Showing total 36 results

1. Optically Active, Paper-Based Scaffolds for 3D Cardiac Pacing.

Author

Guo F, Jooken S, Ahmad A, Yu W, Deschaume O, Thielemans W, and Bartic C

Subjects

Quantum Dots chemistry, Animals, Mice, Cell Line, Nanocomposites chemistry, Tissue Engineering, Cellulose chemistry, Paper, Tissue Scaffolds chemistry, Gold chemistry, Myocytes, Cardiac cytology, Myocytes, Cardiac drug effects, Nanotubes chemistry

Abstract

In this work, we report the design and fabrication of a light-addressable, paper-based nanocomposite scaffold for optical pacing and read-out of in vitro grown cardiac tissue. The scaffold consists of paper cellulose microfibers functionalized with gold nanorods (GNRs) and semiconductor quantum dots (QDs), embedded in a cell-permissive collagen matrix. The GNRs enable cardiomyocyte activity modulation through local temperature gradients induced by modulated near-infrared (NIR) laser illumination, with the local temperature changes reported by temperature-dependent QD photoluminescence (PL). The micrometer-sized paper fibers promote the tubular organization of HL-1 cardiac muscle cells, while the NIR plasmonic stimulation modulates reversibly their activity. Given the nanoscale spatial resolution and facile fabrication, paper-based nanocomposite scaffolds with NIR modulation offer excellent alternatives to electrode-based or optogenetic methods for cell activity modulation, at the single cell level, and are compatible with 3D tissue constructs. Such paper-based optical platforms can provide new possibilities for the development of in vitro drug screening assays and heart disease modeling.

Published

2024

2. Fabrication of 3D engineered intestinal tissue producing abundant mucus by air-liquid interface culture using paper-based dual-layer scaffold.

Author

Nagasawa M, Onuki M, Imoto N, Tanaka K, Tanaka R, Kawada M, Imato K, Iitani K, Tsuchido Y, and Takeda N

Subjects

Humans, Caco-2 Cells, Intestines cytology, Intestines physiology, Intestinal Mucosa metabolism, Intestinal Mucosa cytology, Air, Cell Culture Techniques methods, Tissue Scaffolds chemistry, Tissue Engineering, Paper, Mucus metabolism

Abstract

Fabrication of engineered intestinal tissues with the structures and functions as humans is crucial and promising as the tools for developing drugs and functional foods. The aim of this study is to fabricate an engineered intestinal tissue from Caco-2 cells by air-liquid interface culture using a paper-based dual-layer scaffold and analyze its structure and functions. Just by simply placing on a folded paper soaked in the medium, the electrospun gelatin microfiber mesh as the upper cell adhesion layer of the dual-layer scaffold was exposed to the air, while the lower paper layer worked to preserve and supply the cell culture medium to achieve stable culture over several weeks. Unlike the flat tissue produced using the conventional commercial cultureware, Transwell, the engineered intestinal tissue fabricated in this study formed three-dimensional villous architectures. Microvilli and tight junction structures characteristic of epithelial tissue were also formed at the apical side. Furthermore, compared to the tissue prepared by Transwell, mucus production was significantly larger, and the enzymatic activities of drug metabolism and digestion were almost equivalent. In conclusion, the air-liquid interface culture using the paper-based dual-layer scaffold developed in this study was simple but effective in fabricating the engineered intestinal tissue with superior structures and functions., (© 2024 IOP Publishing Ltd.)

Published

2024

3. Unconventional strategies for liver tissue engineering: plant, paper, silk and nanomaterial-based scaffolds.

Author

Jain S and Sharma JG

Subjects

Humans, Animals, Paper, Plants metabolism, Hepatocytes cytology, Hepatocytes metabolism, Tissue Engineering methods, Tissue Scaffolds chemistry, Nanostructures chemistry, Liver cytology, Liver metabolism, Silk chemistry

Abstract

The paper highlights how significant characteristics of liver can be modeled in tissue-engineered constructs using unconventional scaffolds. Hepatic lobular organization and metabolic zonation can be mimicked with decellularized plant structures with vasculature resembling a native-hepatic lobule vascular arrangement or silk blend scaffolds meticulously designed for guided cellular arrangement as hepatic patches or metabolic activities. The functionality of hepatocytes can be enhanced and maintained for long periods in naturally fibrous structures paving way for bioartificial liver development. The phase I enzymatic activity in hepatic models can be raised exploiting the microfibrillar structure of paper to allow cellular stacking creating hypoxic conditions to induce in vivo -like xenobiotic metabolism. Lastly, the paper introduces amalgamation of carbon-based nanomaterials into existing scaffolds in liver tissue engineering.

Published

2024

4. Mineralized paper scaffolds for bone tissue engineering.

Author

Wu X, Walsh K, Suvarnapathaki S, Lantigua D, McCarthy C, and Camci-Unal G

Subjects

Animals, Male, Rats, Rats, Wistar, Bone and Bones metabolism, Osteogenesis, Paper, Tissue Engineering, Tissue Scaffolds chemistry

Abstract

Mineralized polymer scaffolds have proven to be effective biomaterials for inducing osteoinductivity in bone tissue engineering. Sequential mineralization is a promising technique for depositing minerals in three-dimensional (3D) scaffolds. Paper, which is made of cellulose fibers, can be used as a tissue scaffold due to its highly porous structure and flexibility, as well as its excellent ability to wick fluids and support the growth of bone cells. In this study, paper-based, mineralized scaffolds were fabricated using sequential mineralization. We conducted experiments with two groups of scaffolds based on different incubation times in the mineralization solutions (30 min and 24 h). Ten cycles of mineralization were performed for each group. We found that the mineral content increased as the cycle number increased and that the 24-h group scaffolds consistently had more mineralization than did the 30-min group scaffolds when measured at the same cycle number. A quantitative reverse transcription-polymerase chain reaction was performed for two osteogenic differentiation markers of the preosteoblasts that were grown on the mineralized paper scaffolds. The gene expression results for bone-specific markers revealed that the mineralized scaffolds were osteoinductive. Subcutaneous implantation of the scaffolds in rats demonstrated favorable biocompatibility, high vascularization, and non-immunogenicity in vivo. The overall results suggest that the sequentially mineralized paper scaffolds are promising materials for use in bone tissue engineering., (© 2020 Wiley Periodicals LLC.)

Published

2021

5. Preparation of Extracellular Matrix Paper and Construction of Multi-Layered 3D Tissue Model.

Author

Nakatsuji H, Kitano S, Irie S, and Matsusaki M

Subjects

Animals, Cells, Cultured, Humans, Models, Biological, Cell Movement, Extracellular Matrix chemistry, Tissue Engineering methods, Tissue Scaffolds chemistry

Abstract

Construction of organized three-dimensional (3D) tissue with extracellular matrix (ECM) and multiple types of cells is important for tissue engineering to enable tissue function and enhance cellular function. However, the concentration of ECM and the thickness of the 3D tissue have been limited in previous methods due to a lack of permeability to nutrients and oxygen. Besides, it is difficult to use matured natural ECM as a cell scaffold without chemical modification due to its insolubility. In this article, we focus on multi-layered structure, which is commonly found in living tissue such as skin, blood vessels, and other organs. Here, we describe the preparation of a paper-like scaffold (ECM paper) from micro-fibered natural ECM and the construction of 3D multi-layered tissue composed of cell layers and ECM layers by stacking cell-seeded ECM papers. The thickness and components of the ECM layers are easily controllable by changing the composition of the ECM papers, and the fibrous structure of ECM paper shows high permeability and permits cell migration. Additionally, the ECM microfiber, which is physically defiberized from natural ECM, has a high ECM concentration equal to that of living tissue and high stability under physiological conditions. Therefore, this set of protocols enables construction of multi-layered 3D tissue composed of precisely controlled ECM layers and cell layers that may contribute to the assembly of tissue models. © 2020 by John Wiley & Sons, Inc. Basic Protocol 1: Preparation of extracellular matrix paper Basic Protocol 2: Evaluation of cellular function of cells on extracellular matrix paper Basic Protocol 3: Construction of multi-layered 3D tissue., (© 2020 Wiley Periodicals LLC.)

