshkabadi, A, Edwards, DS, Harris, TD, Yalamanchili, P, Sinusas, AJ, Zaret, BL, Bender, JR, Epstein, FH, Gilson, WD, Sureau, FC, Yang, Z, French, BA, Lewis, S, Lu, XE, Tom, EM, Felix, MM, Gretton, JE, Varghese, RP, Wagner, WR, and Villanueva, FS

Published
2004
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5. A novel approach to fully characterize fiber network morphology of planar fibrous tissues and scaffolds

Author

D'AMORE, Antonio, Stella, JA, Wagner, WR, Sacks, MS, D'Amore, A, Stella, JA, Wagner, WR, and Sacks, MS

Subjects
Image Aanalysis, Soft Tissue Engineering, Electrospinning, Collagen Gel, DEcellularized Tissue
Abstract

Understanding how scaffold structure influences cell morphology, metabolism, phenotypic expression, and predicting mechanical behaviors have increasingly become crucial goals in the development of engineered tissue scaffolds. A novel image-based analysis algorithm that provides an automatic tool to characterize engineered tissue fiber network topology is presented. Micro architectural descriptors that unambiguously define the fiber network topology were detected, which include fiber orientation distribution, connectivity, intersection spatial density, and diameter. Algorithm performance was tested using actual sample scanning electron microscopy (SEM) images of (1) electrospun poly(ester urethane)urea (ES-PEUU) scaffolds, (2) rabbit MSCs seeded collagen gel scaffolds, and (3) decellularized rat carotid arteries. Qualitative and quantitative validation was performed comparing fiber network topology manually detected by human operators (n=5) with the one automatically detected by the algorithm. R2 correlation values defining the correlation between manual detected and algorithm detected results for the fiber angle distribution and for the fiber connectivity distribution were 0.86 and 0.93 respectively. Algorithm detected fiber intersections and fiber diameter values were inside the (mean ± standard deviation) range detected by human operators. The algorithm’s ability to automatically identify and quantify the complete fiber network morphology regardless of the scaffold typology and of the scale of the problem was proven analyzing three different scaffold models. While the presented validation shows strong consistency between the human operators and the algorithm analysis results the automatic procedure guaranties objectivity and a significant reduction of the analysis time.

Published
2010

6. Micro-Meso Scale Models of Electrosun Poly (Ester Urethane) Urea Scaffolds

Author

D'AMORE, Antonio, Stella, JA, Schimdt, jE, Wagner, WR, Sacks, MS, D’Amore, A, Stella, JA, Schimdt, jE, Wagner, WR, and Sacks, MS

Subjects
Settore ING-IND/14 - Progettazione Meccanica E Costruzione Di Macchine, Soft tissue engineering, Electrospun PEUU scaffold, microstructure, FEM
Published
2009

7. Micro Scale Based Mechanical Models for Electrospun Poly (Ester Urethane) Urea Scaffolds

Author

D'AMORE, Antonio, Stella, JA, Schmidt, DE, Wagner, WR, Sacks, MS, D’Amore, A, Stella, JA, Schimdt, DE, Wagner, ER, Sacks, MS, D'Amore, A, Schmidt, DE, and Wagner, WR

Subjects
Settore ING-IND/14 - Progettazione Meccanica E Costruzione Di Macchine, Electrospun Poly (Ester Urethane) Urea Scaffolds, micro-structure, image analysis, soft tissue engineering, FEM, Electrospun Poly (Ester Urethane) Urea Scaffolds, Soft tissue engineering, microstructure, FEM
Abstract

Micro scale based mechanical models can provide a tool to guide tissue engineering scaffold design and to investigate on how the cellular mechanical and metabolic response are related to local micro-structural deformations. The present study proposes a novel approach to automatically collect micro-architectural data from SEM images of electrospun poly (ester urethane) urea (PEUU) and to recreate statistically equivalent scaffold mechanical models. Sets of contiguous SEM images for each of the three mandrel velocities (1.5, 4.5, 9.0 m/s) were analyzed. A combination of thresholding and morphological procedures enabled fibers overlaps to be detected. The algorithm precision was tested on regular grids of known characteristics. A modified Delanauy network was generated starting from the detected 2D fiber overlap coordinates. The following micro-architectural data were extracted from the generated network: (1) fiber overlap number and position, (2) connectivity distribution, (3) fiber angle distribution. Appropriate representative volume element (RVE) size was determined. A finite element model of the meso scale system (250 x 250 µm) was constructed respecting the micro-architectural data characterized by the image analysis. FEM and image analysis results revealed the capacity of the approach to characterize the material mechanical behavior at both the fiber and the global levels.

Published
2009

8. A Structural Deterministic Model for Electrospun Scaffolds

Author

D'AMORE, Antonio, Stella, JA, Schimdt, dE, Wagner, WR, Sacks, MS, D’Amore, A, Stella, JA, Schimdt, dE, Wagner, WR, and Sacks, MS

Subjects
Settore ING-IND/14 - Progettazione Meccanica E Costruzione Di Macchine, Electrospun poly (ester urethane) urea scaffolds, soft tissue engineering, structural modeling
Published
2009

9. Micro - Architectural Data Extraction for Electrospun Poly (Ester Urethane) Urea Scaffolds for Biomechanical Modeling

Author

D'AMORE, Antonio, Stella, JA, Schmidt, DE, Wagner, WR, Sacks, MS, D'Amore, A, Stella, JA, Schmidt, DE, Wagner, WR, and Sacks, MS

Subjects
Settore ING-IND/14 - Progettazione Meccanica E Costruzione Di Macchine, electrospun poly (ester urethane) urea (PEUU) scaffold, soft tissue engineering, microstructure
Abstract

Problem: Soft tissue engineered applications have raised the need for accurate descriptions of tissue microstructure and their contributions to global mechanical behavior [1]. Accurate material image analysis is crucial to model engineered tissue biomechanics. The present study proposes a novel method to automatically collect micro-architectural data from electron micrographs (SEM) of electrospun poly (ester urethane) urea (PEUU). Methods: Sets of contiguous SEM images for electrospun PEUU scaffolds made using three mandrel collection tangential velocities (1.5, 4.5, 9.0 m/s) were analyzed. A combination of thresholding and morphological procedures enabled overlaps of fibers to be detected. The algorithm detection precision was tested on regular grids of known characteristics. A modified Delanauy network was generated starting from the detected 2D fiber overlap coordinates. The following micro-architectural data were extracted from the generated network: (1) fiber overlap number and position, (2) connectivity distribution, (3) fiber angle distribution. Appropriate representative volume element (RVE) size was determined performing the image analysis over material areas of different sizes. Results: The number of overlaps, the total number of connections and the estimated porosity all decreased as the mandrel velocity was raised. Fiber orientation results were consistent with previous findings [1]. The RVE size increased as the mandrel velocity increased consistent with a higher degree of structural organization and fiber alignment. The number of fiber overlaps was predicted for a given mandrel velocity and scaffold area. Conclusions: The detected fiber overlaps, connectivity and angle distribution showed consistency with the known relationship between mandrel velocity and fiber alignment. The extracted data are considered to be highly relevant for electrospun PEUU scaffolds and collagenous tissue biomechanical modeling. The proposed approach enables a detailed analysis of the micro-architecture to be performed on electrospun PEUU scaffolds. References: 1) Courtney et al. Biomaterials 2006. 27, 3631-3638. Acknowledgements: The authors would like to acknowledge financial support from the NIH grant R01 HL-068816. Disclosures: None of the authors have financial interests related to the topic of the abstract.

Published
2009

10. A three-dimensional gel bioreactor for assessment of cardiomyocyte induction in skeletal muscle-derived stem cells

Author

Clause, KC, Tinney, JP, Liu, LJ, Gharaibeh, B, Huard, J, Kirk, JA, Shroff, SG, Fujimoto, KL, Wagner, WR, Ralphe, JC, Keller, BB, Tobita, K, Clause, KC, Tinney, JP, Liu, LJ, Gharaibeh, B, Huard, J, Kirk, JA, Shroff, SG, Fujimoto, KL, Wagner, WR, Ralphe, JC, Keller, BB, and Tobita, K

Abstract

Skeletal muscle-derived stem cells (MDSCs) are able to differentiate into cardiomyocytes (CMs). However, it remains to be investigated whether differentiated CMs contract similar to native CMs. Here, we developed a three-dimensional collagen gel bioreactor (3DGB) that induces a working CM phenotype from MDSCs, and the contractile properties are directly measured as an engineered cardiac tissue. Neonate rat MDSCs were isolated from hind-leg muscles via the preplate technique. Isolated MDSCs were approximately 60% positive to Sca-1 and negative to CD34, CD45, or c-kit antigens. We sorted Sca-1(-) MDSCs and constructed MDSC-3DGBs by mixing MDSCs with acid soluble rat tail collagen type-I and matrix factors. MDSC-3DGB exhibited spontaneous cyclic contraction by culture day 7. MDSC-3DGB expressed cardiac-specific genes and proteins. Histological assessment revealed that cardiac-specific troponin-T and-I expressed in a typical striation pattern and connexin-43 was expressed similar to the native fetal ventricular papillary muscle. β-Adrenergic stimulation increased MDSC-3DGB spontaneous beat frequency. MDSC-3DGB generated contractile force and intracellular calcium ion transients similar to engineered cardiac tissue from native cardiac cells. Results suggest that MDSC-3DGB induces a working CM phenotype in MDSCs and is a useful 3D culture system to directly assess the contractile properties of differentiated CMs in vitro. © 2010 Mary Ann Liebert, Inc.

