Your search keyword '"Jessica D. Schiffman"' showing total 19 results

1. Effect of pH Value on the Electrical Properties of PEDOT:PSS-Based Fiber Mats

Author

Prerana Rathore and Jessica D. Schiffman

Subjects

Chemical engineering, TP155-156

Published

2023

2. Improved Recovery of Captured Airborne Bacteria and Viruses with Liquid-Coated Air Filters

Author

Daniel P. Regan, ChunKi Fong, Avery C. S. Bond, Claudia Desjardins, Justin Hardcastle, Shao-Hsiang Hung, Andrew P. Holmes, Jessica D. Schiffman, Melissa S. Maginnis, and Caitlin Howell

Subjects

Air Filters, Bacteria, SARS-CoV-2, Viruses, Humans, COVID-19, General Materials Science, Dust, Pandemics, Polytetrafluoroethylene, Article

Abstract

The COVID-19 pandemic has revealed the importance of the detection of airborne pathogens. Here, we present composite air filters featuring a bioinspired liquid coating that facilitates the removal of captured aerosolized bacteria and viruses for further analysis. We tested three types of air filters: commercial polytetrafluoroethylene (PTFE), which is well known for creating stable liquid coatings, commercial high-efficiency particulate air (HEPA) filters, which are widely used, and in-house-manufactured cellulose nanofiber mats (CNFMs), which are made from sustainable materials. All filters were coated with omniphobic fluorinated liquid to maximize the release of pathogens. We found that coating both the PTFE and HEPA filters with liquid improved the rate at which Escherichia coli was recovered using a physical removal process compared to uncoated controls. Notably, the coated HEPA filters also increased the total number of recovered cells by 57%. Coating the CNFM filters did not improve either the rate of release or the total number of captured cells. The most promising materials, the liquid-coated HEPA, filters were then evaluated for their ability to facilitate the removal of pathogenic viruses via a chemical removal process. Recovery of infectious JC polyomavirus, a nonenveloped virus that attacks the central nervous system, was increased by 92% over uncoated controls; however, there was no significant difference in the total amount of genomic material recovered compared to that of controls. In contrast, significantly more genomic material was recovered for SARS-CoV-2, the airborne, enveloped virus, which causes COVID-19, from liquid-coated filters. Although the amount of infectious SARS-CoV-2 recovered was 58% higher, these results were not significantly different from uncoated filters due to high variability. These results suggest that the efficient recovery of airborne pathogens from liquid-coated filters could improve air sampling efforts, enhancing biosurveillance and global pathogen early warning.

Published

2022

3. Robust, small diameter hydrophilic nanofibers improve the flux of ultrafiltration membranes

Author

Jessica D. Schiffman, Christopher A. Kuo-Leblanc, Jared W. Bowden, and Kerianne M. Dobosz

Subjects

chemistry.chemical_classification, Materials science, Base (chemistry), General Chemical Engineering, Ultrafiltration, General Chemistry, Industrial and Manufacturing Engineering, Electrospinning, Article, chemistry.chemical_compound, Membrane, chemistry, Chemical engineering, Nanofiber, Polysulfone, Cellulose, Flux (metabolism)

Abstract

In this study, we systematically investigated the flux performance of ultrafiltration (UF) membranes functionalized with randomly-accumulated nanofibers. By electrospinning nanofibers from hydrophobic polysulfone (PSf) and hydrophilic cellulose (CL), we were able to explore the role that bulk nanofiber (NF) layer thickness, individual NF diameter, and intrinsic chemistry have on composite membrane flux. Additional parameters that we systematically tested include the molecular weight cut-off (MWCO) of the base membrane (10, 100, and 200 kDa), flow orientation (cross-flow versus dead-end), and the feed solution (hydrophilic water versus hydrophobic oil). Structurally, the crosslinked PSf nanofibers were more robust than the CL nanofibers, which lead to the PSfNF-UF membranes having a greater flux performance. To decouple the structural robustness from the water affinity of the fibers, we chemically modified the PSf fibers to be hydrophilic and indeed, the flux of these new composite membranes featuring hydrophilic crosslinked nanofibers were superior. In summary, the greatest increase in flux performance arises from the smallest diameter, hydrophilic nanofibers that are mechanically robust (crosslinked). We have demonstrated that electrospun nanofiber layers improve the flux performance of ultrafiltration membranes.

