Complexation‐Induced Resolution Enhancement Pleiotropic Small Diameter Vascular Constructs with Superior Antibacterial and Angiogenesis Properties

Xu, Huilun; Liu, Zhengjiang; Yan, Wei; Hu, Yinchun; Zhao, Liqin; Wang, Long; Liang, Ziwei; Lian, Xiaojie; Chen, Weiyi; Wang, Jiucun; Yu, Zhaoyan; Ma, Xudong; Huang, Di

doi:10.1002/adhm.202301809

Cited by 4 publications

(6 citation statements)

References 47 publications

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“…Figure 2a displays the tensile stress−strain curves of the five groups of PCO hydrogels, and we can see that the tensile property is significantly influenced by the raw material ratio. As shown in Figure 2b, PCO-2 obtained the highest tensile strength of 0.75 ± 0.04 MPa and a tensile elastic modulus of 0.76 ± 0.02 MPa, being 1.4 times that of pure PVA hydrogel, far exceeding the PVA/alginate/charged chitosan artificial blood vessels 19 and bacterial nanocellulose/chitosan/heparin artificial blood vessels 35 reported to date. The loading− unloading cycling tests for 200 cycles with 20% strain at a constant tensile rate of 100 mm min −1 in Figures 2c, S4, and S5 further demonstrated that PCO-2 hydrogels have ideal elastic recovery, indicating their high tensile mechanical stability and fatigue resistance.…”

Section: Mechanical Properties Of Hydrogelsmentioning

confidence: 84%

“…Xu et al used a bioink mixture of alginate (Alg) and poly(vinyl alcohol) (PVA) for coaxial printing, and then the tube's outer surface was chemically modified with positively charged chitosan (CTS) through electrostatic interactions. 19 The modified PVA artificial blood vessel improved the biocompatibility, and no blockage occurred after 5 days of blood circulation in vitro. Anderson et al grafted the collagen-mimetic peptide onto PVA hydrogel surfaces by CDI chemistry.…”

Section: Introductionmentioning

confidence: 90%

“…Broadly speaking, there are two major classes of methods designed to enhance the blood compatibility of hydrogels. The first approach is modifying the inert surfaces of hydrogels by a wide variety of methods, such as surface-initiated polymerization, grafting, self-assembly, and surface coating techniques . The second approach is compositing with substances or blending with other bioactive polymers that have good antithrombogenicity and biocompatibility.…”

Section: Introductionmentioning

confidence: 99%

“…The blood compatibility of hydrogel membranes was significantly improved following the incorporation of heparin-mimicking SSNFs. Xu et al used a bioink mixture of alginate (Alg) and poly(vinyl alcohol) (PVA) for coaxial printing, and then the tube’s outer surface was chemically modified with positively charged chitosan (CTS) through electrostatic interactions . The modified PVA artificial blood vessel improved the biocompatibility, and no blockage occurred after 5 days of blood circulation in vitro.…”

Section: Introductionmentioning

confidence: 99%

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Dynamically Cross-Linked Double-Network Hydrogels with Matched Mechanical Properties and Ideal Biocompatibility for Artificial Blood Vessels