Published

2020

6. Generation of Cost-Effective Paper-Based Tissue Models through Matrix-Assisted Sacrificial 3D Printing.

Author

Cheng F, Cao X, Li H, Liu T, Xie X, Huang D, Maharjan S, Bei HP, Gómez A, Li J, Zhan H, Shen H, Liu S, He J, and Zhang YS

Subjects

Cell Survival, Equipment Design, Human Umbilical Vein Endothelial Cells, Humans, MCF-7 Cells, Nanofibers chemistry, Paper, Tissue Engineering, Bioprinting instrumentation, Cellulose chemistry, Polysaccharides, Bacterial chemistry, Printing, Three-Dimensional instrumentation, Tissue Scaffolds chemistry

Abstract

Due to the combined advantages of cellulose and nanoscale (diameter 20-60 nm), bacterial cellulose possesses a series of attractive features including its natural origin, moderate biosynthesis process, good biocompatibility, and cost-effectiveness. Moreover, bacterial cellulose nanofibers can be conveniently processed into three-dimensional (3D) intertwined structures and form stable paper devices after simple drying. These advantages make it suitable as the material for construction of organ-on-a-chip devices using matrix-assisted sacrificial 3D printing. We successfully fabricated various microchannel structures embedded in the bulk bacterial cellulose hydrogels and retained their integrity after the drying process. Interestingly, these paper-based devices containing hollow microchannels could be rehydrated and populated with relevant cells to form vascularized tissue models. As a proof-of-concept demonstration, we seeded human umbilical vein endothelial cells (HUVECs) into the microchannels to obtain the vasculature and inoculated the MCF-7 cells onto the surrounding matrix of the paper device to build a 3D paper-based vascularized breast tumor model. The results showed that the microchannels were perfusable, and both HUVECs and MCF-7 cells exhibited favorable proliferation behaviors. This study may provide a new strategy for constructing simple and low-cost in vitro tissue models, which may find potential applications in drug screening and personalized medicine.

Published

2019

7. PAMAM dendrimer grafted cellulose paper scaffolds as a novel in vitro 3D liver model for drug screening applications.

Author

Agarwal T, Rustagi A, Das J, and Maiti TK

Subjects

Cell Adhesion, Cell Proliferation, Cell Survival, Hep G2 Cells, Humans, Cellulose chemistry, Dendrimers chemistry, Drug Evaluation, Preclinical, Imaging, Three-Dimensional, Liver physiology, Paper, Tissue Scaffolds chemistry

Abstract

Development of cheap and portable 3D liver models is a need of an hour for drug screening applications in the healthcare and diagnostic sector. An appropriate 3D liver model would support adhesion, proliferation, viability and functionality of the liver cells. With this perspective, the present study delineates the fabrication and characterization of PAMAM conjugated cellulose filter paper-based 3D liver model. Due to the absence of any cell adhesion motif, paper cannot directly be used for cell culture applications, thus, it was functionalized with PAMAM dendrimer using glutaraldehyde. PAMAM derivatized paper (PF) supported significantly higher adhesion, proliferation, and viability of the HepG2 cells in comparison to non-functionalized paper. Moreover, HepG2 cells maintained their functional aspects i.e., expression of mature hepatocyte markers albumin, CK19, CYP3 A4, MDR1 and SULT2 A1 on PF. Further, we showed the application of the PF-based 3D liver model for drug toxicity evaluations against hepatotoxins. The results showed a significantly higher sensitivity of the HepG2 cells in paper-based 3D culture as compared to 2D monolayer culture, which is similar to that of physiological drug-induced responses. In conclusion, PAMAM functionalized filter paper could serve as an efficient biomaterial platform for the development of microscale technologies, liver-associated diagnostics, and drug screening applications., (Copyright © 2018 Elsevier B.V. All rights reserved.)

Published

2018

8. Constructing an Anisotropic Triple-Pass Tubular Framework within a Lyophilized Porous Gelatin Scaffold Using Dexamethasone-Loaded Functionalized Whatman Paper To Reinforce Its Mechanical Strength and Promote Osteogenesis.

Author

Ran J, Zeng H, Pathak JL, Jiang P, Bai Y, Yan P, Sun G, Shen X, Tong H, and Shi B

Subjects

Animals, Anisotropy, Cell Differentiation drug effects, Dexamethasone chemistry, Gelatin chemistry, Humans, Materials Testing, Mechanical Phenomena, Paper, Porosity, Rats, Dexamethasone administration & dosage, Osteogenesis drug effects, Tissue Engineering, Tissue Scaffolds chemistry

Abstract

In bone tissue engineering (BTE), most of the currently developed scaffolds still lack the ability to demonstrate high porosity and high mechanical strength simultaneously or the ability to maintain bioactivity and sustained release of loaded biofactors. In this work, we constructed an anisotropic triple-pass tubular framework within a lyophilized porous GEL scaffold using FP, which was prepared by coating DEX-covered Whatman paper (WP) using the silk fibroin (SF) membrane with β-sheet conformation. This novel structural design endowed the functionalized paper frame (FPF)/scaffold implant high porosity, high mechanical strength, and sustained DEX delivery capability. Specifically, its porosity was as high as 88.2%, approximating that of human cancellous bone. The pore diameters of the implant ranged from 50 to 350 μm with an average pore diameter of 127.7 μm, indicating proper pore sizes for successful diffusion of essential nutrients/oxygen and bone tissue-ingrowth. Owing to the construction of double-network-like structure, the FPF/scaffold implant demonstrated excellent mechanical properties both in dry (174.7 MPa in elastic modulus and 14.9 MPa in compressive modulus) and wet states (59.0 MPa in elastic modulus and 3.3 MPa in compressive modulus), indicating its feasibility for in vivo implantation. Besides, the FPF/scaffold implant exhibited long-term DEX releasing behavior (over 50 days) with constant release rate in phosphate buffered saline (PBS). Murine osteoblasts MC3T3-E1 cultured in the porous FPF/scaffold implant had excellent viability. Furthermore, the cells cocultured with the FPF/scaffold implant showed positive proliferation, osteogenic differentiation, and calcium deposition. Twenty-eight days after implantation, extensive osteogenesis was observed in the rats treated with the FPF/scaffold implants. The anisotropic triple-pass tubular framework of the FPF/scaffold implant demonstrates structural similarities to the long bone. Therefore, this novel FPF/scaffold implant could be a better alternative for long bone defect repair.

Published

2017

9. Self-driven perfusion culture system using a paper-based double-layered scaffold.

Author

Ozaki A, Arisaka Y, and Takeda N

Subjects

Animals, Bioreactors, Cattle, Cell Adhesion, Cell Culture Techniques instrumentation, Cell Line, Cell Proliferation, Endothelial Cells cytology, Endothelial Cells metabolism, Gelatin chemistry, Microscopy, Electron, Scanning, Stress, Mechanical, Cell Culture Techniques methods, Paper, Tissue Scaffolds chemistry

Abstract

Shear stress caused by fluid flow is known to promote tissue development from cells in vivo. Therefore, perfusion cultures have been studied to investigate the mechanisms involved and to fabricate engineered tissues in vitro, particularly those that include blood vessels. Microfluidic devices, which function with fine machinery of chambers and microsyringes for fluid flow and have small culture areas, are conventionally used for perfusion culture. In contrast, we have developed a self-driven perfusion culture system by using a paper-based double-layered scaffold as the fundamental component. Gelatin microfibers were electrospun onto a paper material to prepare the scaffold system, in which the constant perfusion of the medium and the scaffold for cell adhesion/proliferation were functionally divided into a paper and a gelatin microfiber layer, respectively. By applying both the capillary action and siphon phenomenon of the paper-based scaffold, which bridged two medium chambers at different height levels, a self-driven medium flow was achieved and the flow rate was also stable, constant, and quantitatively controllable. Moreover, the culture area was enlargeable to the cm(2) scale. The endothelial cells cultivated on this system oriented along the medium-flow direction, suggesting that the shear stress caused by medium flow was effectively applied. This perfusion culture system is expected to be useful for fabricating three-dimensional and large engineered tissues in the future.

Published

2016

10. Biomineralization Guided by Paper Templates.

Author

Camci-Unal G, Laromaine A, Hong E, Derda R, and Whitesides GM

Subjects

Animals, Calcium Phosphates metabolism, Cell Line, Cell Proliferation, Mice, Osteoblasts metabolism, Osteoblasts physiology, Calcification, Physiologic, Osteoblasts cytology, Paper, Tissue Engineering methods, Tissue Scaffolds chemistry

Abstract

This work demonstrates the fabrication of partially mineralized scaffolds fabricated in 3D shapes using paper by folding, and by supporting deposition of calcium phosphate by osteoblasts cultured in these scaffolds. This process generates centimeter-scale free-standing structures composed of paper supporting regions of calcium phosphate deposited by osteoblasts. This work is the first demonstration that paper can be used as a scaffold to induce template-guided mineralization by osteoblasts. Because paper has a porous structure, it allows transport of O2 and nutrients across its entire thickness. Paper supports a uniform distribution of cells upon seeding in hydrogel matrices, and allows growth, remodelling, and proliferation of cells. Scaffolds made of paper make it possible to construct 3D tissue models easily by tuning material properties such as thickness, porosity, and density of chemical functional groups. Paper offers a new approach to study mechanisms of biomineralization, and perhaps ultimately new techniques to guide or accelerate the repair of bone.