Published

2021

4. Memristive behavior of mixed oxide nanocrystal assemblies

Author

Jessica D. Schiffman, Dylan M. Barber, Isabel Van Driessche, Pedro López-Domínguez, Alfred J. Crosby, Muhammad Abdullah, Jieun Park, Stephen S. Nonnenmann, Xiangxi Meng, Kevin R. Kittilstved, and Zimu Zhou

Subjects

MECHANISM, Fabrication, Materials science, SRZRO3, SWITCHING CHARACTERISTICS, perovskites, 02 engineering and technology, Electrochemistry, FILMS, 01 natural sciences, nanocrystals, 0103 physical sciences, General Materials Science, Thin film, memristor, Quantum tunnelling, 010302 applied physics, business.industry, resistive switching, Interface and colloid science, MEMORY, 021001 nanoscience & nanotechnology, DIFFUSION, solution-processed, Chemistry, BAZRO3, Sphere packing, Nanocrystal, Mixed oxide, Optoelectronics, LIGANDS, INJECTION, 0210 nano-technology, business

Abstract

Recent advances in memristive nanocrystal assemblies leverage controllable colloidal chemistry to induce a broad range of defect-mediated electrochemical reactions, switching phenomena, and modulate active parameters. The sample geometry of virtually all resistive switching studies involves thin film layers comprising monomodal diameter nanocrystals. Here we explore the evolution of bipolar and threshold resistive switching across highly ordered, solution-processed nanoribbon assemblies and mixtures comprising BaZrO3 (BZO) and SrZrO3 (SZO) nanocrystals. The effects of nanocrystal size, packing density, and A-site substitution on operating voltage (V-SET and V-TH) and switching mechanism were studied through a systematic comparison of nanoribbon heterogeneity (i.e., BZO-BZO vs BZO-SZO) and monomodal vs bimodal size distributions (i.e., small-small and small-large). Analysis of the current-voltage response confirms that tip-induced, trap-mediated space-charge-limited current and trap-assisted tunneling processes drive the low- and high-resistance states, respectively. Our results demonstrate that both smaller nanocrystals and heavier alkaline earth substitution decrease the onset voltage and improve stability and state retention of monomodal assemblies and bimodal nanocrystal mixtures, thus providing a base correlation that informs fabrication of solution-processed, memristive nanocrystal assemblies.

Published

2021

5. Localized characterization of brain tissue mechanical properties by needle induced cavitation rheology and volume controlled cavity expansion

Author

Alfred J. Crosby, Sualyneth Galarza, Krystyn J. Van Vliet, Jessica D. Schiffman, Tal Cohen, Aleksandar S. Mijailovic, Shelly R. Peyton, Nathan P. Birch, and Shabnam Raayai-Ardakani

Subjects

Materials science, Swine, Biomedical Engineering, Modulus, Young's modulus, 02 engineering and technology, Biomaterials, White matter, 03 medical and health sciences, symbols.namesake, 0302 clinical medicine, Rheology, Elastic Modulus, medicine, Animals, Gray Matter, Elastic modulus, Stiffness, Brain, 030206 dentistry, 021001 nanoscience & nanotechnology, White Matter, Stiffening, medicine.anatomical_structure, Mechanics of Materials, Cavitation, symbols, medicine.symptom, 0210 nano-technology, Biomedical engineering

Abstract

Changes in the elastic properties of brain tissue have been correlated with injury, cancers, and neurodegenerative diseases. However, discrepancies in the reported elastic moduli of brain tissue are persistent, and spatial inhomogeneities complicate the interpretation of macroscale measurements such as rheology. Here we introduce needle induced cavitation rheology (NICR) and volume-controlled cavity expansion (VCCE) as facile methods to measure the apparent Young's modulus E of minimally manipulated brain tissue, at specific tissue locations and with sub-millimeter spatial resolution. For different porcine brain regions and sections analyzed by NICR, we found E to be 3.7 ± 0.7 kPa and 4.8 ± 1.0 kPa for gray matter, and white matter, respectively. For different porcine brain regions and sections analyzed by VCCE, we found E was 0.76 ± 0.02 kPa for gray matter and 0.92 ± 0.01 kPa for white matter. Measurements from VCCE were more similar to those obtained from macroscale shear rheology (0.75 ± 0.06 kPa) and from instrumented microindentation of white matter (0.97 ± 0.40 kPa) and gray matter (0.86 ± 0.20 kPa). We attributed the higher stiffness reported from NICR to that method's assumption of a cavitation instability due to a neo-Hookean constitutive response, which does not capture the strain-stiffening behavior of brain tissue under large strains, and therefore did not provide appropriate measurements. We demonstrate via both analytical modeling of a spherical cavity and finite element modeling of a needle geometry, that this strain stiffening may prevent a cavitation instability. VCCE measurements take this stiffening behavior into account by employing an incompressible one-term Ogden model to find the nonlinear elastic properties of the tissue. Overall, VCCE afforded rapid and facile measurement of nonlinear mechanical properties of intact, healthy mammalian brain tissue, enabling quantitative comparison among brain tissue regions and also between species. Finally, accurate estimation of elastic properties for this strain stiffening tissue requires methods that include appropriate constitutive models of the brain tissue response, which here are represented by inclusion of the Ogden model in VCCE.