Published
2010

11. Pericyte-based human tissue engineered vascular grafts

Author

He, W, Nieponice, A, Soletti, L, Hong, Y, Gharaibeh, B, Crisan, M, Usas, A, Peault, B, Huard, J, Wagner, WR, Vorp, DA, He, W, Nieponice, A, Soletti, L, Hong, Y, Gharaibeh, B, Crisan, M, Usas, A, Peault, B, Huard, J, Wagner, WR, and Vorp, DA

Abstract

The success of small-diameter tissue engineered vascular grafts (TEVGs) greatly relies on an appropriate cell source and an efficient cellular delivery and carrier system. Pericytes have recently been shown to express mesenchymal stem cell features. Their relative availability and multipotentiality make them a promising candidate for TEVG applications. The objective of this study was to incorporate pericytes into a biodegradable scaffold rapidly, densely and efficiently, and to assess the efficacy of the pericyte-seeded scaffold in vivo. Bi-layered elastomeric poly(ester-urethane)urea scaffolds (length = 10 mm; inner diameter = 1.3 mm) were bulk seeded with 3 × 106 pericytes using a customized rotational vacuum seeding device in less than 2 min (seeding efficiency > 90%). The seeded scaffolds were cultured in spinner flasks for 2 days and then implanted into Lewis rats as aortic interposition grafts for 8 weeks. Results showed pericytes populated the porous layer of the scaffolds evenly and maintained their original phenotype after the dynamic culture. After implantation, pericyte-seeded TEVGs showed a significant higher patency rate than the unseeded control: 100% versus 38% (p < 0.05). Patent pericyte-seeded TEVGs revealed extensive tissue remodeling with collagen and elastin present. The remodeled tissue consisted of multiple layers of α-smooth muscle actin- and calponin-positive cells, and a von Willebrand factor-positive monolayer in the lumen. These results demonstrate the feasibility of a pericyte-based TEVG and suggest that the pericytes play a role in maintaining patency of the TEVG as an arterial conduit. © 2010 Elsevier Ltd.

Published
2010

12. In Vivo assessment of a tissue-engineered vascular graft combining a biodegradable elastomeric scaffold and muscle-derived stem cells in a rat model

Author

Nieponice, A, Soletti, L, Guan, J, Hong, Y, Gharaibeh, B, Maul, TM, Huard, J, Wagner, WR, Vorp, DA, Nieponice, A, Soletti, L, Guan, J, Hong, Y, Gharaibeh, B, Maul, TM, Huard, J, Wagner, WR, and Vorp, DA

Abstract

Limited autologous vascular graft availability and poor patency rates of synthetic grafts for bypass or replacement of small-diameter arteries remain a concern in the surgical community. These limitations could potentially be improved by a tissue engineering approach. We report here our progress in the development and in vivo testing of a stem-cell-based tissue-engineered vascular graft for arterial applications. Poly(ester urethane)urea scaffolds (length=10mm; inner diameter=1.2mm) were created by thermally induced phase separation (TIPS). Compound scaffolds were generated by reinforcing TIPS scaffolds with an outer electrospun layer of the same biomaterial (ES-TIPS). Both TIPS and ES-TIPS scaffolds were bulk-seeded with 10×106 allogeneic, LacZ-transfected, muscle-derived stem cells (MDSCs), and then placed in spinner flask culture for 48h. Constructs were implanted as interposition grafts in the abdominal aorta of rats for 8 weeks. Angiograms and histological assessment were performed at the time of explant. Cell-seeded constructs showed a higher patency rate than the unseeded controls: 65% (ES-TIPS) and 53% (TIPS) versus 10% (acellular TIPS). TIPS scaffolds had a 50% mechanical failure rate with aneurysmal formation, whereas no dilation was observed in the hybrid scaffolds. A smooth-muscle-like layer of cells was observed near the luminal surface of the constructs that stained positive for smooth muscle α-actin and calponin. LacZ+ cells were shown to be engrafted in the remodeled construct. A confluent layer of von Willebrand Factor-positive cells was observed in the lumen of MDSC-seeded constructs, whereas acellular controls showed platelet and fibrin deposition. This is the first evidence that MDSCs improve patency and contribute to the remodeling of a tissue-engineered vascular graft for arterial applications. © 2010 Mary Ann Liebert, Inc.

Published
2010

13. Development of a tissue-engineered vascular graft combining a biodegradable scaffold, muscle-derived stem cells and a rotational vacuum seeding technique

Author

Nieponice, A, Soletti, L, Guan, J, Deasy, BM, Huard, J, Wagner, WR, Vorp, DA, Nieponice, A, Soletti, L, Guan, J, Deasy, BM, Huard, J, Wagner, WR, and Vorp, DA

Abstract

There is a clinical need for a tissue-engineered vascular graft (TEVG), and combining stem cells with biodegradable tubular scaffolds appears to be a promising approach. The goal of this study was to characterize the incorporation of muscle-derived stem cells (MDSCs) within tubular poly(ester urethane) urea (PEUU) scaffolds in vitro to understand their interaction, and to evaluate the mechanical properties of the constructs for vascular applications. Porous PEUU scaffolds were seeded with MDSCs using our recently described rotational vacuum seeding device, and cultured inside a spinner flask for 3 or 7 days. Cell viability, number, distribution and phenotype were assessed along with the suture retention strength and uniaxial mechanical behavior of the TEVGs. The seeding device allowed rapid even distribution of cells within the scaffolds. After 3 days, the constructs appeared completely populated with cells that were spread within the polymer. Cells underwent a population doubling of 2.1-fold, with a population doubling time of 35 h. Stem cell antigen-1 (Sca-1) expression by the cells remained high after 7 days in culture (77±20% vs. 66±6% at day 0) while CD34 expression was reduced (19±12% vs. 61±10% at day 0) and myosin heavy chain expression was scarce (not quantified). The estimated burst strength of the TEVG constructs was 2127±900 mmHg and suture retention strength was 1.3±0.3 N. We conclude from this study that MDSCs can be rapidly seeded within porous biodegradable tubular scaffolds while maintaining cell viability and high proliferation rates and without losing stem cell phenotype for up to 7 days of in-vitro culture. The successful integration of these steps is thought necessary to provide rapid availability of TEVGs, which is essential for clinical translation. © 2007 Elsevier Ltd. All rights reserved.

Published
2008

18. A custom image-based analysis tool for quantifying elastin and collagen micro-architecture in the wall of the human aorta from multi-photon microscopy

Author

Ryan G. Koch, William R. Wagner, Simon C. Watkins, Antonio D'Amore, Thomas G. Gleason, Alkiviadis Tsamis, David A. Vorp, Koch,RG, Tsamis,A, D’Amore,A, Wagner,WR, Watkins, SC, Gleason, TG, and Vorp DA

Subjects
Adult, Male, Aging, Micro-architecture, Materials science, Fibrillar Collagens, Biomedical Engineering, Biophysics, Connective tissue, Multi-photon microscopy, Tortuosity, Article, Weight-Bearing, Extracellular matrix, Quantification, medicine.artery, Microscopy, medicine, Humans, Orthopedics and Sports Medicine, Fiber, Aorta, Aged, Aged, 80 and over, biology, Binary image, Fiber orientation, Rehabilitation, Middle Aged, Extracellular Matrix, Elastin, medicine.anatomical_structure, Connective Tissue, biology.protein, Female, Collagen, Algorithms, Software, Biomedical engineering
Abstract

The aorta possesses a micro-architecture that imparts and supports a high degree of compliance and mechanical strength. Alteration of the quantity and/or arrangement of the main load-bearing components of this micro-architecture - the elastin and collagen fibers - leads to mechanical, and hence functional, changes associated with aortic disease and aging. Therefore, in the future, the ability to rigorously characterize the wall fiber micro-architecture could provide insight into the complicated mechanisms of aortic wall remodeling in aging and disease. Elastin and collagen fibers can be observed using state-of-the-art multi-photon microscopy. Image-analysis algorithms have been effective at characterizing fibrous constructs using various microscopy modalities. The objective of this study was to develop a custom MATLAB-language automated image-based analysis tool to describe multiple parameters of elastin and collagen micro-architecture in human soft fibrous tissue samples using multi-photon microscopy images. Human aortic tissue samples were used to develop the code. The tool smooths, cleans and equalizes fiber intensities in the image before segmenting the fibers into a binary image. The binary image is cleaned and thinned to a fiber skeleton representation of the image. The developed software analyzes the fiber skeleton to obtain intersections, fiber orientation, concentration, porosity, diameter distribution, segment length and tortuosity. In the future, the developed custom image-based analysis tool can be used to describe the micro-architecture of aortic wall samples in a variety of conditions. While this work targeted the aorta, the software has the potential to describe the architecture of other fibrous materials, tube-like networks and connective tissues

Published
2014
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19. On the biomechanical function of scaffolds for engineering load-bearing soft tissues

Author

Michael S. Sacks, Antonio D'Amore, William R. Wagner, John A. Stella, Stella, JA, D'Amore, A, Wagner, WR, and Sacks, MS

Subjects
Scaffold, Engineering, media_common.quotation_subject, Biomedical Engineering, Nanotechnology, Biochemistry, Article, Load bearing, Biomechanical Phenomena, Biomaterials, Settore ING-IND/14 - Progettazione Meccanica E Costruzione Di Macchine, Tissue engineering, Animals, Humans, Mechanical behavior, Function (engineering), Molecular Biology, media_common, Materials processing, business.industry, Regeneration (biology), Soft tissue, Extracellular matrix, General Medicine, Connective Tissue, Microscopy, Electron, Scanning, Biochemical engineering, business, Biotechnology
Abstract

Replacement or regeneration of load-bearing soft tissues has long been the impetus for the development of bioactive materials. While maturing, current efforts continue to be confounded by our lack of understanding of the intricate multi-scale hierarchical arrangements and interactions typically found in native tissues. The current state of the art in biomaterial processing enables a degree of controllable microstructure that can be used for the development of model systems to deduce fundamental biological implications of matrix morphologies on cell function. Furthermore, the development of computational frameworks which allow for the simulation of experimentally derived observations represents a positive departure from what has mostly been an empirically driven field, enabling a deeper understanding of the highly complex biological mechanisms we wish to ultimately emulate. Ongoing research is actively pursuing new materials and processing methods to control material structure down to the micro-scale to sustain or improve cell viability, guide tissue growth, and provide mechanical integrity, all while exhibiting the capacity to degrade in a controlled manner. The purpose of this review is not to focus solely on material processing but to assess the ability of these techniques to produce mechanically sound tissue surrogates, highlight the unique structural characteristics produced in these materials, and discuss how this translates to distinct macroscopic biomechanical behaviors.