Jia,

Huang,

Meng

et al. 2024

ACS Appl. Mater. Interfaces

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Vessel transplantation is currently considered the "gold standard" treatment for cardiovascular disease. However, ideal artificial vascular grafts should possess good biocompatibility and mechanical strength that match those of native autologous vascular tissue to promote in vivo tissue regeneration. In this study, a series of dynamic cross-linking double-network hydrogels and the resultant hydrogel tubes were prepared. The hydrogels (named PCO), composed of rigid poly(vinyl alcohol) (PVA), flexible carboxymethyl chitosan (CMCS), and a cross-linker of aldehydebased β-cyclodextrin (OCD), were formed in a double-network structure with multiple dynamical cross-linking including dynamic imine bonds, hydrogen bonds, and microcrystalline regions. The PCO hydrogels exhibited superior mechanical strength, good network stability, and fatigue resistance. Additionally, it demonstrated excellent cell and blood compatibility. The results showed that the introduction of CMCS/OCD led to a significant increase in the proliferation rate of endothelial cells seeded on the surface of the hydrogel. The hemolysis rate in the test was lower than 0.3%, and both protein adsorption and platelet adhesion were reduced, indicating an excellent anticoagulant function. The plasma recalcification time test results showed that endogenous coagulation was alleviated to some extent. When formed into blood vessels and incubated with blood, no thrombus formation was observed, and there was minimal red blood cell aggregation. Therefore, this novel hydrogel tube, with excellent mechanical properties, exhibits antiadhesive characteristics toward blood cells and proteins, as well as antithrombotic properties, making it hold tremendous potential for applications in the biomedical and engineering fields.

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Section: Mechanical Properties Of Hydrogelsmentioning

confidence: 84%

Section: Introductionmentioning

confidence: 90%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Dynamically Cross-Linked Double-Network Hydrogels with Matched Mechanical Properties and Ideal Biocompatibility for Artificial Blood Vessels

Jia,

Huang,

Meng

et al. 2024

ACS Appl. Mater. Interfaces

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show abstract

“…Therefore, the development of novel biodegradable vascular grafts that provide suitable space, allowing cell proliferation, attachment, growth, migration on the scaffold, and subsequent formation of new blood vessels has become a research hotspot. ,− ,, However, novel vascular grafts still face several challenges, including postoperative infection, ,, excessive inflammatory response, , long-term patency, , and lack of nondestructive monitorability. , Significant advancements have been made in the development of a variety of scaffolds with distinct structures and compositions tailored to address the specific challenges mentioned above. For instance, Xu et al fabricated a decellularized CuSO 4 –Alg-PVA-CTS tubular vascular tissue engineering scaffold using coaxial 3D printing and post-treatment, which demonstrated synergistic antibacterial effects due to the release of Cu 2+ ions and the presence of CTS. Furthermore, the Cu 2+ ions were found to enhance EC proliferation and angiogenesis.…”

Section: Introductionmentioning

confidence: 99%

Customized Vascular Repair Microenvironment: Poly(lactic acid)-Gelatin Nanofibrous Scaffold Decorated with bFGF and Ag@Fe₃O₄ Core–Shell Nanowires

Yang,

Yuan,

Liao

et al. 2024

ACS Appl. Mater. Interfaces

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Vascular defects caused by trauma or vascular diseases can significantly impact normal blood circulation, resulting in serious health complications. Vascular grafts have evolved as a popular approach for vascular reconstruction with promising outcomes. However, four of the greatest challenges for successful application of small-diameter vascular grafts are (1) postoperative anti-infection, (2) preventing thrombosis formation, (3) utilizing the inflammatory response to the graft to induce tissue regeneration and repair, and (4) noninvasive monitoring of the scaffold and integration. The present study demonstrated a basic fibroblast growth factor (bFGF) and oleic acid dispersed Ag@Fe 3 O 4 core−shell nanowires (OA-Ag@Fe 3 O 4 CSNWs) codecorated poly(lactic acid) (PLA)/gelatin (Gel) multifunctional electrospun vascular grafts (bAPG). The Ag@Fe 3 O 4 CSNWs have sustained Ag + release and exceptional photothermal capabilities to effectively suppress bacterial infections both in vitro and in vivo, noninvasive magnetic resonance imaging (MRI) modality to monitor the position of the graft, and antiplatelet adhesion properties to promise long-term patency. The gradually released bFGF from the bAPG scaffold promotes the M2 macrophage polarization and enhances the recruitment of macrophages, endothelial cells (ECs) and fibroblast cells. This significant regulation of diverse cell behavior has been proven to be beneficial to vascular repair and regeneration both in vitro and in vivo. Therefore, this study supplies a method to prepare multifunctional vascularrepair materials and is expected to represent a significant guidance and reference to the development of biomaterials for vascular tissue engineering.