Published

2016

11. Hydrogel-laden paper scaffold system for origami-based tissue engineering.

Author

Kim SH, Lee HR, Yu SJ, Han ME, Lee DY, Kim SY, Ahn HJ, Han MJ, Lee TI, Kim TS, Kwon SK, Im SG, and Hwang NS

Subjects

Alginates chemistry, Animals, Cartilage drug effects, Cartilage physiology, Chondrocytes cytology, Chondrocytes drug effects, Chondrocytes transplantation, Compressive Strength, Glucuronic Acid chemistry, HeLa Cells, Hexuronic Acids chemistry, Humans, Maleates chemistry, Mice, Inbred BALB C, Mice, Nude, Microscopy, Electron, Scanning, Molecular Weight, Neovascularization, Physiologic drug effects, Polystyrenes chemistry, Rabbits, Spectrometry, X-Ray Emission, Trachea drug effects, Trachea physiology, Hydrogel, Polyethylene Glycol Dimethacrylate pharmacology, Paper, Tissue Engineering methods, Tissue Scaffolds chemistry

Abstract

In this study, we present a method for assembling biofunctionalized paper into a multiform structured scaffold system for reliable tissue regeneration using an origami-based approach. The surface of a paper was conformally modified with a poly(styrene-co-maleic anhydride) layer via initiated chemical vapor deposition followed by the immobilization of poly-l-lysine (PLL) and deposition of Ca(2+). This procedure ensures the formation of alginate hydrogel on the paper due to Ca(2+) diffusion. Furthermore, strong adhesion of the alginate hydrogel on the paper onto the paper substrate was achieved due to an electrostatic interaction between the alginate and PLL. The developed scaffold system was versatile and allowed area-selective cell seeding. Also, the hydrogel-laden paper could be folded freely into 3D tissue-like structures using a simple origami-based method. The cylindrically constructed paper scaffold system with chondrocytes was applied into a three-ring defect trachea in rabbits. The transplanted engineered tissues replaced the native trachea without stenosis after 4 wks. As for the custom-built scaffold system, the hydrogel-laden paper system will provide a robust and facile method for the formation of tissues mimicking native tissue constructs.

Published

2015

12. A paper-based scaffold for enhanced osteogenic differentiation of equine adipose-derived stem cells.

Author

Petersen GF, Hilbert BJ, Trope GD, Kalle WH, and Strappe PM

Subjects

Animals, Cell Culture Techniques instrumentation, Cell Culture Techniques methods, Horses, Adipocytes cytology, Cell Differentiation physiology, Osteogenesis physiology, Paper, Stem Cells cytology, Tissue Scaffolds chemistry

Abstract

Objectives: We investigated the applicability of single layer paper-based scaffolds for the three-dimensional (3D) growth and osteogenic differentiation of equine adipose-derived stem cells (EADSC), with comparison against conventional two-dimensional (2D) culture on polystyrene tissue culture vessels., Results: Viable culture of EADSC was achieved using paper-based scaffolds, with EADSC grown and differentiated in 3D culture retaining high cell viability (>94 %), similarly to EADSC in 2D culture. Osteogenic differentiation of EADSC was significantly enhanced in 3D culture, with Alizarin Red S staining and quantification demonstrating increased mineralisation (p < 0.0001), and an associated increase in expression of the osteogenic-specific markers alkaline phosphatase (p < 0.0001), osteopontin (p < 0.0001), and runx2 (p < 0.01). Furthermore, scanning electron microscopy revealed a spherical morphology of EADSC in 3D culture, compared to a flat morphology of EADSC in 2D culture., Conclusions: Single layer paper-based scaffolds provide an enhanced environment for the in vitro 3D growth and osteogenic differentiation of EADSC, with high cell viability, and a spherical morphology.

Published

2015

13. Paper-based bioactive scaffolds for stem cell-mediated bone tissue engineering.

Author

Park HJ, Yu SJ, Yang K, Jin Y, Cho AN, Kim J, Lee B, Yang HS, Im SG, and Cho SW

Subjects

Animals, Bone Regeneration, Cell Culture Techniques, Cell Differentiation, Cells, Cultured, Humans, Mice, Mice, Inbred BALB C, Mice, Nude, Skull cytology, Skull injuries, Skull physiology, Adipose Tissue cytology, Osteogenesis, Paper, Stem Cell Transplantation, Stem Cells cytology, Tissue Engineering methods, Tissue Scaffolds chemistry

Abstract

Bioactive, functional scaffolds are required to improve the regenerative potential of stem cells for tissue reconstruction and functional recovery of damaged tissues. Here, we report a paper-based bioactive scaffold platform for stem cell culture and transplantation for bone reconstruction. The paper scaffolds are surface-engineered by an initiated chemical vapor deposition process for serial coating of a water-repellent and cell-adhesive polymer film, which ensures the long-term stability in cell culture medium and induces efficient cell attachment. The prepared paper scaffolds are compatible with general stem cell culture and manipulation techniques. An optimal paper type is found to provide structural, physical, and mechanical cues to enhance the osteogenic differentiation of human adipose-derived stem cells (hADSCs). A bioactive paper scaffold significantly enhances in vivo bone regeneration of hADSCs in a critical-sized calvarial bone defect. Stacking the paper scaffolds with osteogenically differentiated hADSCs and human endothelial cells resulted in vascularized bone formation in vivo. Our study suggests that paper possesses great potential as a bioactive, functional, and cost-effective scaffold platform for stem cell-mediated bone tissue engineering. To the best of our knowledge, this is the first study reporting the feasibility of a paper material for stem cell application to repair tissue defects., (Copyright © 2014 Elsevier Ltd. All rights reserved.)

Published

2014

14. Three-dimensional paper-based model for cardiac ischemia.

Author

Mosadegh B, Dabiri BE, Lockett MR, Derda R, Campbell P, Parker KK, and Whitesides GM

Subjects

Animals, Cell Movement, Cell Shape, Cells, Cultured, Hydrogen-Ion Concentration, Rats, Fibroblasts cytology, Models, Cardiovascular, Myocardial Ischemia, Myocytes, Cardiac cytology, Paper, Tissue Scaffolds

Abstract

In vitro models of ischemia have not historically recapitulated the cellular interactions and gradients of molecules that occur in a 3D tissue. This work demonstrates a paper-based 3D culture system that mimics some of the interactions that occur among populations of cells in the heart during ischemia. Multiple layers of paper containing cells, suspended in hydrogels, are stacked to form a layered 3D model of a tissue. Mass transport of oxygen and glucose into this 3D system can be modulated to induce an ischemic environment in the bottom layers of the stack. This ischemic stress induces cardiomyocytes at the bottom of the stack to secrete chemokines which subsequently trigger fibroblasts residing in adjacent layers to migrate toward the ischemic region. This work demonstrates the usefulness of patterned, stacked paper for performing in vitro mechanistic studies of cellular motility and viability within a model of the laminar ventricle tissue of the heart., (© 2014 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2014

15. Substrate stiffness influences high resolution printing of living cells with an ink-jet system.

Author

Tirella A, Vozzi F, De Maria C, Vozzi G, Sandri T, Sassano D, Cognolato L, and Ahluwalia A

Subjects

3T3 Cells, Animals, Biocompatible Materials, Cell Survival, Cells, Cultured, Electrical Equipment and Supplies, Ink, Mice, Paper, Viscosity, Cell Culture Techniques methods, Printing methods, Tissue Engineering methods, Tissue Scaffolds

Abstract

The adaptation of inkjet printing technology for the realisation of controlled micro- and nano-scaled biological structures is of great potential in tissue and biomaterial engineering. In this paper we present the Olivetti BioJet system and its applications in tissue engineering and cell printing. BioJet, which employs a thermal inkjet cartridge, was used to print biomolecules and living cells. It is well known that high stresses and forces are developed during the inkjet printing process. When printing living particles (i.e., cell suspensions) the mechanical loading profile can dramatically damage the processed cells. Therefore computational models were developed to predict the velocity profile and the mechanical load acting on a droplet during the printing process. The model was used to investigate the role of the stiffness of the deposition substrate during droplet impact and compared with experimental investigations on cell viability after printing on different materials. The computational model and the experimental results confirm that impact forces are highly dependent on the deposition substrate and that soft and viscous surfaces can reduce the forces acting on the droplet, preventing cell damage. These results have high relevance for cell bioprinting; substrates should be designed to have a good compromise between substrate stiffness to conserve spatial patterning without droplet coalescence but soft enough to absorb the kinetic energy of droplets in order to maintain cell viability., (Copyright © 2011. Published by Elsevier B.V.)