Published
2010
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20. Nonthrombogenic, Biodegradable Elastomeric Polyurethanes with Variable Sulfobetaine Content

Author

Samuel K. Luketich, William R. Wagner, Antonio D'Amore, Sang-Ho Ye, Yi Hong, Venkat Shankarraman, Hirokazu Sakaguchi, Ye, SH, Hong, Y, Sakaguchi, H, Shankarraman, V, Luketich, SK, D'Amore, A, and Wagner, WR

Subjects
Materials science, Polyurethanes, Thrombogenicity, Biocompatible Materials, Elastomer, Fibrinolytic Agents, Hardness, Tensile Strength, Ultimate tensile strength, Polymer chemistry, Absorbable Implants, Materials Testing, Animals, General Materials Science, Blood Coagulation, chemistry.chemical_classification, biodegradable polyurethane, sulfobetaine, cardiovascular, thromboresistance, vascular graft, zwitterion, Polymer, Biodegradation, Electrospinning, Betaine, chemistry, Chemical engineering, Surface modification, Degradation (geology), Cattle
Abstract

For applications where degradable polymers are likely to have extended blood contact, it is often important for these materials to exhibit high levels of thromboresistance. This can be achieved with surface modification approaches, but such modifications may be transient with degradation. Alternatively, polymer design can be altered such that the bulk polymer is thromboresistant and this is maintained with degradation. Toward this end a series of biodegradable, elastic polyurethanes (PESBUUs) containing different zwitterionic sulfobetaine (SB) content were synthesized from a polycaprolactone-diol (PCL-diol):SB-diol mixture (100:0, 75:25, 50:50, 25:75 and 0:100) reacted with diisocyanatobutane and chain extended with putrescine. The chemical structure, tensile mechanical properties, thermal properties, hydrophilicity, biodegradability, fibrinogen adsorption and thrombogenicity of the resulting polymers was characterized. With increased SB content some weakening in tensile properties occurred in wet conditions and enzymatic degradation also decreased. However, at higher zwitterionic molar ratios (50% and 75%) wet tensile strength exceeded 15 MPa and breaking strain was >500%. Markedly reduced thrombotic deposition was observed both before and after substantial degradation for both of these PESBUUs and they could be processed by electrospinning into a vascular conduit format with appropriate compliance properties. The mechanical and degradation properties as well as the acute in vitro thrombogenicity assessment suggest that these tunable polyurethanes could provide options appropriate for use in blood contacting applications where a degradable, elastomeric component with enduring thromboresistance is desired.

Published
2014

21. Effects of fabrication on the mechanics, microstructure and micromechanical environment of small intestinal submucosa scaffolds for vascular tissue engineering

Author

J C Briceño, Andres Gonzalez-Mancera, Diana M. Sánchez-Palencia, William R. Wagner, Antonio D’ Amore, Sánchez-Palencia,DM, D’Amore, A, Gonzalez-Mancera, A, Wagner WR, and Briceño JC

Subjects
Void (astronomy), Scaffold, Materials science, Fabrication, Swine, Biomedical Engineering, Biophysics, Tissue engineering, Intestine, Small, Animals, Orthopedics and Sports Medicine, Intestinal Mucosa, Anisotropy, Microstructure, Tissue Engineering, Tissue Scaffolds, Rehabilitation, Micromechanics, SIS (small intestine submucosa), Small intestinal submucosa, Extracellular Matrix, Constitutive modeling, Collagen, Stress, Mechanical, Mechanical propertie, Biomedical engineering
Abstract

In small intestinal submucosa scaffolds for functional tissue engineering, the impact of scaffold fabrication parameters on success rate may be related to the mechanotransductory properties of the final microstructural organization of collagen fibers. We hypothesized that two fabrication parameters, 1) preservation (P) or removal (R) of a dense collagen layer present in SIS and 2) SIS in a final dehydrated (D) or hydrated (H) state, have an effect on scaffold void area, microstructural anisotropy (fiber alignment) and mechanical anisotropy (global mechanical compliance). We further integrated our experimental measurements in a constitutive model to explore final effects on the micromechanical environment inside the scaffold volume. Our results indicated that PH scaffolds might exhibit recurrent and large force fluctuations between layers (up to 195 pN), while fluctuations in RH scaffolds might be larger (up to 256 pN) but not as recurrent. In contrast, both PD and RD groups were estimated to produce scarcer and smaller fluctuations (not larger than 50 pN). We concluded that the hydration parameter strongly affects the micromechanics of SIS and that an adequate choice of fabrication parameters, assisted by the herein developed method, might leverage the use of SIS for functional tissue engineering applications, where forces at the cellular level are of concern in the guidance of new tissue formation.

Published
2013

22. Intervening to Preserve Function in Ischemic Cardiomyopathy with a Porous Hydrogel and Extracellular Matrix Composite in a Rat Myocardial Infarction Model.

Author

Hayashi Y, Fujii T, Kim S, Ozeki T, Badylak SF, D'Amore A, Mutsuga M, and Wagner WR

Abstract

Multiple hydrogels are developed for injection therapy after myocardial infarction, with some incorporating substances promoting tissue regeneration and others emphasizing mechanical effects. In this study, porosity and extracellular matrix-derived digest (ECM) are incorporated, into a mechanically optimized, thermoresponsive, degradable hydrogel (poly(N-isopropylacrylamide-co-N-vinylpyrrolidone-co-MAPLA)) and evaluate whether this biomaterial injectate can abrogate adverse remodeling in rat ischemic cardiomyopathy. After myocardial infarction, rats are divided into four groups: NP (non-porous hydrogel) without either ECM or porosity, PM (porous hydrogel) from the same synthetic copolymer with mannitol beads as porogens, and PME with porosity and ECM digest added to the synthetic copolymer. PBS injection alone is a control group. Intramyocardial injections occurred 3 days after myocardial infarction followed by serial echocardiography and histological assessments 8 weeks after infarction. Echocardiographic function and neovascularization improved in the PME group compared to the other hydrogels and PBS injection. The PME group also demonstrated improved LV geometry and macrophage polarization (toward M2) compared to PBS, whereas differences are not observed in the NP or PM groups versus control. These results demonstrate further functional improvement may be achieved in hydrogel injection therapy for ischemic cardiomyopathy by incorporating porosity and ECM digest, representing combined mechanical and biological effects., (© 2024 The Author(s). Advanced Healthcare Materials published by Wiley‐VCH GmbH.)

Published
2024
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23. Improving the hemocompatibility of a porohyperelastic layered vascular graft using luminal reversal microflows.

Author

Behrangzade A, Ye SH, Maestas DR Jr, Wagner WR, and Vande Geest JP

Subjects
Porosity, Elasticity, Finite Element Analysis, Humans, Biocompatible Materials chemistry, Biocompatible Materials pharmacology, Blood Platelets, Thrombosis, Blood Vessel Prosthesis, Materials Testing
Abstract

Vascular graft thrombosis is a long-standing clinical problem. A myriad of efforts have been devoted to reducing thrombus formation following bypass surgery. Researchers have primarily taken a chemical approach to engineer and modify surfaces, seeking to make them more suitable for blood contacting applications. Using mechanical forces and surface topology to prevent thrombus formation has recently gained more attention. In this study, we have designed a bilayered porous vascular graft capable of repelling platelets and destabilizing absorbed protein layers from the luminal surface. During systole, fluid penetrates through the graft wall and is subsequently ejected from the wall into the luminal space (Luminal Reversal Flow - LRF), pushing platelets away from the surface during diastole. In-vitro hemocompatibility tests were conducted to compare platelet deposition in high LRF grafts with low LRF grafts. Graft material properties were determined and utilized in a porohyperelastic (PHE) finite element model to computationally predict the LRF generation in each graft type. Hemocompatibility testing showed significantly lower platelet deposition values in high versus low LRF generating grafts (median±IQR = 5,708 ± 987 and 23,039 ± 3,310 platelets per mm 2 , respectively, p=0.032). SEM imaging of the luminal surface of both graft types confirmed the quantitative blood test results. The computational simulations of high and low LRF generating grafts resulted in LRF values of -10.06 μm/s and -2.87 μm/s, respectively. These analyses show that a 250% increase in LRF is associated with a 75.2% decrease in platelet deposition. PHE vascular grafts with high LRF have the potential to improve anti-thrombogenicity and reduce thrombus-related post-procedure complications. Additional research is required to overcome the limitations of current graft fabrication technologies that further enhance LRF generation., Competing Interests: Declaration of competing interest The authors declare the following financial interests/personal relationships which may be considered as potential competing interests: Jonathan Pieter Vande Geest and Ali Behrangzade has patent #US patent 18008476 pending to University of Pittsburgh. If there are other authors, they 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 © 2024. Published by Elsevier Ltd.)

Published
2024
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24. Development of an Injectable, ECM-Derivative Embolic for the Treatment of Cerebral Saccular Aneurysms.

