Angiogenesis in Free-Standing Two-Vasculature-Embedded Scaffold Extruded by Two-Core Laminar Flow Device

Nguyen, Chanh Trung; Duong, Van Thuy; Hwang, Chang Ho; Koo, Kyo‐in

doi:10.18063/ijb.v8i3.557

Cited by 5 publications

(5 citation statements)

References 65 publications

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“…Especially, the sprout length increased abruptly from day 5 to day 9. This observation was similar with the previous reports [23,62]…”

Section: Microvascular Network Formationsupporting

confidence: 94%

“…Hence, branching is a fundamental process that plays a critical role in the vessel network organization and functionality. For long-term survival and proper function of the engineered tissue, the vasculature networks need to meet some requirements; (i) a 3D dense network to surpass the 200 µm diffusion limit of oxygen and nutrients, (ii) branching connections to cover the maximum tissue volume, (iii) functions of angiogenesis and perfusion, (iv) implantability to target host [20][21][22][23][24].…”

Section: Introductionmentioning

confidence: 99%

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Ultrasound standing wave spatial patterning of human umbilical vein endothelial cells for 3D micro-vascular networks formation

Le,

Phan,

Lenshof

et al. 2023

Biofabrication

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Generating functional and perfusable micro-vascular networks is an important goal for the fabrication of large and three-dimensional tissues. Up to now, it is a complicated multitask involving several different factors such as time consuming, cells survival, micro-diameter vasculature and strict alignment. Here, we propose a technique combining multi-material extrusion and ultrasound standing wave forces to create a network structure of human umbilical vein endothelial cells within a mixture of calcium alginate and decellularized extracellular matrix. The functionality of the matured microvasculature networks was demonstrated through the enhancement of cell-cell adhesion, angiogenesis process, and perfusion tests with microparticles, FITC-dextran, and whole mouse blood. Moreover, animal experiments exhibited the implantability including that the pre-existing blood vessels of the host sprout towards the preformed vessels of the scaffold over time and the microvessels inside the implanted scaffold matured from empty tubular structures to functional blood-carrying microvessels in two weeks.

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“…Especially, the sprout length increased abruptly from day 5 to day 9. This observation was similar with the previous reports [23,62]…”

Section: Microvascular Network Formationsupporting

confidence: 94%

Section: Introductionmentioning

confidence: 99%

Ultrasound standing wave spatial patterning of human umbilical vein endothelial cells for 3D micro-vascular networks formation

Le,

Phan,

Lenshof

et al. 2023

Biofabrication

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“…Extrusion-based bioprinting is a modification of inkjet printing that exerts a constant force on the bio-ink during output [ 21 ]. This results in a cylindrical printed stream that attaches to the intended surface as a continuous line [ 22 , 23 ]. This is a significantly different approach to the singular, high-cell-density, bio-ink droplets found in standard inkjet bioprinting [ 24 ].…”

Section: Bioprinting: Methods and Materialsmentioning

confidence: 99%

“… Bioprinting Method Key Aspects Advantages Disadvantages References Inkjet First bioprinting technology that has a bio-ink cartridge. Minimum droplet volume of 20 nL Low cost Easy accessibility High cell viability (>85%) Thermal actuator is potentially prone to high-temperature stress [ 13 , 14 , 15 , 16 ] Extrusion A modification of inkjet-based bioprinting that prints a cylindrical stream onto a printing surface in a continuous line Highly controlled printing structure Limited resolution (100–500 µm) Reduced cell viability [ 22 , 23 , 32 ] Laser-assisted Propels bio-ink onto the printing surface High cell viability (>95%) Fast printing speed High resolution (10–50 µm) High cost Long-term effects of laser unclear [ 11 , 20 , 21 , 33 ] Stereolithography Uses UV light to solidify bio-ink layer-by-layer Fast printing speed High resolution Excellent cell adhesion …”

Section: Bioprinting: Methods and Materialsmentioning

confidence: 99%

3D Bioprinting for Next-Generation Personalized Medicine

Lam

Zhu

et al. 2023

IJMS

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In the past decade, immense progress has been made in advancing personalized medicine to effectively address patient-specific disease complexities in order to develop individualized treatment strategies. In particular, the emergence of 3D bioprinting for in vitro models of tissue and organ engineering presents novel opportunities to improve personalized medicine. However, the existing bioprinted constructs are not yet able to fulfill the ultimate goal: an anatomically realistic organ with mature biological functions. Current bioprinting approaches have technical challenges in terms of precise cell deposition, effective differentiation, proper vascularization, and innervation. This review introduces the principles and realizations of bioprinting with a strong focus on the predominant techniques, including extrusion printing and digital light processing (DLP). We further discussed the applications of bioprinted constructs, including the engraftment of stem cells as personalized implants for regenerative medicine and in vitro high-throughput drug development models for drug discovery. While no one-size-fits-all approach to bioprinting has emerged, the rapid progress and promising results of preliminary studies have demonstrated that bioprinting could serve as an empowering technology to resolve critical challenges in personalized medicine.

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“…To fabricate long vasculatures with affordable systems in laboratories [38][39][40][41][42][43][44][45][46][47][48], direct extrusion techniques were developed by different research groups. The developed microfluidic devices usually induce coaxial laminar flow and simultaneously encapsulate vascular cells in hydrogels, such as decellularised extracellular matrix [49,50], type-I collagen [39], calcium alginate [51][52][53], a mixture of collagen and alginate [50,54], and customised gelatine methacryloyl (GelMA) [55].…”

Section: Introductionmentioning

confidence: 99%

Double-layered blood vessels over 3 mm in diameter extruded by the inverse-gravity technique

Duong,

Nguyen,

Phan

et al. 2023

Biofabrication

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One of the most promising techniques for treating severe peripheral artery disease is the use of cellular tissue-engineered vascular grafts (TEVGs). This study proposes an inverse-gravity (IG) extrusion technique for creating long double-layered cellular TEVGs with diameters over 3 mm. A three-layered coaxial laminar hydrogel flow in an 8 mm-diameter pipe was realized simply by changing the extrusion direction of the hydrogel from being aligned with the direction of gravity to against it. This technique produced an extruded mixture of human aortic smooth muscle cells (HASMCs) and Type-I collagen as a tubular structure with an inner diameter of 3.5 mm. After a 21-day maturation period, the maximal burst pressure, longitudinal breaking force, and circumferential breaking force of the HASMC TEVG were 416 mmHg, 0.69 N, and 0.89 N, respectively. The HASMC TEVG was endothelialized with human umbilical vein endothelial cells to form a tunica intima that simulated human vessels. Besides subcutaneous implantability on mice, the double-layered blood vessels showed a considerably lower adherence of platelets and red blood cells once exposed to heparinized mouse blood and were considered nonhemolytic. The proposed IG extrusion technique can be applied in various fields requiring multilayered materials with large diameters.

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Angiogenesis in Free-Standing Two-Vasculature-Embedded Scaffold Extruded by Two-Core Laminar Flow Device

Cited by 5 publications

References 65 publications

Ultrasound standing wave spatial patterning of human umbilical vein endothelial cells for 3D micro-vascular networks formation

Ultrasound standing wave spatial patterning of human umbilical vein endothelial cells for 3D micro-vascular networks formation

3D Bioprinting for Next-Generation Personalized Medicine

Double-layered blood vessels over 3 mm in diameter extruded by the inverse-gravity technique

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