PREPARATION AND CHARACTERIZATION OF AN ELECTROSPUN GELATIN/DENDRIMER HYBRID NANOFIBER DRESSING

Smith-Freshwater, Alicia P.

14 August 2009

A novel dendritic wound dressing was designed and characterized for its potential to treat chronic wounds. Comprised of gelatin, dendrimer, synthetic polymer and antibiotics, the dressing was electrospun to mimic the natural extracellular matrix (ECM). Gelatin is biocompatible, biodegradable, non-toxic, and easily available. The antibiotic, doxycycline, has the ability to inhibit matrix metalloproteinases. Matrix metalloproteinases, which occur in excess in chronic wounds, degrade the reconstituted ECM. Starburst™ polyamidoamine (PAMAM) dendrimer G3.5, which provides a versatile and structurally controlled architecture to construct nanomedicine, was covalently bonded to the gelatin backbone and electrospun into nanofibers with gelatin, doxycycline and stabilizing polymers. The proposed gelatin/dendrimer hybrid provides a bacterial free environment and mimics the ECM to promote wound healing. The development of this new polymeric matrix is an important step in advancing the use of bioactive nanofibers with targeted and controlled drug delivery as a wound dressing.

PAMAM dendrimer

electrospinning

gelatin wound dressing

Engineering

ANGIOGENIC POTENTIAL OF HUMAN MACROPHAGES ON ELECTROSPUN BIORESORBABLE VASCULAR GRAFTS

Garg, Koyal

11 November 2008

The aim of this study was to investigate macrophage interactions with electrospun scaffolds and quantify the expression of vital angiogenic growth factors in vitro. This study will further help in evaluating the potential of these electrospun constructs as vascular grafts for tissue repair and regeneration in situ. Human peripheral blood macrophages were seeded in serum free media on electrospun (10 mm) discs of polydioxanone (PDO), elastin and PDO:elastin blends (50:50, 70:30 and 90:10). The growth factor secretion was analyzed by ELISA. Macrophages produced high levels of vascular endothelial growth factor (VEGF) and acidic fibroblast growth factor (aFGF). Transforming growth factor beta-1 (TGF-β1) secretion was relatively low and there was negligible production of basic fibroblast growth factor (bFGF). Histology revealed direct correlation between cell infiltration into scaffolds and the PDO concentration. There was greater macrophage infiltration through fibrous networks of the PDO and 90:10 scaffolds. Therefore, it can be anticipated that these scaffolds will support tissue regeneration and angiogenesis.

Angiogenesis

electrospinning

macrophages

biomaterials

Engineering

DEVELOPMENT OF MAGNETIC FABRICS WITH TUNABLE HYDROPHOBICITY

Ho, Thu

27 July 2012

Polystyrene (PS) fiber mats incorporating iron (Fe) particles were fabricated by electrospinning and the hydrophobicity of the resulting magnetic fabrics was investigated with and without an applied magnetic field. The results show that the hydrophobicity (as measured using water droplet contact angle) increases in the presence of a magnetic field and the hysterisis in the advancing/receding contact angle (a measure of the stickiness of the surface) decreases in the presence of a magnetic field. It is also shown that the contact angle and hysterises increase with decreasing fiber diameter and mat thickness.

superhydrophobic

polystyrene

magnetic particles

contact angle

hysteresis

electrospinning

fiber

Engineering

REGENERATION OF ELECTROSPUN BIORESORBABLE VASCULAR GRAFTS: A PHENOMENON ASSOCIATED WITH VASCULAR GRAFT PROPERTIES AND MACROPHAGE PHENOTYPES (M1/M2)