Author

Kim S, Nowicki KW, Kohyama K, Mittal A, Ye S, Wang K, Fujii T, Rajesh S, Cao C, Mantena R, Barbuto M, Jung Y, Gross BA, Friedlander RM, and Wagner WR

Subjects
Animals, Mice, Hyaluronic Acid chemistry, Gelatin chemistry, Male, Humans, Intracranial Aneurysm therapy, Embolization, Therapeutic methods, Extracellular Matrix
Abstract

Cerebral aneurysms are a source of neurological morbidity and mortality, most often as a result of rupture. The most common approach for treating aneurysms involves endovascular embolization using nonbiodegradable medical devices, such as platinum coils. However, the need for retreatment due to the recanalization of coil-treated aneurysms highlights the importance of exploring alternative solutions. In this study, we propose an injectable extracellular matrix-derived embolic formed in situ by Michael addition of gelatin-thiol (Gel-SH) and hyaluronic acid vinyl sulfone (HA-VS) that may be delivered with a therapeutic agent (here, RADA-SP) to fill and remodel aneurysmal tissue without leaving behind permanent foreign bodies. The injectable embolic material demonstrated rapid gelation under physiological conditions, forming a highly porous structure and allowing for cellular infiltration. The injectable embolic exhibited thrombogenic behavior in vitro that was comparable to that of alginate injectables. Furthermore, in vivo studies in a murine carotid aneurysm model demonstrated the successful embolization of a saccular aneurysm and extensive cellular infiltration both with and without RADA-SP at 3 weeks, with some evidence of increased vascular or fibrosis markers with RADA-SP incorporation. The results indicate that the developed embolic has inherent potential for acutely filling cerebrovascular aneurysms and encouraging the cellular infiltration that would be necessary for stable, chronic remodeling.

Published
2024
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25. Redefining vascular repair: revealing cellular responses on PEUU-gelatin electrospun vascular grafts for endothelialization and immune responses on in vitro models.

Author

Rodríguez-Soto MA, Riveros-Cortés A, Orjuela-Garzón IC, Fernández-Calderón IM, Rodríguez CF, Vargas NS, Ostos C, Camargo CM, Cruz JC, Kim S, D'Amore A, Wagner WR, and Briceño JC

Abstract

Tissue-engineered vascular grafts (TEVGs) poised for regenerative applications are central to effective vascular repair, with their efficacy being significantly influenced by scaffold architecture and the strategic distribution of bioactive molecules either embedded within the scaffold or elicited from responsive tissues. Despite substantial advancements over recent decades, a thorough understanding of the critical cellular dynamics for clinical success remains to be fully elucidated. Graft failure, often ascribed to thrombogenesis, intimal hyperplasia, or calcification, is predominantly linked to improperly modulated inflammatory reactions. The orchestrated behavior of repopulating cells is crucial for both initial endothelialization and the subsequent differentiation of vascular wall stem cells into functional phenotypes. This necessitates the TEVG to provide an optimal milieu wherein immune cells can promote early angiogenesis and cell recruitment, all while averting persistent inflammation. In this study, we present an innovative TEVG designed to enhance cellular responses by integrating a physicochemical gradient through a multilayered structure utilizing synthetic (poly (ester urethane urea), PEUU) and natural polymers (Gelatin B), thereby modulating inflammatory reactions. The luminal surface is functionalized with a four-arm polyethylene glycol (P4A) to mitigate thrombogenesis, while the incorporation of adhesive peptides (RGD/SV) fosters the adhesion and maturation of functional endothelial cells. The resultant multilayered TEVG, with a diameter of 3.0 cm and a length of 11 cm, exhibits differential porosity along its layers and mechanical properties commensurate with those of native porcine carotid arteries. Analyses indicate high biocompatibility and low thrombogenicity while enabling luminal endothelialization and functional phenotypic behavior, thus limiting inflammation in in-vitro models. The vascular wall demonstrated low immunogenicity with an initial acute inflammatory phase, transitioning towards a pro-regenerative M2 macrophage-predominant phase. These findings underscore the potential of the designed TEVG in inducing favorable immunomodulatory and pro-regenerative environments, thus holding promise for future clinical applications in vascular tissue engineering., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest. The author(s) declared that they were an editorial board member of Frontiers, at the time of submission. This had no impact on the peer review process and the final decision., (Copyright © 2024 Rodríguez-Soto, Riveros-Cortés, Orjuela-Garzón, Fernández-Calderón, Rodríguez, Vargas, Ostos, Camargo, Cruz, Kim, D’Amore, Wagner and Briceño.)

Published
2024
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26. Open-Source Image-Based Tool to Experimentally Evaluate Blood Residence Time in Clinical Devices.

Author

Menallo G, Miraglia R, Gerasia R, Cosentino F, Terranova P, Barbuto M, Wagner WR, and D'Amore A

Subjects
Humans, Software, Time Factors, Image Processing, Computer-Assisted methods
Abstract

This article introduces an open-source tool to experimentally compare blood residence time in biomedical devices using an image-based method. The experimental setup and the postprocessing workflow are comprehensively elucidated in a detailed report that conducts a thorough comparison of the residence times of a blood analog within three distinct blood oxygenator prototypes. To enable widespread accessibility and ease of use, the user-friendly MATLAB App developed for the analysis is available on the Mathworks repository: https://www.mathworks.com/matlabcentral/fileexchange/135156 ., Competing Interests: Disclosure: The authors have no conflicts of interest to report., (Copyright © ASAIO 2024.)

Published
2024
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27. Influence of Polymer Stiffness and Geometric Design on Fluid Mechanics in Tissue-Engineered Pulmonary Valve Scaffolds.

Author

Pedersen DD, Kim S, D'Amore A, and Wagner WR

Subjects
Tissue Engineering methods, Tissue Scaffolds, Heart Valves, Polyesters, Polymers, Pulmonary Valve
Abstract

There is still much unknown about the fluid mechanical response to cardiac valve scaffolds, even as their implementation in the clinic is on the horizon. Specifically, while degradable polymer valve scaffolds are currently being tested in the pulmonary valve position, their material and mechanical properties have not been fully elucidated. Optimizing these properties are important determinants not only of acute function, but long-term remodeling prospects. This study aimed to characterize fluid profiles downstream of electrospun valve scaffolds under dynamic pulmonary conditions. Valve scaffold design was changed by either blending poly(carbonate urethane) urea (PCUU) with poly(ε-caprolactone) (PCL) to modulate material stiffness or by changing the geometric design of the valve scaffolds. Specifically, two designs were utilized: one modeled after a clinically used bioprosthetic valve design (termed Mk1 design), and another using a geometrically "optimized" design (termed Mk2) based on anatomical data. Particle image velocimetry results showed that material stiffness only had a mild impact on fluid mechanics, measured by velocity magnitude, vorticity, viscous shear stress, Reynolds shear stress, and turbulent kinetic energy. However, comparing the two geometric designs yielded a much greater impact, with the Mk2 valve groups containing the highest PCUU/PCL ratio demonstrating the overall best performance. This report highlights the easily manipulable design features of polymeric valve scaffolds and demonstrates their relative significance for valve function., (© 2023. The Author(s) under exclusive licence to Biomedical Engineering Society.)

Published
2024
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28. Shape-recovery of implanted shape-memory devices remotely triggered via image-guided ultrasound heating.

Author

Zhu Y, Deng K, Zhou J, Lai C, Ma Z, Zhang H, Pan J, Shen L, Bucknor MD, Ozhinsky E, Kim S, Chen G, Ye SH, Zhang Y, Liu D, Gao C, Xu Y, Wang H, and Wagner WR

Subjects
Animals, Dogs, Heating, Magnetic Resonance Imaging methods, Urea, Polyurethanes, High-Intensity Focused Ultrasound Ablation methods
Abstract

Shape-memory materials hold great potential to impart medical devices with functionalities useful during implantation, locomotion, drug delivery, and removal. However, their clinical translation is limited by a lack of non-invasive and precise methods to trigger and control the shape recovery, especially for devices implanted in deep tissues. In this study, the application of image-guided high-intensity focused ultrasound (HIFU) heating is tested. Magnetic resonance-guided HIFU triggered shape-recovery of a device made of polyurethane urea while monitoring its temperature by magnetic resonance thermometry. Deformation of the polyurethane urea in a live canine bladder (5 cm deep) is achieved with 8 seconds of ultrasound-guided HIFU with millimeter resolution energy focus. Tissue sections show no hyperthermic tissue injury. A conceptual application in ureteral stent shape-recovery reduces removal resistance. In conclusion, image-guided HIFU demonstrates deep energy penetration, safety and speed., (© 2024. The Author(s).)

Published
2024
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29. Tissue formation and host remodeling of an elastomeric biodegradable scaffold in an ovine pulmonary leaflet replacement model.

Author

Machaidze Z, D'Amore A, Freitas RCC, Joyce AJ, Bayoumi A, Rich K, Brown DW, Aikawa E, Wagner WR, Rego BV, and Mayer JE Jr

Subjects
Animals, Sheep, Endothelial Cells, Tissue Scaffolds chemistry, Biocompatible Materials, Polymers, Polyesters, Tissue Engineering methods, Pulmonary Valve, Heart Valve Prosthesis
Abstract

In pursuit of a suitable scaffold material for cardiac valve tissue engineering applications, an acellular, electrospun, biodegradable polyester carbonate urethane urea (PECUU) scaffold was evaluated as a pulmonary valve leaflet replacement in vivo. In sheep (n = 8), a single pulmonary valve leaflet was replaced with a PECUU leaflet and followed for 1, 6, and 12 weeks. Implanted leaflet function was assessed in vivo by echocardiography. Explanted samples were studied for gross pathology, microscopic changes in the extracellular matrix, host cellular re-population, and immune responses, and for biomechanical properties. PECUU leaflets showed normal leaflet motion at implant, but decreased leaflet motion and dimensions at 6 weeks. The leaflets accumulated α-SMA and CD45 positive cells, with surfaces covered with endothelial cells (CD31+). New collagen formation occurred (Picrosirius Red). Accumulated tissue thickness correlated with the decrease in leaflet motion. The PECUU scaffolds had histologic evidence of scaffold degradation and an accumulation of pro-inflammatory/M1 and anti-inflammatory/M2 macrophages over time in vivo. The extent of inflammatory cell accumulation correlated with tissue formation and polymer degradation but was also associated with leaflet thickening and decreased leaflet motion. Future studies should explore pre-implant seeding of polymer scaffolds, more advanced polymer fabrication methods able to more closely approximate native tissue structure and function, and other techniques to control and balance the degradation of biomaterials and new tissue formation by modulation of the host immune response., (© 2023 Wiley Periodicals LLC.)

