Multilayered blow-spun vascular prostheses with luminal surfaces in Nano/Micro range: the influence on endothelial cell and platelet adhesion

Łopianiak, Iwona; Rzempołuch, Wiktoria; Civelek, Mehtap; Cicha, Iwona; Ciach, Tomasz; Butruk-Raszeja, Beata A.

doi:10.1186/s13036-023-00337-9

Cited by 5 publications

(5 citation statements)

References 52 publications

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“…Representative SEM images of materials surface morphology (Figures 2−4) show typical morphology of fibrous PU materials produced by SBS method, characterized by the presence of fibers and single defects in the form of stains. 28,32,34 There were no significant differences in the fiber alignment, depending on the rotation speed of the collector in materials with an average fiber diameter of 200 nm (Figure 2). Differences in fiber alignment appeared in the SEM images of the materials with average fiber diameters of 500 and 1000 nm.…”

Section: Fiber Alignmentmentioning

confidence: 95%

“…Due to their high mechanical strength and degradation rate, PUs are attractive materials for tissue engineering applications, especially in vascular graft designing,. − Solution blow spinning (SBS) is an emerging technique for fiber production that allows the fabrication of morphologically various well-controlled fibrous architectures that are increasingly used in tissue engineering . The properties of fibrous materials produced using this method can be easily customized to meet the requirements of tissue engineering applications. , Heart, bone, skin, and vascular scaffolds have been widely produced using SBS. ,− …”

Section: Introductionmentioning

confidence: 99%

“…Several studies have been performed to define the influence of SBS process parameters, such as the polymer solution concentration, gas pressure, polymer solution flow rate, rotation speed of the collector, working distance, and nozzle design, on the fiber and fibrous material properties. , It was concluded that there are dependent characteristics for each parameter (e.g., solution concentration influences fiber diameter and pore size, increasing the collector rotational speed results in fiber orientation, and reducing the working distance reduces the porosity of the material), although the final properties of the fibrous scaffold result from the utilized polymer and the overall combination of all process parameters.…”

Section: Introductionmentioning

confidence: 99%

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Characterization of Blow-Spun Polyurethane Scaffolds–Influence of Fiber Alignment and Fiber Diameter on Pericyte Growth

Łopianiak,

Kawecka,

Civelek

et al. 2024

ACS Biomater. Sci. Eng.

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In this study, fibrous polyurethane (PU) materials with average fiber diameter of 200, 500, and 1000 nm were produced using a solution blow spinning (SBS) process. The effects of the rotation speed of the collector (in the range of 200−25 000 rpm) on the fiber alignment and diameter were investigated. The results showed that fiber alignment was influenced by the rotation speed of the collector, and such alignment was possible when the fiber diameter was within a specific range. Homogeneously oriented fibers were obtained only for a fiber diameter ≥500 nm. Moreover, the changes in fiber orientation and fiber diameter (resulting from changes in the rotation speed of the collector) were more noticeable for materials with an average fiber diameter of 1000 nm in comparison to 500 nm, which suggests that the larger the fiber diameter, the better the controlled architectures that can be obtained. The porosity of the produced scaffolds was about 65−70%, except for materials with a fiber diameter of 1000 nm and aligned fibers, which had a higher porosity (76%). Thus, the scaffold pore size increased with increasing fiber diameter but decreased with increasing fiber alignment. The mechanical properties of fibrous materials strongly depend on the direction of stretching, whereby the fiber orientation influences the mechanical strength only for materials with a fiber diameter of 1000 nm. Furthermore, the fiber diameter and alignment affected the pericyte growth. Significant differences in cell growth were observed after 7 days of cell culture between materials with a fiber diameter of 1000 nm (cell coverage 96−99%) and those with a fiber diameter of 500 nm (cell coverage 70−90%). By appropriately setting the SBS process parameters, scaffolds can be easily adapted to the cell requirements, which is of great importance in producing complex 3D structures for guided tissue regeneration.

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Section: Fiber Alignmentmentioning

confidence: 95%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Characterization of Blow-Spun Polyurethane Scaffolds–Influence of Fiber Alignment and Fiber Diameter on Pericyte Growth

Łopianiak,

Kawecka,

Civelek

et al. 2024

ACS Biomater. Sci. Eng.