Garg, Koyal

01 January 2012

Macrophages (MФ) and mast cells are important cell types in the context of tissue remodeling and regeneration. Mast cells participate in the early stages of wound healing and modulate the acute inflammatory responses to biomaterials. Mast cells can secrete a myriad of different cytokines by the process of degranulation; the process of regulated secretion in which preformed contents stored in their granules are rapidly released by exocytosis. Some of these cytokines such as IL-4, IL-13 and TNF-α can modulate the MФ phenotype. Macrophages (MΦ) are innate immune cells, crucial for tissue homeostasis, presentation of foreign and self-antigens following infection/injury, pathogen clearance, inflammation resolution, angiogenesis, and wound healing. MΦ display plasticity and can acquire pro-inflammatory (M1) or angiogenic/wound healing (M2) phenotypes depending upon the environmental stimuli. The phenotypic profile of MФ as M1 or M2 following exposure to the biomaterial can dictate the downstream processes of tissue remodeling and angiogenesis. An analysis of how these two cell types interact with electrospun biomaterials and how different properties of an electrospun biomaterial impacts the MΦ phenotype is the focus of this thesis. Mast cells synthesize several potent angiogenic factors and can also stimulate fibroblasts, endothelial cells and macrophages. An understanding of how they participate in wound healing and angiogenesis is important to further our knowledge about in situ vascular prosthetic regeneration. The adhesion, proliferation and cytokine secretion of bone marrow derived murine mast cells (BMMC) on electrospun polydioxanone (PDO), polycaprolactone (PCL) and silk scaffolds, as well as tissue culture plastic (TCP) has been investigated in the presence or absence of IL-3, SCF, IgE and IgE with a crosslinking antigen, dinitrophenol-conjugated albumin (DNP). It was previously believed that only activated BMMCs exhibit adhesion and cytokine secretion. However, this study shows non-activated BMMC adhesion to electrospun scaffolds. Silk scaffold was not found to be conducive for mast cell adhesion and cytokine secretion. Activation by IgE and DNP significantly enhanced mast cell adhesion, proliferation, migration and secretion of TNF-α, MIP-1α and IL-13. This indicates that mast cells might play a role in MФ polarization (M1/M2), biomaterial integration into the host tissue, regeneration, and possibly angiogenesis. In the next study, bone marrow derived murine macrophages (BMMΦs, 106 cells) were seeded on TCP (24 well plate) and PDO scaffolds (15 mm discs) electrospun from varying polymer concentrations (60, 100, and 140 mg/ml). Scaffold evaluation showed that large polymer concentrations led to larger fiber diameters, which in turn led to larger pore-sizes and porosity but a smaller surface area to volume ratio. After 24 hrs of culture, the cell lysates were analyzed for Arginase (Arg1) and inducible nitric oxide synthase (iNOS) expression by western blot and cell culture supernatants were analyzed for Nitric oxide (NO2-), Tumor Necrosis Factor – alpha (TNF-α), Interleukin-6 (IL-6), Vascular Endothelial Growth Factor (VEGF), Transforming Growth Factor – beta1 (TGF-β1) and basic fibroblast growth factor (bFGF) levels. The results indicated a correlation between Arg1 expression and increasing fiber/pore-size, indicating that the larger fiber/pore-sizes polarize towards a M2 phenotype. Also, the expression of iNOS was downregulated on the larger fiber/pore-size. The levels of NO2- were significantly higher on the lower fiber/pore-sizes indicating an M1 phenotype. The levels of VEGF, TGF-β1 and bFGF increased with increasing fiber/pore-sizes. The results showed higher Arg1 expression in M2s on the 60 mg/ml scaffold created by the air-flow impedance method compared to the 60 mg/ml scaffold created on the solid mandrel created by traditional electrospinning. The Arg1 expression was reduced on the compressed 140 mg/ml PDO scaffold compared to the normal 140 mg/ml scaffold. This result indicates that pore-size might be playing a greater role compared to fiber diameter in BMMФ phenotype modulation. In order to assess the angiogenic potential of BMMΦs cultured on PDO scaffolds, a 3D angiogenesis bead assay was performed using conditioned media from the BMMΦ:PDO interaction. The results of the 3D angiogenesis bead assay showed that the conditioned media from BMMΦs of M0 and M2 phenotypes cultured on the 140 mg/ml PDO scaffold induced larger sprouting and higher percentage density of sprouts when compared to the 60 mg/ml PDO scaffold and TCP. To investigate the signaling mechanism involved in this phenotypic switch, BMMΦs were isolated from the bone marrow of MyD88 knockout (KO) mice (Jackson Laboratories) and cultured on PDO (60 and 140 mg/ml) scaffolds (106 /disc) and TCP for 24 hrs and their Arg1 and iNOS expression was analyzed by western blot. The expression of Arg1 and iNOS was severely impaired on the BMMΦs from MyD88-/- mice cultured on the 140 mg/ml scaffold when compared to the 60 mg/ml PDO scaffold and TCP. This result indicates that scaffolds with different fiber/pore-sizes signal differently. A subcutaneous mouse model (described in Chapter 6) was used to evaluate the angiogenic and regenerative potential of PDO scaffolds in vivo. The DIVAA assay showed statistically higher FITC-dextran signal intensity for the 140 mg/ml scaffold compared to the 60 mg/ml scaffold indicating greater angiogenic response in the 140 mg/ml tube. However, problems of high background were observed in this assay with the use of electrospun PDO. The observed high background was probably due to the formation of complexes between dextran and adsorbed plasma proteins on the surface of the PDO. More studies are needed to optimize this assay for use with biomaterials such as PDO. H&E staining of the harvested PDO tubes (60 mg/ml and 140 mg/ml) was also performed. The cross-sections of these tubes showed greater cell recruitment and infiltration into the fibrous structures of the 140 mg/ml tube compared to the 60 mg/ml tube. This result corroborates the in vitro result of BMMФ infiltrating deeper into the structures of the 140 mg/ml scaffold compared to the 60 mg/ml scaffold. The scaffolds were also analyzed by immunostaining for iNOS (indicative of M1 phenotype of MФs). The results showed statistically higher ratios of iNOS positive:negative areas on the 60 mg/ml scaffold compared to the 140 mg/ml scaffold. Overall, these studies indicate that 140 mg/ml scaffold supports greater cell recruitment and cell infiltration in vivo but a smaller ratio of iNOS positive:negative areas compared to the 60 mg/ml scaffold, which supports a predominately M1 MФ phenotype. The studies indicate that varying properties of PDO can alter both the phenotype and function of BMMΦs in vitro and in vivo. We have also shown that the 140 mg/ml scaffold signal BMMΦs through MyD88-dependent mechanisms. A complete understanding of the way materials signal would allow us to control or modulate undesirable immune reactions to biomaterials in vivo. These studies would also help engineer biomaterials that promote angiogenesis and regeneration.