Published

2011

16. Effect of surface morphologies and chemistry of paper on deposited collagen.

Author

Chang, Boyce S., Boddupalli, Anuraag, Boyer, Andrea F., Orondo, Millicent, Bloch, Jean-Francis, Bratlie, Kaitlin M., and Thuo, Martin M.

Subjects

*SURFACE chemistry, *SURFACE morphology, *COLLAGEN, *SURFACE energy, *SURFACE roughness, *TISSUE scaffolds

Abstract

Paper-based platforms for biological studies have received significant attention given that cellulose is ubiquitous, biocompatible, and can be readily organized into tunable fibrous structures. In the latter form, effect of complexity in surface morphologies (roughness, porosity and fiber organization) on cell-substrate interaction has not been thoroughly explored. We infer that altering the properties of a fibrous material should lead to significant changes in cellular microenvironment and direct the deposition of structurally analogous extracellular matrix (fiber-fiber templating) like collagen. Here, we elucidate the effect of varying paper roughness and surface chemistry on NIH/3T3 fibroblasts via organization of excreted collagen. Collagen intensity was found to increase linearly with paper porosity, indicating a 3D culture platform. The intensity, however, decays over time due to biodegradation of the substrate. Stability can be improved by introducing fluorinated alkyl silanes to yield hydrophobic paper. This process concomitantly transforms the substrate to a 2D-like scaffold where collagen is predominantly assembled on the surface, thus changing the cellular microenvironment. Altering surface energy also led to fluctuations in collagen intensity and organization over time for smooth (calendered) paper substrates. We infer that the increased roughness improves collagen adsorption through capillary driven petal effect. In general, the influence of the substrate simultaneously affects its ability to host collagen and guide orientation. These findings offer insights into the effects of secondary structures and chemistry of fibrous polymeric materials on cell culture, which we propose as vital parameters when using paper-based platforms. Unlabelled Image • Collagen secreted from NIH/3T3 fibroblast cells increases linearly with paper porosity. • Paper transitions from 3D to 2D cell culture scaffold when rendered hydrophobic. • Hydrophobic paper relies on capillary driven petal effect for collagen adsorption. [ABSTRACT FROM AUTHOR]

Published

2019

17. Mineralized paper scaffolds for bone tissue engineering

Author

Colleen McCarthy, Kierra Walsh, Sanika Suvarnapathaki, Gulden Camci-Unal, Xinchen Wu, and Darlin Lantigua

Subjects

Male, Paper, 0106 biological sciences, 0301 basic medicine, Scaffold, Biocompatibility, Bioengineering, 01 natural sciences, Applied Microbiology and Biotechnology, Mineralization (biology), Bone and Bones, Bone tissue engineering, 03 medical and health sciences, Tissue engineering, Osteogenesis, In vivo, 010608 biotechnology, Bone cell, Animals, Rats, Wistar, Tissue Engineering, Tissue Scaffolds, Chemistry, Rats, Cellulose fiber, 030104 developmental biology, Biotechnology, Biomedical engineering

Abstract

Mineralized polymer scaffolds have proven to be effective biomaterials for inducing osteoinductivity in bone tissue engineering. Sequential mineralization is a promising technique for depositing minerals in three-dimensional (3D) scaffolds. Paper, which is made of cellulose fibers, can be used as a tissue scaffold due to its highly porous structure and flexibility, as well as its excellent ability to wick fluids and support the growth of bone cells. In this study, paper-based, mineralized scaffolds were fabricated using sequential mineralization. We conducted experiments with two groups of scaffolds based on different incubation times in the mineralization solutions (30 min and 24 h). Ten cycles of mineralization were performed for each group. We found that the mineral content increased as the cycle number increased and that the 24-h group scaffolds consistently had more mineralization than did the 30-min group scaffolds when measured at the same cycle number. A quantitative reverse transcription-polymerase chain reaction was performed for two osteogenic differentiation markers of the preosteoblasts that were grown on the mineralized paper scaffolds. The gene expression results for bone-specific markers revealed that the mineralized scaffolds were osteoinductive. Subcutaneous implantation of the scaffolds in rats demonstrated favorable biocompatibility, high vascularization, and non-immunogenicity in vivo. The overall results suggest that the sequentially mineralized paper scaffolds are promising materials for use in bone tissue engineering.

Published

2020

18. Generation of Cost-Effective Paper-Based Tissue Models through Matrix-Assisted Sacrificial 3D Printing

Author

Sushila Maharjan, Ameyalli Gómez, Di Huang, Haokai Shen, Feng Cheng, Jun Li, Sanwei Liu, Ho Pan Bei, Yu Shrike Zhang, Haoqun Zhan, Xin Xie, Hongbin Li, Jinmei He, Xia Cao, and Tingting Liu

Subjects

Paper, Materials science, Biocompatibility, Cell Survival, Nanofibers, 3D printing, Bioengineering, Nanotechnology, 02 engineering and technology, Matrix (biology), Article, chemistry.chemical_compound, Human Umbilical Vein Endothelial Cells, Humans, General Materials Science, Cellulose, Microchannel, Tissue Engineering, Tissue Scaffolds, business.industry, Mechanical Engineering, Polysaccharides, Bacterial, Bioprinting, Equipment Design, General Chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, chemistry, Bacterial cellulose, Nanofiber, Printing, Three-Dimensional, Self-healing hydrogels, MCF-7 Cells, 0210 nano-technology, business

Abstract

Due to the combined advantages of cellulose and nanoscale (diameter 20–60 nm), bacterial cellulose possesses a series of attractive features including its natural origin, moderate biosynthesis process, good biocompatibility, and cost-effectiveness. Moreover, bacterial cellulose nanofibers can be conveniently processed into three-dimensional (3D) intertwined structures and form stable paper devices after simple drying. These advantages make it suitable as the material for construction of organ-on-a-chip devices using matrix-assisted sacrificial 3D printing. We successfully fabricated various microchannel structures embedded in the bulk bacterial cellulose hydrogels and retained their integrity after the drying process. Interestingly, these paper-based devices containing hollow microchannels could be rehydrated and populated with relevant cells to form vascularized tissue models. As a proof-of-concept demonstration, we seeded human umbilical vein endothelial cells (HUVECs) into the microchannels to obtain the vasculature and inoculated the MCF-7 cells onto the surrounding matrix of the paper device to build a 3D paper-based vascularized breast tumor model. The results showed that the microchannels were perfusable, and both HUVECs and MCF-7 cells exhibited favorable proliferation behaviors. This study may provide a new strategy for constructing simple and low-cost in vitro tissue models, which may find potential applications in drug screening and personalized medicine.

Published

2019

19. Constructing an Anisotropic Triple-Pass Tubular Framework within a Lyophilized Porous Gelatin Scaffold Using Dexamethasone-Loaded Functionalized Whatman Paper To Reinforce Its Mechanical Strength and Promote Osteogenesis

Author

Jiabing Ran, Hao Zeng, Pan Yan, Xinyu Shen, Guanglin Sun, Janak L. Pathak, Pei Jiang, Hua Tong, Bin Shi, and Yi Bai

Subjects

Paper, Scaffold, Materials science, Polymers and Plastics, Fibroin, Bioengineering, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Dexamethasone, Biomaterials, Tissue engineering, Osteogenesis, Materials Testing, Materials Chemistry, medicine, Animals, Humans, Porosity, Elastic modulus, Mechanical Phenomena, Tissue Engineering, Tissue Scaffolds, Cell Differentiation, 021001 nanoscience & nanotechnology, Rats, 0104 chemical sciences, medicine.anatomical_structure, Compressive strength, Anisotropy, Gelatin, Implant, 0210 nano-technology, Cancellous bone, Biomedical engineering

Abstract

In bone tissue engineering (BTE), most of the currently developed scaffolds still lack the ability to demonstrate high porosity and high mechanical strength simultaneously or the ability to maintain bioactivity and sustained release of loaded biofactors. In this work, we constructed an anisotropic triple-pass tubular framework within a lyophilized porous GEL scaffold using FP, which was prepared by coating DEX-covered Whatman paper (WP) using the silk fibroin (SF) membrane with β-sheet conformation. This novel structural design endowed the functionalized paper frame (FPF)/scaffold implant high porosity, high mechanical strength, and sustained DEX delivery capability. Specifically, its porosity was as high as 88.2%, approximating that of human cancellous bone. The pore diameters of the implant ranged from 50 to 350 μm with an average pore diameter of 127.7 μm, indicating proper pore sizes for successful diffusion of essential nutrients/oxygen and bone tissue-ingrowth. Owing to the construction of double-network-like structure, the FPF/scaffold implant demonstrated excellent mechanical properties both in dry (174.7 MPa in elastic modulus and 14.9 MPa in compressive modulus) and wet states (59.0 MPa in elastic modulus and 3.3 MPa in compressive modulus), indicating its feasibility for in vivo implantation. Besides, the FPF/scaffold implant exhibited long-term DEX releasing behavior (over 50 days) with constant release rate in phosphate buffered saline (PBS). Murine osteoblasts MC3T3-E1 cultured in the porous FPF/scaffold implant had excellent viability. Furthermore, the cells cocultured with the FPF/scaffold implant showed positive proliferation, osteogenic differentiation, and calcium deposition. Twenty-eight days after implantation, extensive osteogenesis was observed in the rats treated with the FPF/scaffold implants. The anisotropic triple-pass tubular framework of the FPF/scaffold implant demonstrates structural similarities to the long bone. Therefore, this novel FPF/scaffold implant could be a better alternative for long bone defect repair.