Published
2024
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30. Nerve Wrap for Local Delivery of FK506/Tacrolimus Accelerates Nerve Regeneration.

Author

Xiao B, Feturi F, Su AA, Van der Merwe Y, Barnett JM, Jabbari K, Khatter NJ, Li B, Katzel EB, Venkataramanan R, Solari MG, Wagner WR, Steketee MB, Simons DJ, and Washington KM

Subjects
Animals, Rats, Neurons, Urethane, Nerve Regeneration, Amides, Carbamates, Urea, Esters, Tacrolimus pharmacology, Myelin Sheath
Abstract

Peripheral nerve injuries (PNIs) occur frequently and can lead to devastating and permanent sensory and motor function disabilities. Systemic tacrolimus (FK506) administration has been shown to hasten recovery and improve functional outcomes after PNI repair. Unfortunately, high systemic levels of FK506 can result in adverse side effects. The localized administration of FK506 could provide the neuroregenerative benefits of FK506 while avoiding systemic, off-target side effects. This study investigates the utility of a novel FK506-impregnated polyester urethane urea (PEUU) nerve wrap to treat PNI in a previously validated rat infraorbital nerve (ION) transection and repair model. ION function was assessed by microelectrode recordings of trigeminal ganglion cells responding to controlled vibrissae deflections in ION-transected and -repaired animals, with and without the nerve wrap. Peristimulus time histograms (PSTHs) having 1 ms bins were constructed from spike times of individual single units. Responses to stimulus onsets (ON responses) were calculated during a 20 ms period beginning 1 ms after deflection onset; this epoch captures the initial, transient phase of the whisker-evoked response. Compared to no-wrap controls, rats with PEUU-FK506 wraps functionally recovered earlier, displaying larger response magnitudes. With nerve wrap treatment, FK506 blood levels up to six weeks were measured nearly at the limit of quantification (LOQ ≥ 2.0 ng/mL); whereas the drug concentrations within the ION and muscle were much higher, demonstrating the local delivery of FK506 to treat PNI. An immunohistological assessment of ION showed increased myelin expression for animals assigned to neurorrhaphy with PEUU-FK506 treatment compared to untreated or systemic-FK506-treated animals, suggesting that improved PNI outcomes using PEUU-FK506 is mediated by the modulation of Schwann cell activity.

Published
2024
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31. Epoxy silane sulfobetaine block copolymers for simple, aqueous thromboresistant coating on ambulatory assist lung devices.

Author

Ye SH, Orizondo RA, De BN, Kim S, Frankowski BJ, Federspiel WJ, and Wagner WR

Subjects
Humans, Polymers, Lung, Water, Silanes, Blood Platelets
Abstract

Developing an ambulatory assist lung (AAL) for patients who need continuous extracorporeal membrane oxygenation has been associated with several design objectives, including the design of compact components, optimization of gas transfer efficiency, and reduced thrombogenicity. In an effort to address thrombogenicity concerns with currently utilized component biomaterials, a low molecular weight water soluble siloxane-functionalized zwitterionic sulfobetaine (SB-Si) block copolymer was coated on a full-scale AAL device set via a one pot aqueous circulation coating. All device parts including hollow fiber bundle, housing, tubing and cannular were successfully coated with increasing atomic compositions of the SB block copolymer and the coated surfaces showed a significant reduction of platelet deposition while gas exchange performance was sustained. However, water solubility of the SB-Si was unstable, and the coating method, including oxygen plasma pretreatment on the surfaces were considered inconsistent with the objective of developing a simple aqueous coating. Addressing these weaknesses, SB block copolymers were synthesized bearing epoxy or epoxy-silane groups with improved water solubility (SB-EP & SB-EP-Si) and no requirement for surface pretreatment (SB-EP-Si). An SB-EP-Si triblock copolymer showed the most robust coating capacity and stability without prior pretreatment to represent a simple aqueous circulation coating on an assembled full-scale AAL device., (© 2023 Wiley Periodicals LLC.)

Published
2024
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32. Creating and Transferring an Innervated, Vascularized Muscle Flap Made from an Elastic, Cellularized Tissue Construct Developed In Situ.

Author

Sato H, Kohyama K, Uchibori T, Takanari K, Huard J, Badylak SF, D'Amore A, and Wagner WR

Subjects
Rats, Animals, Extracellular Matrix, Surgical Flaps blood supply, Surgical Flaps innervation, Muscles
Abstract

Reanimating facial structures following paralysis and muscle loss is a surgical objective that would benefit from improved options for harvesting appropriately sized muscle flaps. The objective of this study is to apply electrohydrodynamic processing to generate a cellularized, elastic, biocomposite scaffold that could develop and mature as muscle in a prepared donor site in vivo, and then be transferred as a thin muscle flap with a vascular and neural pedicle. First, an effective extracellular matrix (ECM) gel type is selected for the biocomposite scaffold from three types of ECM combined with poly(ester urethane)urea microfibers and evaluated in rat abdominal wall defects. Next, two types of precursor cells (muscle-derived and adipose-derived) are compared in constructs placed in rat hind limb defects for muscle regeneration capacity. Finally, with a construct made from dermal ECM and muscle-derived stem cells, protoflaps are implanted in one hindlimb for development and then microsurgically transferred as a free flap to the contralateral limb where stimulated muscle function is confirmed. This construct generation and in vivo incubation procedure may allow the generation of small-scale muscle flaps appropriate for transfer to the face, offering a new strategy for facial reanimation., (© 2023 Wiley-VCH GmbH.)

Published
2023
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33. Cardiac valve scaffold design: Implications of material properties and geometric configuration on performance and mechanics.

Author

Pedersen DD, Kim S, D'Amore A, and Wagner WR

Subjects
Aortic Valve, Tissue Scaffolds, Polymers, Catheters, Tissue Engineering methods, Heart Valve Prosthesis
Abstract

Development of tissue engineered scaffolds for cardiac valve replacement is nearing clinical translation. While much work has been done to characterize mechanical behavior of native and bioprosthetic valves, and incorporate those data into models improving valve design, similar work for degradable valve scaffolds is lacking. This is particularly important given the implications mechanics have on short-term survival and long-term remodeling. As such, this study aimed to characterize spatially-resolved strain profiles on the leaflets of degradable polymeric valve scaffolds, manipulating common design features such as material stiffness by blending poly(carbonate urethane)urea with stiffer polymers, and geometric configuration, modeled after either a clinically-used valve design (Mk1 design) or an anatomically "optimized" design (Mk2 design). It was shown that material stiffness plays a significant role in overall valve performance, with the stiffest valve groups showing asymmetric and incomplete opening during systole. However, the geometric configuration had a significantly greater effect on valve performance as well as strain magnitude and distribution. Major findings in the strain maps included systolic strains having overall higher strain magnitudes than diastole, and peak radial-direction strain concentrations in the base region of Mk1 valves during systole, with a significant mitigation of radial strain in Mk2 valves. The high tunability of tissue engineered scaffolds is a great advantage for valve design, and the results reported here indicate that design parameters have significant and unequal impact on valve performance and mechanics., Competing Interests: Declaration of competing interest The authors declare the following financial interests/personal relationships which may be considered as potential competing interests: W.R. Wagner, A. D'Amore are inventors on patent #US11129711B2 issued to RiMED Foundation and University of Pittsburgh and licensed to Neoolife, Inc. W.R. Wagner reports a relationship with Neoolife that includes: equity or stocks. A. D'Amore reports a relationship with Neoolife that includes: equity or stocks, chief technical officer, board member., (Copyright © 2023 Elsevier Ltd. All rights reserved.)

Published
2023
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34. Polyester urethane urea (PEUU) functionalization for enhanced anti-thrombotic performance: advancing regenerative cardiovascular devices through innovative surface modifications.

Author

Rodríguez-Soto MA, Suárez Vargas N, Ayala-Velásquez M, Aragón-Rivera AM, Ostos C, Cruz JC, Muñoz Camargo C, Kim S, D'Amore A, Wagner WR, and Briceño JC

Abstract

Introduction: Thrombogenesis, a major cause of implantable cardiovascular device failure, can be addressed through the use of biodegradable polymers modified with anticoagulating moieties. This study introduces a novel polyester urethane urea (PEUU) functionalized with various anti-platelet deposition molecules for enhanced antiplatelet performance in regenerative cardiovascular devices. Methods: PEUU, synthesized from poly-caprolactone, 1,4-diisocyanatobutane, and putrescine, was chemically oxidized to introduce carboxyl groups, creating PEUU-COOH. This polymer was functionalized in situ with polyethyleneimine, 4-arm polyethylene glycol, seleno-L-cystine, heparin sodium, and fondaparinux. Functionalization was confirmed using Fourier-transformed infrared spectroscopy and X-ray photoelectron spectroscopy. Bio-compatibility and hemocompatibility were validated through metabolic activity and hemolysis assays. The anti-thrombotic activity was assessed using platelet aggregation, lactate dehydrogenase activation assays, and scanning electron microscopy surface imaging. The whole-blood clotting time quantification assay was employed to evaluate anticoagulation properties. Results: Results demonstrated high biocompatibility and hemocompatibility, with the most potent anti-thrombotic activity observed on pegylated surfaces. However, seleno-L-cystine and fondaparinux exhibited no anti-platelet activity. Discussion: The findings highlight the importance of balancing various factors and addressing challenges associated with different approaches when developing innovative surface modifications for cardiovascular devices., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest. The authors declared that they were an editorial board member of Frontiers, at the time of submission. This had no impact on the peer review process and the final decision., (Copyright © 2023 Rodríguez-Soto, Suárez Vargas, Ayala-Velásquez, Aragón-Rivera, Ostos, Cruz, Muñoz Camargo, Kim, D’Amore, Wagner and Briceño.)