Macrophages

electrospinning

angiogenesis

mast cells

Engineering

Electrospinning as a Processing Method for Electroactive Polymers and Composites

Pawlowski, Kristin Joy

01 January 2004

Electrospinning was examined for its potential to create functional materials. Three distinct electroactive materials were electrospun into fibers and fiber mats and then characterized with the intent of determining their utility in aerospace and biomedical applications such as micro-air vehicles and the cardiovascular system. Electrospun Graft Elastomers demonstrated potential as actuators, as electromechanical strain testing showed comparable response to the film form of this material. Further improvement of electroactive response was realized with high dielectric inclusions and fiber orientation. Electrospin processing imparted piezoelectric properties to the fibers of poly(vinylidene fluoride). Differential scanning calorimetry and infrared spectroscopy indicated a degree of control over crystalline phase in poly(vinylidene fluoride) fibers based on electrospinning conditions. An increase in dielectric constant in the direction of fiber orientation proved that electrospinning also caused alignment of single-walled carbon nanotubes within the fibers. Ultem®/aligned single-walled carbon nanotube fiber nanocomposites were also fabricated; these showed evidence of enhanced piezoelectric strain response relative to fibers composed of the matrix alone. Thermal and static mechanical testing of all three types of fibers revealed no significant findings that would limit their use in abovementioned applications. Extract biocompatibility tests did not indicate severe adverse reaction of L929 mouse fibroblast cells to fiber mats for either Graft Elastomers or poly(vinylidene fluoride). These contributions prove that functional electroactive materials can be produced utilizing electrospinning as the processing method. This technique is simpler and cheaper to carry out, and resulting fiber mats showed comparable or improved properties and performance compared to other physical forms of the same materials.