Published

2017

20. Tissue Papers: Leveraging Paper-Based Microfluidics for the Next Generation of 3D Tissue Models

Author

Tyler S. Larson, Sabrina M. Cramer, and Matthew R. Lockett

Subjects

Paper, Microfluidics, Cell Culture Techniques, 010402 general chemistry, 01 natural sciences, Models, Biological, Article, Analytical Chemistry, Cell Movement, Lab-On-A-Chip Devices, Human Umbilical Vein Endothelial Cells, Animals, Humans, Myocytes, Cardiac, Cellulose, Tissue Engineering, Tissue Scaffolds, Chemistry, 010401 analytical chemistry, Hydrogels, Paper based, Fibroblasts, 0104 chemical sciences, Extracellular Matrix, Hepatocytes, Biochemical engineering, Current (fluid)

Abstract

Paper-based scaffolds support the three-dimensional culture of mammalian cells in tissue-like environments. These Tissue Papers, a name that highlights the use of materials obtained from (plant) tissue to generate newly functioning (human) tissue structures, are a promising analytical tool to quantify cellular responses in physiologically relevant extracellular gradients and coculture architectures. Here, we highlight current examples of Tissue Papers, commonly used methods of analysis, and current measurement challenges.

Published

2019

21. Customizable, engineered substrates for rapid screening of cellular cues

Author

Eline Huethorst, Fraser A Campbell, Nikolaj Gadegaard, Anwer Saeed, Paul M. Reynolds, Rachel Love, Marie F.A. Cutiongco, and Matthew J. Dalby

Subjects

Pluripotent Stem Cells, Paper, Materials science, pillar, Bone development, Surface Properties, 0206 medical engineering, Elastic shear modulus, Cell Culture Techniques, Biomedical Engineering, Biocompatible Materials, Bioengineering, high throughput, 02 engineering and technology, Matrix (biology), Biochemistry, Biomaterials, Mice, 03 medical and health sciences, Chondrocytes, Osteoblast function, topography, Microscopy, Animals, Humans, Myocytes, Cardiac, Cell adhesion, Cells, Cultured, Cell Proliferation, 030304 developmental biology, Nanopillar, cell morphology, 0303 health sciences, Tissue Engineering, Tissue Scaffolds, substrate rigidity, General Medicine, 021001 nanoscience & nanotechnology, 020601 biomedical engineering, injection moulding, Nanostructures, nanofabrication, 0210 nano-technology, Biotechnology, Biomedical engineering

Abstract

Biophysical cues robustly direct cell responses and are thus important tools for in vitro and translational biomedical applications. High throughput platforms exploring substrates with varying physical properties are therefore valuable. However, currently existing platforms are limited in throughput, the biomaterials used, the capability to segregate between different cues and the assessment of dynamic responses. Here we present a multiwell array (3 × 8) made of a substrate engineered to present topography or rigidity cues welded to a bottomless plate with a 96-well format. Both the patterns on the engineered substrate and the well plate format can be easily customized, permitting systematic and efficient screening of biophysical cues. To demonstrate the broad range of possible biophysical cues examinable, we designed and tested three multiwell arrays to influence cardiomyocyte, chondrocyte and osteoblast function. Using the multiwell array, we were able to measure different cell functionalities using analytical modalities such as live microscopy, qPCR and immunofluorescence. We observed that grooves (5 μm in size) induced less variation in contractile function of cardiomyocytes. Compared to unpatterned plastic, nanopillars with 127 nm height, 100 nm diameter and 300 nm pitch enhanced matrix deposition, chondrogenic gene expression and chondrogenic maintenance. High aspect ratio pillars with an elastic shear modulus of 16 kPa mimicking the matrix found in early stages of bone development improved osteogenic gene expression compared to stiff plastic. We envisage that our bespoke multiwell array will accelerate the discovery of relevant biophysical cues through improved throughput and variety.

Published

2020

22. Hydrogel-laden paper scaffold system for origami-based tissue engineering

Author

Su-Hwan Kim, Min Eui Han, Doh Young Lee, Taek-Soo Kim, Tae-Ik Lee, Hee Jin Ahn, Seong Keun Kwon, Mi Jung Han, Nathaniel S. Hwang, Seung Jung Yu, Hak Rae Lee, Soo Yeon Kim, and Sung Gap Im

Subjects

Paper, Scaffold, Materials science, Compressive Strength, Alginates, Mice, Nude, Neovascularization, Physiologic, Nanotechnology, Hydrogel, Polyethylene Glycol Dimethacrylate, Chondrocytes, Glucuronic Acid, Tissue engineering, Animals, Humans, Electrostatic interaction, Mice, Inbred BALB C, Multidisciplinary, Tissue Engineering, Tissue Scaffolds, Hexuronic Acids, Maleates, Spectrometry, X-Ray Emission, Substrate (chemistry), Adhesion, Biological Sciences, Molecular Weight, Trachea, Cartilage, Native tissue, Microscopy, Electron, Scanning, Polystyrenes, Rabbits, Alginate hydrogel, Layer (electronics), HeLa Cells, Biomedical engineering

Abstract

In this study, we present a method for assembling biofunctionalized paper into a multiform structured scaffold system for reliable tissue regeneration using an origami-based approach. The surface of a paper was conformally modified with a poly(styrene-co-maleic anhydride) layer via initiated chemical vapor deposition followed by the immobilization of poly-l-lysine (PLL) and deposition of Ca(2+). This procedure ensures the formation of alginate hydrogel on the paper due to Ca(2+) diffusion. Furthermore, strong adhesion of the alginate hydrogel on the paper onto the paper substrate was achieved due to an electrostatic interaction between the alginate and PLL. The developed scaffold system was versatile and allowed area-selective cell seeding. Also, the hydrogel-laden paper could be folded freely into 3D tissue-like structures using a simple origami-based method. The cylindrically constructed paper scaffold system with chondrocytes was applied into a three-ring defect trachea in rabbits. The transplanted engineered tissues replaced the native trachea without stenosis after 4 wks. As for the custom-built scaffold system, the hydrogel-laden paper system will provide a robust and facile method for the formation of tissues mimicking native tissue constructs.

Published

2015

23. Paper-based bioactive scaffolds for stem cell-mediated bone tissue engineering

Author

Seung Woo Cho, Hee Seok Yang, Hyun Ji Park, Jin Kim, Ann Na Cho, Bora Lee, Kisuk Yang, Yoonhee Jin, Sung Gap Im, and Seung Jung Yu

Subjects

Paper, Scaffold, Bone Regeneration, Materials science, Cell, Cell Culture Techniques, Biophysics, Mice, Nude, Bioengineering, Gene delivery, Biomaterials, Extracellular matrix, Mice, Osteogenesis, medicine, Animals, Humans, Bone regeneration, Cells, Cultured, Mice, Inbred BALB C, Tissue Engineering, Tissue Scaffolds, Stem Cells, Skull, Cell Differentiation, Transplantation, medicine.anatomical_structure, Adipose Tissue, Mechanics of Materials, Ceramics and Composites, Stem cell, Bioactive paper, Stem Cell Transplantation, Biomedical engineering

Abstract

Bioactive, functional scaffolds are required to improve the regenerative potential of stem cells for tissue reconstruction and functional recovery of damaged tissues. Here, we report a paper-based bioactive scaffold platform for stem cell culture and transplantation for bone reconstruction. The paper scaffolds are surface-engineered by an initiated chemical vapor deposition process for serial coating of a water-repellent and cell-adhesive polymer film, which ensures the long-term stability in cell culture medium and induces efficient cell attachment. The prepared paper scaffolds are compatible with general stem cell culture and manipulation techniques. An optimal paper type is found to provide structural, physical, and mechanical cues to enhance the osteogenic differentiation of human adipose-derived stem cells (hADSCs). A bioactive paper scaffold significantly enhances in vivo bone regeneration of hADSCs in a critical-sized calvarial bone defect. Stacking the paper scaffolds with osteogenically differentiated hADSCs and human endothelial cells resulted in vascularized bone formation in vivo. Our study suggests that paper possesses great potential as a bioactive, functional, and cost-effective scaffold platform for stem cell-mediated bone tissue engineering. To the best of our knowledge, this is the first study reporting the feasibility of a paper material for stem cell application to repair tissue defects.