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Coaxial 3D Printing Enabling Mn/CHA@Pd/CHA Zeolite‐Based Core–Shell Monoliths for Efficient Passive NO_x Adsorbers

Li,

Wei,

Zhang

et al. 2024

Adv Funct Materials

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Pd‐based zeolites are extensively used as passive NOx adsorbers (PNA) for cold‐start NOx emissions to meet stringent emission regulations. However, optimizing adsorber design to reduce Pd usage with substitution by non‐noble metals that are prone to suffer from H2O remains a significant challenge. Herein, the core–shell Mn/CHA@Pd/CHA zeolite monoliths based on non‐noble metal/zeolite core are constructed using coaxial 3D printing technology and identified as efficient passive NOx adsorbers for the first time. In the Mn/CHA@Pd/CHA monolith, the Pd/CHA shell effectively protected the Mn active sites in the core from H2O, while the integration of the Mn/CHA core not only introduced efficient storage sites but also facilitated NOx desorption, thereby achieving comparable adsorption properties and increased the NOx desorption efficiency by 35% at 350 °C compared with that of Pd/CHA monolith. Furthermore, some non‐noble metal‐based zeolites (e.g., Co/CHA, Mn/MFI, Mn/BEA) and Pd‐based zeolites (e.g., Pd/AEI) are also employed as cores and shells respectively to fabricate a series of core–shell zeolite monoliths via coaxial 3D printing, highlighting the benefits of incorporating non‐noble metals into Pd‐based zeolites for improving adsorption and desorption behaviors. This work provides a promising strategy for designing cost‐effective PNA materials and contributes to improving the exhaust after‐treatment technology.

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Complexation‐Induced Resolution Enhancement Pleiotropic Small Diameter Vascular Constructs with Superior Antibacterial and Angiogenesis Properties

Cited by 4 publications

References 47 publications

Dynamically Cross-Linked Double-Network Hydrogels with Matched Mechanical Properties and Ideal Biocompatibility for Artificial Blood Vessels

Dynamically Cross-Linked Double-Network Hydrogels with Matched Mechanical Properties and Ideal Biocompatibility for Artificial Blood Vessels

Customized Vascular Repair Microenvironment: Poly(lactic acid)-Gelatin Nanofibrous Scaffold Decorated with bFGF and Ag@Fe₃O₄ Core–Shell Nanowires

Coaxial 3D Printing Enabling Mn/CHA@Pd/CHA Zeolite‐Based Core–Shell Monoliths for Efficient Passive NO_x Adsorbers

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Complexation‐Induced Resolution Enhancement Pleiotropic Small Diameter Vascular Constructs with Superior Antibacterial and Angiogenesis Properties

Cited by 4 publications

References 47 publications

Dynamically Cross-Linked Double-Network Hydrogels with Matched Mechanical Properties and Ideal Biocompatibility for Artificial Blood Vessels

Dynamically Cross-Linked Double-Network Hydrogels with Matched Mechanical Properties and Ideal Biocompatibility for Artificial Blood Vessels

Customized Vascular Repair Microenvironment: Poly(lactic acid)-Gelatin Nanofibrous Scaffold Decorated with bFGF and Ag@Fe3O4 Core–Shell Nanowires

Coaxial 3D Printing Enabling Mn/CHA@Pd/CHA Zeolite‐Based Core–Shell Monoliths for Efficient Passive NOx Adsorbers

Contact Info

Product

Resources

About

Customized Vascular Repair Microenvironment: Poly(lactic acid)-Gelatin Nanofibrous Scaffold Decorated with bFGF and Ag@Fe₃O₄ Core–Shell Nanowires

Coaxial 3D Printing Enabling Mn/CHA@Pd/CHA Zeolite‐Based Core–Shell Monoliths for Efficient Passive NO_x Adsorbers