Ultem

GE

electrospinning

PVDF

Engineering

Novel Small Airway Model Using Electrospun Decellularized Lung Extracellular Matrix

Young, Bethany M

01 January 2016

Chronic respiratory diseases affects many people worldwide with little known about the mechanisms diving the pathology, making it difficult to find a cure. Improving the understanding of smooth muscle and extracellular matrix (ECM) interaction is key to developing a remedy to this leading cause of death. With currently no relevant or controllable in vivo or in vitro model to investigate diseased and normal interactions of small airway components, the development of a physiologically relevant in vitro model with comparable cell attachment, signaling, and organization is necessary to develop new treatments for airway disease. The goal of this study is to create a mechanically, biologically and structurally relevant in vitro model of small airway smooth muscle tissue. Synthetic Poly-L-Lactic Acid (PLLA) and decellularized pig lung ECM (DPLECM) were electrospun to form nanofibrous mats that can closely mimic natural bronchial tissue. The addition of DPLECM significantly changed the PLLA scaffold mechanically, biologically, and physically to bring it closer to the characteristics of the human lung. DPLECM scaffolds exhibited a significant decrease in the elastic modulus compared with PLLA alone. Histological staining and SDS-PAGE showed that after scaffold fabrication, essential proteins or protein fragments in natural ECM are still present after processing. Human bronchial smooth muscle cells (HBSMCs) seeded onto PLECM scaffolds formed multiple layers of cells compared to scaffolds composed solely of PLLA. Phenotype of smooth muscle is better maintained when DPLECM is incorporated into the scaffold shown by enhanced contractile protein expression and increased collagen production for normal smooth muscle remodeling of the scaffold. In summary, this research demonstrates that a PLLA/DPLECM composite electrospun mat is a promising tool to produce an in vitro model with the potential to uncover unknown characteristics of bronchiole smooth muscle behavior in diseased or normal states.

Extracellular Matrix

Electrospinning

Decellularized

Lung

Pulmonary

Morphology-driven superhydrophobic polystyrene webs: fabrication and characterization

Yuan, Yue

January 1900

Master of Science / Department of Apparel, Textiles, and Interior Design / Jooyoun Kim / Seong-O Choi / Superhydrophobicity (water contact angle, WCA >150˚) can be achieved by introducing surface roughness and decreasing surface energy. Polystyrene (PS) electrospun web can be used as an excellent substrate for superhydrophobic surface due to its low surface energy (~33 mN/m) and processibility to form various roughness. As the Cassie-Baxter model explains, the presence of roughness amplifies anti-wettability of materials whose surface energy is low (hydrophobic, WCA >90˚). This study aims to fabricate superhydrophobic PS nonwoven webs by electrospinning process and vapor deposition of 1H,1H,2H,2H-perfluorodecyltrichlorosilane (PFDTS) and to investigate the influence of fiber morphology and surface energy on wettability. To this end, PS webs with various fiber morphologies were electrospun under different polymer concentrations and solvent mixtures. PS substrates were treated by air plasma to attach –OH groups before the vapor deposition of PFDTS. Air plasma treatment itself increased the surface energy of PS; however, with PFDTS coating, the surface energy was decreased. The wettability was characterized by WCA and sliding angle measurement. WCAs on the electrospun webs were greater than that of flat PS film (WCA=95˚) due to the increased roughness of the web. The web with beads or grooved fibers achieved superhydrophobicity (WCA>150˚). PFDTS deposition lowered the surface energy of PS surface to about 15.8 mN/m. PS web with PFDTS deposition presented high water contact angle up to 169˚ and low sliding angle about 3˚. Also it was attempted to characterize the interfacial area between water and a solid surface on irregular fibrous webs. The fraction of solid surface area wet by the liquid (solid fraction) was observed by staining the rough electrospun web with a hydrophobic fluorescent dye, coumarin. The actual solid fraction corresponded fairly well with the theoretical solid fraction calculated by the Cassie-Baxter equation, demonstrating that the treated superhydrophobic surface follows the Cassie-Baxter wetting state.