Published

2014

24. Self-driven perfusion culture system using a paper-based double-layered scaffold

Author

Yoshinori Arisaka, Ai Ozaki, and Naoya Takeda

Subjects

0301 basic medicine, Paper, Scaffold, food.ingredient, business.product_category, Materials science, Capillary action, Microfluidics, Biomedical Engineering, Cell Culture Techniques, Bioengineering, 02 engineering and technology, Biochemistry, Gelatin, Cell Line, Biomaterials, 03 medical and health sciences, food, Perfusion Culture, Bioreactors, Microfiber, Shear stress, Cell Adhesion, Animals, Cell Proliferation, Tissue Scaffolds, Endothelial Cells, General Medicine, 021001 nanoscience & nanotechnology, 030104 developmental biology, Cell culture, Microscopy, Electron, Scanning, Cattle, Stress, Mechanical, 0210 nano-technology, business, Biotechnology, Biomedical engineering

Abstract

Shear stress caused by fluid flow is known to promote tissue development from cells in vivo. Therefore, perfusion cultures have been studied to investigate the mechanisms involved and to fabricate engineered tissues in vitro, particularly those that include blood vessels. Microfluidic devices, which function with fine machinery of chambers and microsyringes for fluid flow and have small culture areas, are conventionally used for perfusion culture. In contrast, we have developed a self-driven perfusion culture system by using a paper-based double-layered scaffold as the fundamental component. Gelatin microfibers were electrospun onto a paper material to prepare the scaffold system, in which the constant perfusion of the medium and the scaffold for cell adhesion/proliferation were functionally divided into a paper and a gelatin microfiber layer, respectively. By applying both the capillary action and siphon phenomenon of the paper-based scaffold, which bridged two medium chambers at different height levels, a self-driven medium flow was achieved and the flow rate was also stable, constant, and quantitatively controllable. Moreover, the culture area was enlargeable to the cm(2) scale. The endothelial cells cultivated on this system oriented along the medium-flow direction, suggesting that the shear stress caused by medium flow was effectively applied. This perfusion culture system is expected to be useful for fabricating three-dimensional and large engineered tissues in the future.

Published

2016

25. Biomineralization Guided by Paper Templates

Author

Ratmir Derda, Estrella Hong, George M. Whitesides, Gulden Camci-Unal, Anna Laromaine, Wyss Institute of Biologically Inspired Engineering, University of Texas, and National Science Foundation (US)

Subjects

Calcium Phosphates, Paper, Scaffold, Cell biology, Materials science, Nanotechnology, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Article, Cell Line, Mice, Cell growth, Calcification, Physiologic, Tissue scaffolds, Tissue engineering, Animals, Porosity, Cell Proliferation, Osteoblasts, Multidisciplinary, Tissue Engineering, Tissue Scaffolds, 021001 nanoscience & nanotechnology, 3d shapes, 0104 chemical sciences, Template, 0210 nano-technology, Biomineralization

Abstract

This work demonstrates the fabrication of partially mineralized scaffolds fabricated in 3D shapes using paper by folding, and by supporting deposition of calcium phosphate by osteoblasts cultured in these scaffolds. This process generates centimeter-scale free-standing structures composed of paper supporting regions of calcium phosphate deposited by osteoblasts. This work is the first demonstration that paper can be used as a scaffold to induce template-guided mineralization by osteoblasts. Because paper has a porous structure, it allows transport of O2 and nutrients across its entire thickness. Paper supports a uniform distribution of cells upon seeding in hydrogel matrices, and allows growth, remodelling, and proliferation of cells. Scaffolds made of paper make it possible to construct 3D tissue models easily by tuning material properties such as thickness, porosity, and density of chemical functional groups. Paper offers a new approach to study mechanisms of biomineralization, and perhaps ultimately new techniques to guide or accelerate the repair of bone., This work was funded by the Wyss Institute of Biologically Inspired Engineering. Early work on this project was funded by a sub-award from the University of Texas Health Science Center at Houston, under DARPA grant # W911NF-09-1-0044. The project was performed in part at the Center for Nanoscale Systems (CNS), a member of the National Nanotechnology Infrastructure Network (NNIN), which is supported by the National Science Foundation under NSF award no. ECS-0335765. CNS is part of Harvard University. A patent application for this work has been filed but not yet published.

Published

2016

26. Synthetic Matrices to Serve as Niches for Muscle Cell Transplantation

Author

Charles E. Murry, Shannon Kuklok, Joseph Schmidt Mcgonigle, Hans Reinecke, and Sarah Fernandes

Subjects

Paper, medicine.medical_specialty, Histology, Cell Survival, Cellular differentiation, Cell, Cell- and Tissue-Based Therapy, Biocompatible Materials, Biology, Cell Line, Cell therapy, Mice, Tissue engineering, medicine, Animals, Humans, Cell adhesion, Muscle Cells, Tissue Engineering, Tissue Scaffolds, Myocardium, Biomaterial, Cell Differentiation, Surgery, Transplantation, medicine.anatomical_structure, Cell culture, Anatomy, Biomedical engineering

Abstract

Poor cell retention and limited cell survival after grafting are major limitations of cell therapy. Recent studies showed that the use of matrices as vehicles at the time of cell injection can significantly improve cell engraftment by providing an appropriate structure and physical support for the injected cells. Properly designed matrices can also promote the organization of the cells into a functioning cardiac-like tissue and enhance integration between the host and the engrafted tissue. Furthermore, the use of an injectable biomaterial provides an opportunity to release in situ bioactive molecules that can further enhance the beneficial effects of cell transplantation. In this article we review a large variety of biologically derived synthetic and hybrid materials that have been tested as matrices for cardiac repair. We summarize the optimal parameters required for an ideal matrix including biocompatibility, injectability, degradation rate, and mechanical properties. Using an in vivo subcutaneous grafting model, we also provide novel data involving a side-by-side comparison of six synthetic matrices derived from maltodextrin. By systematically varying polymer molecular weight, cross-link density, and availability of cell adhesion motifs, a synthetic matrix was identified that supported skeletal myotube formation similar to Matrigel™. Our results emphasize not only the need to have a range of tunable matrices for cardiac cell therapy but also the importance of further characterizing the physical properties required for an ideal injectable matrix.

Published

2011

27. The Evolution of Vascular Tissue Engineering and Current State of the Art

Author

David Gebhart, Nathalie Dusserre, Nicolas L'Heureux, Todd N. McAllister, and Marissa Peck

Subjects

Paper, medicine.medical_specialty, Histology, Tissue Engineering, Tissue Scaffolds, business.industry, Expanded polytetrafluoroethylene, Blood Vessel Prosthesis, Surgery, Clinical trial, medicine.anatomical_structure, Blood pressure, Tissue engineering, Blood vessel prosthesis, Materials Testing, Mechanical strength, medicine, Vascular tissue engineering, Animals, Humans, Anatomy, business, Blood vessel

Abstract

Dacron® (polyethylene terephthalate) and Goretex® (expanded polytetrafluoroethylene) vascular grafts have been very successful in replacing obstructed blood vessels of large and medium diameters. However, as diameters decrease below 6 mm, these grafts are clearly outperformed by transposed autologous veins and, particularly, arteries. With approximately 8 million individuals with peripheral arterial disease, over 500,000 patients diagnosed with end-stage renal disease, and over 250,000 patients per year undergoing coronary bypass in the USA alone, there is a critical clinical need for a functional small-diameter conduit [Lloyd-Jones et al., Circulation 2010;121:e46–e215]. Over the last decade, we have witnessed a dramatic paradigm shift in cardiovascular tissue engineering that has driven the field away from biomaterial-focused approaches and towards more biology-driven strategies. In this article, we review the preclinical and clinical efforts in the quest for a tissue-engineered blood vessel that is free of permanent synthetic scaffolds but has the mechanical strength to become a successful arterial graft. Special emphasis is given to the tissue engineering by self-assembly (TESA) approach, which has been the only one to reach clinical trials for applications under arterial pressure.