Published
2023
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35. The Year 2022 in biomaterials research: A perspective from the editors of six leading journals.

Author

Stegemann JP, Wagner WR, Göbel U, Perets E, Leong KW, Leach JK, and Gilbert J

Subjects
Biocompatible Materials, Tissue Engineering methods, Proteins, Printing, Three-Dimensional, Periodicals as Topic, Bioprinting
Abstract

The field of biomaterials science is highly active, with a steadily increasing number of publications and new journals being founded. This article brings together contributions from the editors of six leading journals in the area of biomaterials science and engineering. Each contributor highlights specific advances, topics, and trends that have emerged through the publications in their respective journal in the calendar year 2022. It presents a global perspective on a wide range of material types, functionalities, and applications. The highlighted topics include a diversity of biomaterials; from proteins, polysaccharides, and lipids to ceramics, metals, advanced composites, and a variety of new forms of these materials. Important advances in dynamically functional materials are presented, including a range of fabrication techniques such as bioassembly, 3D bioprinting and microgel formation. Similarly, several applications are highlighted in drug and gene delivery, biological sensing, cell guidance, immunoengineering, electroconductivity, wound healing, infection resistance, tissue engineering, and treatment of cancer. The goal of this paper is to provide the reader with both a broad view of recent biomaterials research, as well as expert commentary on some of the key advances that will shape the future of biomaterials science and engineering., (© 2023 Wiley Periodicals LLC.)

Published
2023
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36. In vitro and in vivo assessment of a novel ultra-flexible ventriculoamniotic shunt for treating fetal hydrocephalus.

Author

Emery SP, Greene S, Elsisy M, Chung K, Ye SH, Kim S, Wagner WR, Hazen N, and Chun Y

Subjects
Humans, Animals, Sheep, Pregnancy, Female, Quality of Life, Cerebrospinal Fluid Shunts methods, Cesarean Section, Hydrocephalus surgery
Abstract

Fetal aqueductal stenosis (AS) is one of the most common causes of congenital hydrocephalus, which increases intracranial pressure due to partial or complete obstruction of cerebrospinal fluid (CSF) flow within the ventricular system. Approximately 2-4 infants per 10,000 births develop AS, which leads to progressive hydrocephalus, which enlarges the head often necessitating delivery by cesarean section. Most babies born with AS are severely neurologically impaired and experience a lifetime of disability. Therefore, a new device technology for venticuloamniotic shunting is urgently needed and has been studied to ameliorate or prevent fetal hydrocephalus development, which can provide a significant impact on patients and their family's quality of life and on the decrease of the healthcare dollars spent for the treatment. This study has successfully validated the design of shunt devices and demonstrated the mechanical performance and valve functions. A functional prototype shunt has been fabricated and subsequently used in multiple in vitro tests to demonstrate the performance of this newly developed ventriculoamniotic shunt. The shunt contains a main silicone-nitinol composite tube, a superelastic 90° angled dual dumbbell anchor, and an ePTFE valve encased by a stainless-steel cage. The anchor will change its diameter from 1.15 mm (collapsed state) to 2.75 mm (deployed state) showing up to 1.4-fold diameter change in human body temperature. Flow rates in shunts were quantified to demonstrate the valve function in low flow rates mimicking the fetal hydrocephalus condition showing "no backflow" for the valved shunt while there is up to 15 mL/h flow through the shunt with pressure difference of 20 Pa. In vivo ovine study results show the initial successful device delivery and flow drainage with sheep model.

Published
2023
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37. Mechanical alterations of electrospun poly(ϵ-caprolactone) in response to convective thermobonding.

Author

Behrangzade A, Keeney HR, Martinet KM, Wagner WR, and Vande Geest JP

Subjects
Polyesters chemistry, Blood Vessel Prosthesis, Tissue Scaffolds chemistry, Tissue Engineering methods
Abstract

Vascular graft failure has persisted as a major clinical problem. Mechanical, structural, and transport properties of vascular grafts are critical factors that substantially affect their function and thus the outcome of implantation. The manufacturing method, post-processing technique, and material of choice have a significant impact on these properties. The goal of this work is to use thermal treatment to modulate the transport properties of PCL-based vascular engineered constructs. To this end, we electrospun PCL tubular constructs and thermally bonded the electrospun fibers in a convective oven at various temperatures (54, 57, and 60°C) and durations of treatment (15, 30, and 45 s). The effects of fiber thermal bonding (thermobonding) on the transport, mechanical, and structural properties of PCL tubular constructs were characterized. Increasing the temperature and treatment duration enhanced the degree of thermobonding by removing the interconnected void and fusing the fibers. Thermobonding at 57°C and 60°C for longer than 30 s increased the median tangential modulus (E = 126.1 MPa, [IQR = 20.7]), mean suture retention (F = 193.8 g, [SD = 18.5]), and degradation rate while it decreased the median permeability (k A  = 0 m/s), and median thickness (t = 60 μm, [IQR = 2.5]). In particular, the thermobonding at 57°C allowed a finer modulation of permeability via treatment duration. We believe that the thermobonding method can be utilized to modulate the properties of vascular engineered constructs which can be useful in designing functional vascular grafts., (© 2022 Wiley Periodicals LLC.)

Published
2023
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38. Optimizing the Porohyperelastic Response of a Layered Compliance Matched Vascular Graft to Promote Luminal Self-Cleaning.

Author

Behrangzade A, Simon BR, Wagner WR, and Geest JPV

Subjects
Animals, Arteries, Blood Vessel Prosthesis, Compliance, Rats, Models, Cardiovascular, Vascular Grafting
Abstract

Thrombosis and intimal hyperplasia have remained the major failure mechanisms of small-diameter vascular grafts used in bypass procedures. While most efforts to reduce thrombogenicity have used a biochemical surface modification approach, the use of local mechanical phenomena to aid in this goal has received somewhat less attention. In this work, the mechanical, fluid transport, and geometrical properties of a layered and porous vascular graft are optimized within a porohyperelastic finite element framework to maximize self-cleaning via luminal reversal fluid velocity (into the lumen). This is expected to repel platelets as well as inhibit the formation of and/or destabilize adsorbed protein layers thereby reducing thrombogenic potential. A particle swarm optimization algorithm was utilized to maximize luminal reversal fluid velocity while also compliance matching our graft to a target artery (rat aorta). The maximum achievable luminal reversal fluid velocity was approximately 246 μm/s without simultaneously optimizing for host compliance. Simultaneous optimization of reversal flow and compliance resulted in a luminal reversal fluid velocity of 59 μm/s. Results indicate that a thick highly permeable compressible inner layer and a thin low permeability incompressible outer layer promote intraluminal reversal fluid velocity. Future research is needed to determine the feasibility of fabricating such a layered and optimized graft and verify its ability to improve hemocompatibility., (Copyright © 2023 by ASME.)

Published
2023
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39. Bioabsorbable, elastomer-coated magnesium alloy coils for treating saccular cerebrovascular aneurysms.

Author

Kim S, Nowicki KW, Ye S, Jang K, Elsisy M, Ibrahim M, Chun Y, Gross BA, Friedlander RM, and Wagner WR

Subjects
Rats, Animals, Cerebral Angiography, Platinum, Alloys, Absorbable Implants, Elastomers, Amides, Treatment Outcome, Magnesium, Intracranial Aneurysm therapy
Abstract

Cerebral aneurysm embolization is a therapeutic approach to prevent rupture and resultant clinical sequelae. Current, non-biodegradable metallic coils (platinum or tungsten) are the first-line choice to secure cerebral aneurysms. However, clinical studies report that up to 17% of aneurysms recur within 1 year after coiling, leading to retreatment and additional surgery. It would be ideal for the aneurysm coiling material to induce acute thrombotic occlusion, contribute to a tissue development process to fortify the degenerated vessel wall, and ultimately resorb to avoid leaving a permanent foreign body. With these properties in mind, a new fatty amide-based polyurethane urea (PHEUU) elastomer was synthesized and coated on biodegradable metallic (Mg alloy) coils to prepare a bioabsorbable cerebral saccular aneurysm embolization device. The chemical structure of PHEUU was confirmed using two-dimensional nuclear magnetic resonance spectroscopy. PHEUU showed comparable physical properties to elastomeric biodegradable polyurethanes lacking fatty amide immobilization, modest enzymatic degradation profiles in the first 8 wks, inherent antioxidant activity (>70% at 48 h), no cytotoxicity, and better protection for the underlying Mg alloy than poly(lactic-co-glycolic acid) (PLGA) against surface corrosion and cracking. Rat aortic smooth muscle cell attachment and platelet deposition were higher with the PHEUUs compared to bare or PLGA coated Mg alloy in vitro. PHEUU-coated Mg alloy coils showed the potential to design a fully bioabsorbable embolization coil amenable to clinical placement conditions based on computational mechanics modeling and blood-contacting test using an in vitro aneurysm model. In vivo studies using a mouse aneurysm model elicited comparable inflammatory cytokine expression to a commercially available platinum coil., Competing Interests: Declaration of competing interest The authors declare the following financial interests/personal relationships which may be considered as potential competing interests: William R Wagner reports financial support was provided by National Science Foundation. William R Wagner has patent BIOABSORBABLE METALLIC ALLOY COILS COATED WITH A POLYURETHANE FOR TREATING INTRACRANIAL ANEURYSMS (IAs) AND RENAL ARTERY ANEURYSMS (RAAs) pending to University of Pittsburgh., (Copyright © 2022 Elsevier Ltd. All rights reserved.)

Published
2022
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40. Fully implantable batteryless soft platforms with printed nanomaterial-based arterial stiffness sensors for wireless continuous monitoring of restenosis in real time.