Electrospinning

Superhydrophobic

Polystyrene

Surface energy

Fiber morphology

Solid area fraction

Electrospun Separator for Structural Battery Applications

Keaswejjareansuk, Wisawat

23 April 2019

Lithium-ion battery (LIB) is widely utilized in many modern applications as energy sources. Numerous efforts have been dedicated to increasing electrochemical performances, but improvement on battery safety remains a visible challenge. While new electrode materials have been developed, advancement in new separator for LIB has remained relatively slow. Separator is the polymeric porous material that physically separates electrodes and allows free flow of ions through its structure. It is electrochemically inactive but essential for avoiding thermal runaway conditions. Besides its crucial functions, separator has been known as the mechanically weakest component. Structural battery is a new approach that employs multifunctional material concept to use LIB as load-bearing material to minimize the weight of the complete system and maximize the efficiency. Separator materials are required to have good thermal stability, battery chemistry, and mechanical performance. This work aims at creating electrospun membranes with improved thermal resistance, structural integrity and moderate ionic conductivity as the next generation LIB separators. Electrospinning process is known as a versatile and straightforward technique to fabricate continuous fibers at nano- and micro- scales. The electrospinning process employs an electrostatic force to control the production of fibers from polymer solutions. Solution and process parameters, including type of polymer and solvent system, concentration of polymer solution, acceleration voltage, and solution feed rate, have been studied to achieve the desirable membrane properties. In this report, the electrospinning parameters affecting morphology and corresponding properties of electrospun membranes, electrospun polymer composite and polymer-metal oxide composite membranes for structural battery applications will be discussed.

electrospinning

fiber

lithium-ion battery

separator

structural battery

Produção e caracterização de scaffolds de diferentes espessuras obtidos por eletrofiação de nanofibra polimérica e proteína. / Production and characterization of electrospun polymeric-protein nanofiber scaffolds with different thicknesses.

Kimura, Vanessa Tiemi

26 September 2017

A engenharia tecidual visa repor, reparar ou ajudar a regenerar tecidos e órgãos danificados por meio da combinação de biomateriais, biomoléculas e células. Scaffolds de nanofibras biodegradáveis mimetizam a matriz extracelular natural fornecendo uma estrutura ideal para o crescimento celular. Blendas de policaprolactona (PCL) e gelatina são biodegradáveis e proporcionam uma combinação de boas propriedades mecânicas, do PCL, com a hidrofilicidade e caráter que promove a adesão celular, da gelatina. Neste contexto, o objetivo deste trabalho é avaliar a importância das diferentes espessuras de scaffolds eletrofiados em relação às suas propriedades principais. Quatro conjuntos de scaffolds de PCL/gelatina com diferentes espessuras foram produzidos sob as mesmas condições apenas aumentando o tempo de duração do processo de eletrofiação. Os resultados indicam que as espessuras aumentaram proporcionalmente ao tempo de eletrofiação, variando de 100 nm a 300 nm nos períodos de 1 a 3 horas, enquanto a densidade aparente e a porosidade mantiveram-se constantes. As micrografias das membranas revelaram fibras lisas com diâmetros maiores para os scaffolds de menor espessura, e fibras irregulares com diâmetros menores e regiões fundidas ou ligadas para os scaffolds de maior espessura. Além disso, o aumento da espessura melhorou a resistência mecânica e a molhabilidade dos scaffolds. A esterilização por peróxido de hidrogênio não modificou quimicamente a composição das membranas de PCL/gelatina, embora algumas amostras tenham se deformado. As membranas também apresentaram bons resultados de citotoxicidade, melhorando a viabilidade celular, apesar desses valores diminuírem minimamente para os scaffolds de maior espessura, provavelmente devido à maior quantidade de PCL. O teste de adesão não foi conclusivo e deverá ser repetido. / Tissue engineering aims to replace, repair, or helping regenerate damaged tissues and organs through the combination of biomaterials, biomolecules and cells. Biodegradable nanofibrous scaffolds mimic the natural extracellular matrix providing an ideal structure to cellular growth. Blends of polycaprolactone (PCL) and gelatin are biodegradable and provide a combination of good mechanical properties, from PCL, with the hydrophilicity and cell adhesion promoter character, from gelatin. The aim of this work was to evaluate the importance of the thickness of electrospun scaffolds on their key properties. Four sets of PCL/gelatin scaffolds with different thicknesses were produced under the same conditions by simply increasing the time length of electrospinning process. Results indicate that the thickness increases proportionally to the electrospinning time, varying from 100 nm to 300 nm in periods of 1 to 3 hours, while the apparent density and porosity remained constant. Micrographs from the nonwoven mats revealed smooth fibers with larger diameters in the thinner scaffold, and irregular fibers with smaller diameters and molten or bonded regions as the thickness increased. Furthermore, the increase of thickness improved mechanical resistance and wettability of the scaffolds. Plasma sterilization did not modify chemical composition of PCL/gelatin membranes, although some samples have been deformed. Membranes also presented good results for cytotoxicity, improving cell viability, despite these values decreased minimally to the thicker scaffolds, probably due to the higher amount of PCL. Adhesion test was not conclusive and might be repeat.