Published

2011

28. Optimizing Dynamic Interactions between a Cardiac Patch and Inflammatory Host Cells

Author

Gordana Vunjak-Novakovic, Laura Santambrogio, and Donald O. Freytes

Subjects

Paper, medicine.medical_specialty, Histology, Cell- and Tissue-Based Therapy, Myocardial Ischemia, Ischemia, Inflammation, Paracrine signalling, Tissue engineering, medicine, Animals, Humans, Myocytes, Cardiac, Autocrine signalling, Tissue Engineering, Tissue Scaffolds, business.industry, Myocardium, Regeneration (biology), Cardiac muscle, medicine.disease, Surgery, Cell biology, medicine.anatomical_structure, Anatomy, medicine.symptom, Stem cell, business

Abstract

Damaged heart muscle has only a minimal ability for regeneration following myocardial infarction in which cardiomyocytes are lost to ischemia. The most clinically promising approach to regeneration of cardiac muscle currently under investigation is that of injecting cardiogenic repair cells or implanting a preformed tissue-engineered patch. While major advances are being made in the derivation of functional human cardiomyocytes and the development of tissue-engineering modalities for cardiac repair, the host environment into which the repair cells are placed is largely overlooked. Within seconds of myocardial ischemia, hypoxia sets in in the myocardium and the inflammatory response starts, characterized by rapid deployment of circulating cells and the release of paracrine and autocrine signals. Therefore, the inflammatory conditions under which these interactions take place, the design of the scaffold material used, and the maturity of the implanted cells will determine the outcomes of any stem cell-based therapy. We discuss here the interactions between implanted and inflammatory cells of the host, which are critical for the design of effective heart repair therapies.

Published

2011

29. The Nature and Role of Periosteum in Bone and Cartilage Regeneration

Author

Noritaka Isogai, Seika Matsushima, Elizabeth Lowder, Robin Jacquet, Taku Tokui, and William J. Landis

Subjects

Paper, Bone sialoprotein, Bone Regeneration, Histology, Type II collagen, Mice, Nude, Core Binding Factor Alpha 1 Subunit, Collagen Type I, Prosthesis Implantation, Mice, stomatognathic system, Periosteum, Animals, Integrin-Binding Sialoprotein, Medicine, Collagen Type II, Endochondral ossification, Tissue Engineering, Tissue Scaffolds, biology, business.industry, Cartilage, Mandible, Anatomy, Radiography, medicine.anatomical_structure, Gene Expression Regulation, Intramembranous ossification, biology.protein, Cattle, business, Type I collagen

Abstract

This study was undertaken to determine whether periosteum from different bone sources in a donor results in the same formation of bone and cartilage. In this case, periosteum obtained from the cranium and mandible (examples of tissue supporting intramembranous ossification) and the radius and ilium (examples of tissues supporting endochondral ossification) of individual calves was used to produce tissue-engineered constructs that were implanted in nude mice and then retrieved after 10 and 20 weeks. Specimens were compared in terms of their osteogenic and chondrogenic potential by radiography, histology, and gene expression levels. By 10 weeks of implantation and more so by 20 weeks, constructs with cranial periosteum had developed to the greatest extent, followed in order by ilium, radius, and mandible periosteum. All constructs, particularly with cranial tissue although minimally with mandibular periosteum, had mineralized by 10 weeks on radiography and stained for proteoglycans with safranin-O red (cranial tissue most intensely and mandibular tissue least intensely). Gene expression of type I collagen, type II collagen, runx2, and bone sialoprotein (BSP) was detectable on QRT-PCR for all specimens at 10 and 20 weeks. By 20 weeks, the relative gene levels were: type I collagen, ilium >> radial ≧ cranial ≧ mandibular; type II collagen, radial > ilium > cranial ≧ mandibular; runx2, cranial >>> radial > mandibular ≧ ilium; and BSP, ilium ≧ radial > cranial > mandibular. These data demonstrate that the osteogenic and chondrogenic capacity of the various constructs is not identical and depends on the periosteal source regardless of intramembranous or endochondral ossification. Based on these results, cranial and mandibular periosteal tissues appear to enhance bone formation most and least prominently, respectively. The appropriate periosteal choice for bone and cartilage tissue engineering and regeneration should be a function of its immediate application as well as other factors besides growth rate.

Published

2011

30. Biosurface engineering through ink jet printing

Author

Mohammad Firoz Khan, Gil Garnier, Xu Li, John S. Forsythe, Deniece Fon, Wei Shen, and Junfei Tian

Subjects

Paper, Materials science, Polyesters, Microfluidics, education, Nanofibers, Color, Nanotechnology, Substrate (printing), Surface tension, Viscosity, Colloid and Surface Chemistry, Thermal, Animals, Surface Tension, Physical and Theoretical Chemistry, Horseradish Peroxidase, Microscopy, Confocal, Tissue Engineering, Tissue Scaffolds, Inkwell, Serum Albumin, Bovine, Surfaces and Interfaces, General Medicine, body regions, Polyester, Nanofiber, Printing, Cattle, Ink, Fluorescein-5-isothiocyanate, circulatory and respiratory physiology, Biotechnology

Abstract

The feasibility of thermal ink jet printing as a robust process for biosurface engineering was demonstrated. The strategy investigated was to reconstruct a commercial printer and take advantage of its colour management interface. High printing resolution was achieved by formulating bio-inks of viscosity and surface tension similar to those of commercial inks. Protein and enzyme denaturation during thermal ink jet printing was shown to be insignificant. This is because the time spent by the biomolecules in the heating zone of the printer is negligible; in addition, the air and substrate of high heat capacity absorb any residual heat from the droplet. Gradients of trophic/tropic factors can serve as driving force for cell growth or migration for tissue regeneration. Concentration gradients of proteins were printed on scaffolds to show the capability of ink jet printing. The printed proteins did not desorb upon prolonged immersion in aqueous solutions, thus allowing printed scaffold to be used under in vitro and in vivo conditions. Our group portrait was ink jet printed with a protein on paper, illustrating that complex biopatterns can be printed on large area. Finally, patterns of enzymes were ink jet printed within the detection and reaction zones of a paper diagnostic.

Published

2010

31. A paper-based scaffold for enhanced osteogenic differentiation of equine adipose-derived stem cells

Author

Padraig Strappe, Bryan Hilbert, Wouter Kalle, Gareth Trope, and Gayle F. Petersen

Subjects

Paper, biology, Tissue Scaffolds, Chemistry, Stem Cells, Cell Culture Techniques, Adipose tissue, Bioengineering, Cell Differentiation, General Medicine, Applied Microbiology and Biotechnology, In vitro, Staining, Cell biology, RUNX2, Tissue culture, Osteogenesis, biology.protein, Adipocytes, Alkaline phosphatase, Animals, Osteopontin, Horses, Stem cell, Biotechnology

Abstract

We investigated the applicability of single layer paper-based scaffolds for the three-dimensional (3D) growth and osteogenic differentiation of equine adipose-derived stem cells (EADSC), with comparison against conventional two-dimensional (2D) culture on polystyrene tissue culture vessels. Viable culture of EADSC was achieved using paper-based scaffolds, with EADSC grown and differentiated in 3D culture retaining high cell viability (>94 %), similarly to EADSC in 2D culture. Osteogenic differentiation of EADSC was significantly enhanced in 3D culture, with Alizarin Red S staining and quantification demonstrating increased mineralisation (p

Published

2015

32. Engineered Paper-Based Cell Culture Platforms

Author

Yan Ni Kelly, Darlin Lantigua, Gulden Camci-Unal, and Barış Ünal

Subjects

Paper, 0301 basic medicine, Materials science, Cell Culture Techniques, Biomedical Engineering, Pharmaceutical Science, Biocompatible Materials, Nanotechnology, 02 engineering and technology, Biomaterials, 03 medical and health sciences, Tissue engineering, Biomimetics, Animals, Humans, Tissue Engineering, Tissue Scaffolds, business.industry, Paper based, Modular design, 021001 nanoscience & nanotechnology, Biocompatible material, Multicellular organism, 030104 developmental biology, Cell culture, Self-healing hydrogels, Stem cell, 0210 nano-technology, business

Abstract

Paper is used in various applications in biomedical research including diagnostics, separations, and cell cultures. Paper can be conveniently engineered due to its tunable and flexible nature, and is amenable to high-throughput sample preparation and analysis. Paper-based platforms are used to culture primary cells, tumor cells, patient biopsies, stem cells, fibroblasts, osteoblasts, immune cells, bacteria, fungi, and plant cells. These platforms are compatible with standard analytical assays that are typically used to monitor cell behavior. Due to its thickness and porous nature, there are no mass transport limitations to/from the cells in paper scaffolds. It is possible to pattern paper in different scales (micrometer to centimeter), generate modular configurations in 3D, fabricate multicellular and compartmentalized tissue mimetics for clinical applications, and recover cells from the scaffolds for further analysis. 3D paper constructs can provide physiologically relevant tissue models for personalized medicine. Layer-by layer strategies to assemble tissue-like structures from low-cost and biocompatible paper-based materials offer unique opportunities that include understanding fundamental biology, developing disease models, and assembling different tissues for organ-on-paper applications. Paper-based platforms can also be used for origami-inspired tissue engineering. This work provides an overview of recent progress in engineered paper-based biomaterials and platforms to culture and analyze cells.