Author

Herbert R, Elsisy M, Rigo B, Lim HR, Kim H, Choi C, Kim S, Ye SH, Wagner WR, Chun Y, and Yeo WH

Abstract

Atherosclerosis is a common cause of coronary artery disease and a significant factor in broader cardiovascular diseases, the leading cause of death. While implantation of a stent is a prevalent treatment of coronary artery disease, a frequent complication is restenosis, where the stented artery narrows and stiffens. Although early detection of restenosis can be achieved by continuous monitoring, no available device offers such capability without surgeries. Here, we report a fully implantable soft electronic system without batteries and circuits, which still enables continuous wireless monitoring of restenosis in real-time with a set of nanomembrane strain sensors in an electronic stent. The low-profile system requires minimal invasive implantation to deploy the sensors into a blood vessel through catheterization. The entirely printed, nanomaterial-based set of soft membrane strain sensors utilizes a sliding mechanism to offer enhanced sensitivity and detection of low strain while unobtrusively integrating with an inductive stent for passive wireless sensing. The performance of the soft sensor platform is demonstrated by wireless monitoring of restenosis in an artery model and an ex-vivo study in a coronary artery of ovine hearts. The capacitive sensor-based artery implantation system offers unique advantages in wireless, real-time monitoring of stent treatments and arterial health for cardiovascular disease.

Published
2022
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41. Biodegradable polyurethane scaffolds in regenerative medicine: Clinical translation review.

Author

Pedersen DD, Kim S, and Wagner WR

Subjects
Biocompatible Materials, Humans, Regenerative Medicine, Suppuration, Tissue Engineering, Polyurethanes, Tissue Scaffolds
Abstract

Early explorations of tissue engineering and regenerative medicine concepts commonly utilized simple polyesters such as polyglycolide, polylactide, and their copolymers as scaffolds. These biomaterials were deemed clinically acceptable, readily accessible, and provided processability and a generally known biological response. With experience and refinement of approaches, greater control of material properties and integrated bioactivity has received emphasis and a broadened palette of synthetic biomaterials has been employed. Biodegradable polyurethanes (PUs) have emerged as an attractive option for synthetic scaffolds in a variety of tissue applications because of their flexibility in molecular design and ability to fulfill mechanical property objectives, particularly in soft tissue applications. Biodegradable PUs are highly customizable based on their composition and processability to impart tailored mechanical and degradation behavior. Additionally, bioactive agents can be readily incorporated into these scaffolds to drive a desired biological response. Enthusiasm for biodegradable PU scaffolds has soared in recent years, leading to rapid growth in the literature documenting novel PU chemistries, scaffold designs, mechanical properties, and aspects of biocompatibility. Despite the enthusiasm in the field, there are still few examples of biodegradable PU scaffolds that have achieved regulatory approval and routine clinical use. However, there is a growing literature where biodegradable PU scaffolds are being specifically developed for a wide range of pathologies and where relevant pre-clinical models are being employed. The purpose of this review is first to highlight examples of clinically used biodegradable PU scaffolds, and then to summarize the growing body of reports on pre-clinical applications of biodegradable PU scaffolds., (© 2022 Wiley Periodicals LLC.)

Published
2022
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42. Acute Elution of TGFβ2 Affects the Smooth Muscle Cells in a Compliance-Matched Vascular Graft.

Author

Furdella KJ, Higuchi S, Kim K, Doetschman T, Wagner WR, and Vande Geest JP

Subjects
Animals, Collagen metabolism, Rats, Rats, Sprague-Dawley, Blood Vessel Prosthesis, Myocytes, Smooth Muscle drug effects, Myocytes, Smooth Muscle metabolism, Transforming Growth Factor beta2 administration & dosage, Transforming Growth Factor beta2 pharmacology
Abstract

Transforming growth factor beta 2 (TGFβ2) is a pleiotropic growth factor that plays a vital role in smooth muscle cell (SMC) function. Our prior in vitro work has shown that SMC response can be modulated with TGFβ2 stimulation in a dose dependent manner. In particular, we have shown that increasing concentrations of TGFβ2 shift SMCs from a migratory to a synthetic behavior. In this work, electrospun compliance-matched and hypocompliant TGFβ2-eluting tissue engineered vascular grafts (TEVGs) were implanted into Sprague Dawley rats for 5 days to observe SMC population and collagen production. TEVGs were fabricated using a combined computational and experimental approach that varied the ratio of gelatin:polycaprolactone to be either compliance matched or twice as stiff as rat aorta (hypocompliant). TGFβ2 concentrations of 0, 10, 100 ng/mg were added to both graft types ( n  = 3 in each group) and imaged in vivo using ultrasound. Histological markers (SMC, macrophage, collagen, and elastin) were evaluated following explanation at 5 days. In vivo ultrasound showed that compliance-matched TEVGs became stiffer as TGFβ2 increased (100 ng/mg TEVGs compared to rat aorta, p  < 0.01), while all hypocompliant grafts remained stiffer than control rat aorta. In vivo velocity and diameter were also not significantly different than control vessels. The compliance-matched 10 ng/mg group had an elevated SMC signal (myosin heavy chain) compared to the 0 and 100 ng/mg grafts ( p  = 0.0009 and 0.0006). Compliance-matched TEVGs containing 100 ng/mg TGFβ2 had an increase in collagen production ( p  < 0.01), general immune response ( p  < 0.05), and a decrease in SMC population to the 0 and 10 ng/mg groups. All hypocompliant groups were found to be similar, suggesting a lower rate of TGFβ2 release in these TEVGs. Our results suggest that TGFβ2 can modulate in vivo SMC phenotype over an acute implantation period, which is consistent with our prior in vitro work. To the author's knowledge, this is the first in vivo rat study that evaluates a TGFβ2-eluting TEVG. Impact statement TGFβ2 affects the SMCs in a vascular graft.

Published
2022
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43. Continuous Microfiber Wire Mandrel-Less Biofabrication for Soft Tissue Engineering Applications.

Author

Adamo A, Bartolacci JG, Pedersen DD, Traina MG, Kim S, Pantano A, Ghersi G, Watkins SC, Wagner WR, Badylak SF, and D'Amore A

Subjects
Animals, Rats, Tendons, Tensile Strength, Wound Healing, Sutures, Tissue Engineering methods
Abstract

Suture materials are the most common bioimplants in surgical and clinical practice, playing a crucial role in wound healing and tendon and ligament repair. Despite the assortment available on the market, sutures are still affected by significant disadvantages, including failure in mimicking the mechanical properties of the tissue, excessive fibrosis, and inflammation. This study introduces a mandrel-less electrodeposition apparatus to fabricate continuous microfiber wires of indefinite length. The mandrel-less biofabrication produces wires, potentially used as medical fibers, with different microfiber bundles, that imitate the hierarchical organization of native tissues, and tailored mechanical properties. Microfiber wire morphology and mechanical properties are characterized by scanning electron microscopy, digital image processing, and uniaxial tensile test. Wires are tested in vitro on monocyte/macrophage stimulation and in vivo on a rat surgical wound model. The wires produced by mandrel-less deposition show an increased M2 macrophage phenotype in vitro. The in vivo assessment demonstrates that microfiber wires, compared to the medical fibers currently used, reduce pro-inflammatory macrophage response and preserve their mechanical properties after 30 days of use. These results make this microfiber wire an ideal candidate as a suture material for soft tissue surgery, suggesting a crucial role of microarchitecture in more favorable host response., (© 2022 The Authors. Advanced Healthcare Materials published by Wiley-VCH GmbH.)

Published
2022
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44. Pro-angiogenic Potential of Mesenchymal Stromal Cells Regulated by Matrix Stiffness and Anisotropy Mimicking Right Ventricles.

Author

Nguyen-Truong M, Kim S, Doherty C, Frederes M, LeBar K, Ghosh S, Hematti P, Chinnadurai R, Wagner WR, and Wang Z

Subjects
Anisotropy, Heart Ventricles metabolism, Mesenchymal Stem Cells metabolism, Vascular Endothelial Growth Factor A metabolism
Abstract

Capillary rarefaction is a hallmark of right ventricle (RV) failure. Mesenchymal stromal cell (MSC)-based therapy offers a potential treatment due to its pro-angiogenic function. However, the impact of RV tissue mechanics on MSC behavior is unclear, especially when referring to RV end-diastolic stiffness and mechanical anisotropy. In this study, we assessed MSC behavior on electrospun scaffolds with varied stiffness (normal vs failing RV) and anisotropy (isotropic vs anisotropic). In individual MSCs, we observed the highest vascular endothelial growth factor (VEGF) production and total tube length in the failing, isotropic group (2.00 ± 0.37, 1.53 ± 0.24), which was greater than the normal, isotropic group (0.70 ± 0.15, 0.55 ± 0.07; p < 0.05). The presence of anisotropy led to trends of increased VEGF production on normal groups (0.75 ± 0.09 vs 1.20 ± 0.17), but this effect was absent on failing groups. Our findings reveal synergistic effects of RV-like stiffness and anisotropy on MSC pro-angiogenic function and may guide MSC-based therapies for heart failure.

Published
2022
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45. Blood Vessel Detection Algorithm for Tissue Engineering and Quantitative Histology.

Author

Adamo A, Bruno A, Menallo G, Francipane MG, Fazzari M, Pirrone R, Ardizzone E, Wagner WR, and D'Amore A

Subjects
Humans, Image Processing, Computer-Assisted methods, Immunohistochemistry, Neovascularization, Pathologic, Algorithms, Tissue Engineering
Abstract

Immunohistochemistry for vascular network analysis plays a fundamental role in basic science, translational research and clinical practice. However, identifying vascularization in histological tissue images is time consuming and markedly depends on the operator's experience. In this study, we present "blood vessel detection-BVD", an automatic algorithm for quantitative analysis of blood vessels in immunohistochemical images. BVD is based on extraction and analysis of low-level image features and spatial filtering techniques, which do not require a training phase. BVD algorithm performance was comparatively evaluated on histological sections from three different in vivo experiments. Collectively, 173 independent images were analyzed, and the algorithm's results were compared to those obtained by human operators. The developed BVD algorithm proved to be a robust and versatile tool, being able to quantify number, area, and spatial distribution of blood vessels within all three considered histologic datasets. BVD is provided as an open-source application working on different operating systems. BVD is supported by a user-friendly graphical interface designed to facilitate large-scale analysis., (© 2022. The Author(s).)