Biomaterials

Electrospinning

Engenharia tecidual

Materiais nanoestruturados

Nanofibers

Scaffold

Tissue engineering

Novel scaffolds for spinal cord repair

Kraemer, Marina

January 2013

Injuries to the central nervous system (CNS) have traumatic consequences such as irreparable disability due to the inability of the CNS to regenerate injured nerve fibres. The aim of the work presented here was to develop a scaffold which potentially provides guidance to axons in the injured spinal cord thus facilitating signal transduction. A poly-(lactic-co-glycolic acid) (PLGA, PLA:PGA ratio of 75:25) flat sheet membrane scaffold was created using phase inversion with N-methyl pyrrolidinone (NMP) as the solvent and water as the non-solvent for immersion precipitation. PLGA flat sheet membranes were exposed to surface treatments including aminolysis, peptide immobilisation and ozonation in order to achieve higher cell attachment of PC12 cells, a cell line which was cloned from a solid pheochromocytoma tumour of white rats, and used as a tool for measurement of regeneration. Cell attachment studies revealed no significant difference in cell attachment between modified and not-modified PLGA flat sheet membranes. However, the absence of foetal calf serum (FCS) resulted in fivefold higher cell attachment compared to medium supplemented with 10% FCS. A second scaffold was produced by electrospinning 10% (w/w) PLGA in a chloroform:methanol (CHCl3:MeOH) mixture in ratio of 3:1 resulting in a nanofibrous scaffold. Optimum settings for electrospinning were found to be 3 ml/h feeding rate, 15kV applied voltage and 11cm collector-to-needle distance. Random and aligned PLGA nanofibres were produced, with a fibre diameter of 530±140nm. PC12 cells attached and differentiated to the nanofibrous scaffold. When exposed to NGF these cells stopped dividing and extended neurites. On random fibres, neurite orientation was random, whereas on aligned fibres 63% of neurites grew with the fibre orientation ±15��ᵒ. After 7 days of exposure to NGF, cells had 1-4 neurites on random fibres, reaching a maximum length of 188μm, whereas on aligned fibres, cells had 1-2 neurites, reaching a maximum length of 400μm. PLGA nanofibres were also investigated as a delivery vehicle for bioactive molecules. For this, poly-L-lysine (PLL) was incorporated into electrospun PLGA nanofibres via emulsion electrospinning. PLGA-PLL nanofibres were significantly larger than PLGA nanofibres having a diameter of 830±190nm. In order to visualise the incorporation of PLL, FITC-PLL was electrospun und the resulting nanofibres fluoresced greed. Attachment of PC12s to PLGA-PLL nanofibres was not significantly different compared to PLGA nanofibres. Aligned PLGA-PLL nanofibres were shown to promote neurite outgrowth of PC12s with resulting neurites of up to twice the length compared to aligned PLGA nanofibres. The results suggest that PLGA nanofibres strongly influences neurite organisation, which is potentially useful for future therapeutic approaches. The work in this thesis has shown that electrospun PLGA nanofibre mats have the potential to be used as scaffolds for spinal cord repair addressing topographical guidance and delivery of bioactive molecules to the site of injury.

617.482044