Self Cite

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“…The blow-spun mats showed a 3D fibrous porous structure similar to that of the ECM of mammalian tissue. More recently, Łopianiak et al developed non-thrombogenic vascular grafts based on PU by means of a multistep SBS method [127]. The influence of the luminal surface morphology on platelet adhesion and the attachment of endothelial cells was investigated by changing the morphology of the fibers according to the SBS processing parameters (mainly working distance, rotational speed, and polymer concentration).…”

Section: Drug Delivery and 3d Culturesmentioning

confidence: 99%

“…Neither micro nor nanofibers caused hemolysis in contact with blood, and the percentage of plateletoccupied areas for both types of surfaces was comparable to the reference polytetrafluoroethylene (PTFE), used in vascular implants and favored the growth and differentiation of endothelial cells. More recently, Łopianiak et al developed non-thrombogenic vascular grafts based on PU by means of a multistep SBS method [127]. The influence of the luminal surface morphology on platelet adhesion and the attachment of endothelial cells was investigated by changing the morphology of the fibers according to the SBS processing parameters (mainly working distance, rotational speed, and polymer concentration).…”

Section: Drug Delivery and 3d Culturesmentioning

confidence: 99%

Advances in Biomedical Applications of Solution Blow Spinning

Carriles,

Nguewa,

González-Gaitano

2023

IJMS

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In recent years, Solution Blow Spinning (SBS) has emerged as a new technology for the production of polymeric, nanocomposite, and ceramic materials in the form of nano and microfibers, with similar features to those achieved by other procedures. The advantages of SBS over other spinning methods are the fast generation of fibers and the simplicity of the experimental setup that opens up the possibility of their on-site production. While producing a large number of nanofibers in a short time is a crucial factor in large-scale manufacturing, in situ generation, for example, in the form of sprayable, multifunctional dressings, capable of releasing embedded active agents on wounded tissue, or their use in operating rooms to prevent hemostasis during surgical interventions, open a wide range of possibilities. The interest in this spinning technology is evident from the growing number of patents issued and articles published over the last few years. Our focus in this review is on the biomedicine-oriented applications of SBS for the production of nanofibers based on the collection of the most relevant scientific papers published to date. Drug delivery, 3D culturing, regenerative medicine, and fabrication of biosensors are some of the areas in which SBS has been explored, most frequently at the proof-of-concept level. The promising results obtained demonstrate the potential of this technology in the biomedical and pharmaceutical fields.

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Magnetically Controlled Strategies for Enhanced Tissue Vascularization

Zhu,

Xu,

Zhang

et al. 2024

Adv Funct Materials

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Tissue vascularization plays a critical role in the regeneration and repair of damaged tissues. However, in certain instances of tissue injury, the pace and effectiveness of vascularization can be limited. Innovative strategies leveraging magnetic fields and magnetic nanoparticles (MNPs) are devised to enhance the efficacy of tissue vascularization. This review explores the potential of magnetic field‐assisted strategies in augmenting tissue vascularization and repair. Direct application of static or dynamic magnetic fields, alone or in combination with MNPs, offers a means to modulate cellular behaviors and gene expression, thereby promoting angiogenesis and tissue regeneration. Techniques such as cell labeling, gene delivery using MNPs, and magnetic targeting have shown promise in efficiently repairing various ischemic tissue injuries by enhancing tissue vascularization. These strategies have broad applications in bone and skin tissue regeneration, limb ischemia treatment, myocardial injury treatment, and diabetic wound therapy. By summarizing recent advancements in magnetically controlled strategies, this review aims to shed light on their future prospects in tissue regeneration and clinical treatment.

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Multilayered blow-spun vascular prostheses with luminal surfaces in Nano/Micro range: the influence on endothelial cell and platelet adhesion

Cited by 5 publications

References 52 publications

Characterization of Blow-Spun Polyurethane Scaffolds–Influence of Fiber Alignment and Fiber Diameter on Pericyte Growth

Characterization of Blow-Spun Polyurethane Scaffolds–Influence of Fiber Alignment and Fiber Diameter on Pericyte Growth

Advances in Biomedical Applications of Solution Blow Spinning

Magnetically Controlled Strategies for Enhanced Tissue Vascularization

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