Published

2017

33. Three-dimensional paper-based model for cardiac ischemia

Author

Matthew R. Lockett, Ratmir Derda, Kevin Kit Parker, Bobak Mosadegh, Patrick H. Campbell, George M. Whitesides, and Borna E. Dabiri

Subjects

Paper, Chemokine, Materials science, Biomedical Engineering, Ischemia, Myocardial Ischemia, Pharmaceutical Science, Article, Biomaterials, 3D cell culture, Cell Movement, medicine, Animals, Myocytes, Cardiac, Cell Shape, Cells, Cultured, biology, Tissue Scaffolds, Cardiac ischemia, Models, Cardiovascular, Fibroblasts, Hydrogen-Ion Concentration, medicine.disease, In vitro, Rats, medicine.anatomical_structure, Ventricle, Self-healing hydrogels, Biophysics, biology.protein, Biomedical engineering, Blood vessel

Abstract

In vitro models of ischemia have not historically recapitulated the cellular interactions and gradients of molecules that occur in a 3D tissue. This work demonstrates a paper-based 3D culture system that mimics some of the interactions that occur among populations of cells in the heart during ischemia. Multiple layers of paper containing cells, suspended in hydrogels, are stacked to form a layered 3D model of a tissue. Mass transport of oxygen and glucose into this 3D system can be modulated to induce an ischemic environment in the bottom layers of the stack. This ischemic stress induces cardiomyocytes at the bottom of the stack to secrete chemokines which subsequently trigger fi broblasts residing in adjacent layers to migrate toward the ischemic region. This work demonstrates the usefulness of patterned, stacked paper for performing in vitro mechanistic studies of cellular motility and viability within a model of the laminar ventricle tissue of the heart. the blood vessel into the tissue, and ii) the consumption of these nutrients by cellular metabolism. Most tissues in the body have capillaries every ≈200 µm to ensure suffi cient delivery of oxygen to all cells. [ 2 ] Cardi

Published

2013

34. Right ventricular outflow tract repair with a cardiac biologic scaffold

Author

Nathaniel T. Remlinger, Thomas W. Gilbert, William R. Wagner, Ryotaro Hashizume, Kazuro Fujimoto, Stephen F. Badylak, John Wainwright, Colin Pesyna, and Kimimasa Tobita

Subjects

Heart Defects, Congenital, Paper, Histology, Tissue Engineering, Tissue Scaffolds, business.industry, Normal anatomy, Extramural, Polyethylene Terephthalates, Swine, Biologic scaffold, Heart Ventricles, Anatomy, Extracellular Matrix, Rats, Text mining, Tissue engineering, Echocardiography, Rats, Inbred Lew, Medicine, Ventricular outflow tract, Animals, Female, business

Abstract

Background: Surgical reconstruction of congenital heart defects is often limited by the nonresorbable material used to approximate normal anatomy. In contrast, biologic scaffold materials composed of resorbable non-cross-linked extracellular matrix (ECM) have been used for tissue reconstruction of multiple organs and are replaced by host tissue. Preparation of whole organ ECM by decellularization through vascular perfusion can maintain much of the native three-dimensional (3D) structure, strength, and tissue-specific composition. A 3D cardiac ECM (C-ECM) biologic scaffold material would logically have structural and functional advantages over materials such as Dacron™ for myocardial repair, but the in vivo remodeling characteristics of C-ECM have not been investigated to date. Methods and Results: A porcine C-ECM patch or Dacron patch was used to reconstruct a full-thickness right ventricular outflow tract (RVOT) defect in a rat model with end points of structural remodeling function at 16 weeks. The Dacron patch was encapsulated by dense fibrous tissue and showed little cellular infiltration. Echocardiographic analysis showed that the right ventricle of the hearts patched with Dacron were dilated at 16 weeks compared to presurgery baseline values. The C-ECM patch remodeled into dense, cellular connective tissue with scattered small islands of cardiomyocytes. The hearts patched with C-ECM showed no difference in the size or function of the ventricles as compared to baseline values at both 4 and 16 weeks. Conclusions: The C-ECM patch was associated with better functional and histomorphological outcomes compared to the Dacron patch in this rat model of RVOT reconstruction.

Published

2011

35. Characterization of the Natural History of Extracellular Matrix Production in Tissue-Engineered Vascular Grafts during Neovessel Formation

Author

Yuji Naito, Jay D. Humphrey, Christopher K. Breuer, Misty J Williams-Fritze, Daniel Duncan, Spencer N. Church, Narutoshi Hibino, Joseph A. Madri, and Toshiharu Shinoka

Subjects

Paper, Male, Histology, Polymers, Polyesters, Bone Marrow Cells, Vena Cava, Inferior, Matrix metalloproteinase, Inferior vena cava, Glycosaminoglycan, Extracellular matrix, Mice, Tissue engineering, medicine, Animals, Zymography, Lactic Acid, biology, Tissue Engineering, Tissue Scaffolds, Chemistry, Anatomy, Molecular biology, Matrix Metalloproteinases, Blood Vessel Prosthesis, Elastin, Extracellular Matrix, Mice, Inbred C57BL, medicine.anatomical_structure, medicine.vein, biology.protein, Female, Vascular Grafting, Bone marrow, Collagen, Polyglycolic Acid

Abstract

Background: The extracellular matrix (ECM) is a critical determinant of neovessel integrity. Materials and Methods: Thirty-six (polyglycolic acid + polycaprolactone and poly lactic acid) tissue-engineered vascular grafts seeded with syngeneic bone marrow mononuclear cells were implanted as inferior vena cava interposition grafts in C57BL/6 mice. Specimens were characterized using immunohistochemical staining and qPCR for representative ECM components in addition to matrix metalloproteinases (MMPs). Total collagen, elastin, and glycosaminoglycan (GAG) contents were determined. MMP activity was measured using zymography. Results: Collagen production on histology demonstrated an initial increase in type III at 1 week followed by type I production at 2 weeks and type IV at 4 weeks. Gene expression of both type I and type III peaked at 2 weeks, whereas type IV continued to increase over the 4-week period. Histology demonstrated fibrillin-1 deposition at 1 week followed by elastin production at 4 weeks. Elastin gene expression significantly increased at 4 weeks, whereas fibrillin-1 decreased at 4 weeks. GAG demonstrated abundant production at each time point on histology. Gene expression of decorin significantly increased at 4 weeks, whereas versican decreased over time. Biochemical analysis showed that total collagen production was greatest at 2 weeks, and there was a significant increase in elastin and GAG production at 4 weeks. Histological characterization of MMPs showed abundant production of MMP-2 at each time point, while MMP-9 decreased over the 4-week period. Gene expression of MMP-2 significantly increased at 4 weeks, whereas MMP-9 significantly decreased at 4 weeks. Conclusions: ECM production during neovessel formation is characterized by early ECM deposition followed by extensive remodeling.

Published

2011

36. Substrate stiffness influences high resolution printing of living cells with an ink-jet system

Author

Federico Vozzi, Duccio Spartaco Sassano, Annalisa Tirella, Tazio Sandri, Arti Ahluwalia, Carmelo De Maria, Livio Cognolato, and Giovanni Vozzi

Subjects

Paper, Materials science, Cell Survival, Electrical Equipment and Supplies, Cell Culture Techniques, Bioengineering, Nanotechnology, Biocompatible Materials, Substrate (printing), Applied Microbiology and Biotechnology, Mice, Tissue engineering, medicine, Deposition (phase transition), Animals, Cells, Cultured, chemistry.chemical_classification, Mechanical load, Tissue Engineering, Tissue Scaffolds, Viscosity, Biomolecule, Stiffness, Biomaterial, 3T3 Cells, Finite element method, chemistry, Printing, Ink, medicine.symptom, Biotechnology

Abstract

The adaptation of inkjet printing technology for the realisation of controlled micro- and nano-scaled biological structures is of great potential in tissue and biomaterial engineering. In this paper we present the Olivetti BioJet system and its applications in tissue engineering and cell printing. BioJet, which employs a thermal inkjet cartridge, was used to print biomolecules and living cells. It is well known that high stresses and forces are developed during the inkjet printing process. When printing living particles (i.e., cell suspensions) the mechanical loading profile can dramatically damage the processed cells. Therefore computational models were developed to predict the velocity profile and the mechanical load acting on a droplet during the printing process. The model was used to investigate the role of the stiffness of the deposition substrate during droplet impact and compared with experimental investigations on cell viability after printing on different materials. The computational model and the experimental results confirm that impact forces are highly dependent on the deposition substrate and that soft and viscous surfaces can reduce the forces acting on the droplet, preventing cell damage. These results have high relevance for cell bioprinting; substrates should be designed to have a good compromise between substrate stiffness to conserve spatial patterning without droplet coalescence but soft enough to absorb the kinetic energy of droplets in order to maintain cell viability.

Published

2011