Published
2022
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46. Adipose-derived stem cell sheet under an elastic patch improves cardiac function in rats after myocardial infarction.

Author

Kashiyama N, Kormos RL, Matsumura Y, D'Amore A, Miyagawa S, Sawa Y, and Wagner WR

Subjects
Animals, Cell Survival, Disease Models, Animal, Heart Ventricles metabolism, Hepatocyte Growth Factor metabolism, Neovascularization, Physiologic, Rats, Inbred F344, Stroke Volume, Rats, Absorbable Implants, Adipocytes cytology, Decellularized Extracellular Matrix, Myocardial Infarction surgery, Stem Cell Transplantation
Abstract

Objectives: Although adipose-derived stem cells (ADSCs) have shown promise in cardiac regeneration, stable engraftment is still challenging. Acellular bioengineered cardiac patches have shown promise in positively altering ventricular remodeling in ischemic cardiomyopathy. We hypothesized that combining an ADSC sheet approach with a bioengineered patch would enhance ADSC engraftment and positively promote cardiac function compared with either therapy alone in a rat ischemic cardiomyopathy model., Methods: Cardiac patches were generated from poly(ester carbonate urethane) urea and porcine decellularized cardiac extracellular matrix. ADSCs constitutively expressing green fluorescent protein were established from F344 rats and transplanted as a cell sheet over the left ventricle 3 days after left anterior descending artery ligation with or without an overlying cardiac patch. Cardiac function was serially evaluated using echocardiography for 8 weeks, comparing groups with combined cells and patch (group C, n = 9), ADSCs alone (group A, n = 7), patch alone (group P, n = 6) or sham groups (n = 7)., Results: Much greater numbers of ADSCs survived in the C versus A groups (P < .01). At 8 weeks posttransplant, the percentage fibrotic area was lower (P < .01) in groups C and P compared with the other groups and vasculature in the peri-infarct zone was greater in group C versus other groups (P < .01), and hepatocyte growth factor expression was higher in group C than in other groups (P < .05). Left ventricular ejection fraction was higher in group C versus other groups., Conclusions: A biodegradable cardiac patch enhanced ADSC engraftment, which was associated with greater cardiac function and neovascularization in the peri-infarct zone following subacute myocardial infarction., (Published by Elsevier Inc.)

Published
2022
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47. Engineering in-plane mechanics of electrospun polyurethane scaffolds for cardiovascular tissue applications.

Author

Luketich SK, Cosentino F, Di Giuseppe M, Menallo G, Nasello G, Livreri P, Wagner WR, and D'Amore A

Subjects
Biocompatible Materials chemistry, Polyesters chemistry, Tissue Engineering methods, Tissue Scaffolds chemistry, Cardiovascular System, Polyurethanes chemistry
Abstract

Effective cardiovascular tissue surrogates require high control of scaffold structural and mechanical features to match native tissue properties, which are dependent on tissue-specific mechanics, function heterogenicity, and morphology. Bridging scaffold processing variables with native tissue properties is recognized as a priority for advancing biomechanical performance of biomedical materials and, when translated to the clinical practice, their efficacy. Accordingly, this study selected electrospinning on a rotating cylindrical target as an apparatus of broad application and mapped the relationship between key processing variables and scaffold mechanics and structure. This information was combined with mechanical anisotropy ranges of interest for the three main categories of tissue surrogated in cardiovascular tissue engineering: heart valve leaflets, ventricle wall, and large diameter blood vessels. Specifically, three processing variables have been considered: the rotational velocity and the rastering velocity of the mandrel and the dry (single nozzle - polymer only) vs wet (double nozzle - polymer plus phosphate buffer saline solution) fabrication configuration. While the dry configuration is generally utilized to obtain micro-fiber based polymeric mats, the wet fabrication is representative of processing conditions utilized to incorporate cells, growth factors, or micro-particles within the fibrous scaffold matrix. Dry and wet processed electrospun mats were fabricated with tangential and rastering velocities within the 0.3-9.0 m/s and 0.16-8 cm/s range respectively. Biaxial mechanics, fiber network, and pore micro-architectures were measured for each combination of velocities and for each fabrication modality (dry and wet). Results allowed identification of the precise combination of rotational and rastering velocities, for both dry and wet conditions, that is able to recapitulate the native cardiovascular tissue anisotropy ratio. By adopting a simple and broadly utilized electrospinning layout, this study is meant to provide a repeatable and easy to access methodology to improve biomimicry of the in plane-mechanics of heart valve leaflets, ventricular wall, and large diameter blood vessels., (Copyright © 2022. Published by Elsevier Ltd.)

Published
2022
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48. PDMS-Zwitterionic Hybrid for Facile, Antifouling Microfluidic Device Fabrication.

Author

Mercader A, Ye SH, Kim S, Orizondo RA, Cho SK, and Wagner WR

Subjects
Animals, Cell Adhesion, Dimethylpolysiloxanes, Polymers, Printing, Sheep, Biofouling prevention & control, Lab-On-A-Chip Devices
Abstract

Poly(dimethylsiloxane) (PDMS) has been used in a wide range of biomedical devices and medical research due to its biostability, cytocompatibility, gas permeability, and optical properties. Yet, some properties of PDMS create critical limitations, particularly fouling through protein and cell adhesion. In this study, a diallyl-terminated sulfobetaine (SB-diallyl) molecule was synthesized and then directly mixed with a commercial PDMS base (Sylgard 184) and curing agent to produce a zwitterionic group-bearing PDMS (PDMS-SB) hybrid that does not require a complex or an additional surface modification process for the desired end product. In vitro examination of antifouling behavior following exposure to fresh ovine blood showed a significant reduction in platelet deposition for the PDMS-SB hybrid surface compared to that of a PDMS control ( p < 0.05, n = 5). The manufacturability via soft lithography using the synthesized polymers was found to be comparable to that for unmodified PDMS. Bonding via O 2 plasma treatment was confirmed, and the strength was measured and again found to be comparable to the control. PDMS-SB microfluidic devices were successfully fabricated and showed improved blood compatibility that could reduce channel occlusion due to clot formation relative to PDMS control devices. Further, gas (CO 2 ) transfer through a PDMS-SB hybrid membrane was also tested with a proof-of-concept microchannel device and shown to be comparable to that through the PDMS control.

Published
2022
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49. Biomanufacturing in low Earth orbit for regenerative medicine.

Author

Sharma A, Clemens RA, Garcia O, Taylor DL, Wagner NL, Shepard KA, Gupta A, Malany S, Grodzinsky AJ, Kearns-Jonker M, Mair DB, Kim DH, Roberts MS, Loring JF, Hu J, Warren LE, Eenmaa S, Bozada J, Paljug E, Roth M, Taylor DP, Rodrigue G, Cantini P, Smith AW, Giulianotti MA, and Wagner WR

Subjects
Artificial Intelligence, Automation, Bioengineering, Humans, Machine Learning, Research, Biocompatible Materials, Extraterrestrial Environment, Manufactured Materials, Regenerative Medicine
Abstract

Research in low Earth orbit (LEO) has become more accessible. The 2020 Biomanufacturing in Space Symposium reviewed space-based regenerative medicine research and discussed leveraging LEO to advance biomanufacturing for regenerative medicine applications. The symposium identified areas where financial investments could stimulate advancements overcoming technical barriers. Opportunities in disease modeling, stem-cell-derived products, and biofabrication were highlighted. The symposium will initiate a roadmap to a sustainable market for regenerative medicine biomanufacturing in space. This perspective summarizes the 2020 Biomanufacturing in Space Symposium, highlights key biomanufacturing opportunities in LEO, and lays the framework for a roadmap to regenerative medicine biomanufacturing in space., (Copyright © 2021 The Authors. Published by Elsevier Inc. All rights reserved.)

Published
2022
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50. Injectable hydrogels for vascular embolization and cell delivery: The potential for advances in cerebral aneurysm treatment.

Author

Kim S, Nowicki KW, Gross BA, and Wagner WR

Subjects
Humans, Hydrogels, Treatment Outcome, Aneurysm, Ruptured therapy, Embolization, Therapeutic, Intracranial Aneurysm therapy, Subarachnoid Hemorrhage
Abstract

Cerebral aneurysms are vascular lesions caused by the biomechanical failure of the vessel wall due to hemodynamic stress and inflammation. Aneurysmal rupture results in subarachnoid hemorrhage often leading to death or disability. Current treatment options include open surgery and minimally invasive endovascular options aimed at secluding the aneurysm from the circulation. Cerebral aneurysm embolization with appropriate materials is a therapeutic approach to prevent rupture and the resultant clinical sequelae. Metallic platinum coils are a typical, practical option to embolize cerebral aneurysms. However, the development of an alternative treatment modality is of interest because of poor occlusion permanence, coil migration, and coil compaction. Moreover, minimizing the implanted foreign materials during therapy is of importance not just to patients, but also to clinicians in the event an open surgical approach has to be pursued in the future. Polymeric injectable hydrogels have been investigated for transcatheter embolization and cell therapy with the potential for permanent aneurysm repair. This review focuses on how the combination of injectable embolic biomaterials and cell therapy may achieve minimally invasive remodeling of a degenerated cerebral artery with promise for superior outcomes in treatment of this devastating disease., (Copyright © 2021. Published by Elsevier Ltd.)

Published
2021
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