Published

2020

6. High-Performance, UV-Curable Crosslinked Films via Grafting of Hydroxyethyl Methacrylate Methylene Malonate

Author

Mengfei Huang, John Klier, Jessica D. Schiffman, and Yuan Liu

Subjects

Materials science, General Chemical Engineering, technology, industry, and agriculture, Thermosetting polymer, 02 engineering and technology, General Chemistry, (Hydroxyethyl)methacrylate, macromolecular substances, 021001 nanoscience & nanotechnology, Grafting, Industrial and Manufacturing Engineering, Article, chemistry.chemical_compound, Malonate, 020401 chemical engineering, chemistry, Polymer chemistry, Industrial maintenance, 0204 chemical engineering, Methylene, 0210 nano-technology

Abstract

Thermoset coatings have been used extensively to protect and enhance the appearance of substrates for industrial maintenance and architectural applications. Here, we demonstrate that anionic polymerization can be used to first graft hydroxyethyl methacrylate methylene malonate (HEMA-MM) onto a latex particle at ambient conditions, while subsequent ultraviolet (UV) exposure enabled their crosslinking into robust coatings. At room temperature, in the presence of air and water, the polymerization of HEMA-MM was initiated by anionic carboxyl groups present on the MAA latex particles and subsequently grafted onto the surface of particles. The pendent hydroxyethyl methacrylate (HEMA) group enabled UV-curing via free radical polymerization and the formation of a crosslinked network. Systematic investigations were conducted to study the formation and performance of the crosslinked coatings as a function of HEMA-MM incorporation. The incorporation of 10 wt% HEMA-MM into MAA latex yielded crosslinked coatings with decreased swelling, a heightened glass transition temperature (by ~20 °C) and a 2.9-fold improvement in the Young's moduli compared to controls (without HEMA-MM). Here, we demonstrate a facile method that provides a one-step grafting-functionalization approach using functional methylene malonates to produce UV-curable and high-performance coatings at room temperature and under atmospheric environments.

Published

2020

7. Cross-platform mechanical characterization of lung tissue

Author

D. Ezra Aurian-Blajeni, Shelly R. Peyton, Nathan P. Birch, Alfred J. Crosby, Carey E. Dougan, Jessica D. Schiffman, Aritra Nath Kundu, and Samuel R. Polio

Subjects

0301 basic medicine, Male, Respiratory System, Sus scrofa, lcsh:Medicine, Modulus, 02 engineering and technology, Stiffness, Freezing, Medicine and Health Sciences, Biomechanics, lcsh:Science, Materials, Lung, Lung Compliance, Microscale chemistry, 0303 health sciences, Microscopy, Multidisciplinary, Physics, Classical Mechanics, 021001 nanoscience & nanotechnology, Atomic Force Microscopy, Biomechanical Phenomena, Connective Tissue, Cavitation, Physical Sciences, Female, medicine.symptom, Anatomy, 0210 nano-technology, Rheology, Research Article, Materials science, Tissue Mechanics, Amorphous Solids, Materials Science, Material Properties, Uniaxial tension, Biophysics, In Vitro Techniques, Research and Analysis Methods, Continuum Mechanics, Models, Biological, 03 medical and health sciences, Elastic Modulus, medicine, Mechanical Properties, Animals, Humans, Elasticity (economics), Elastic modulus, Bronchioles, 030304 developmental biology, Scanning Probe Microscopy, lcsh:R, Biology and Life Sciences, Small amplitude, 030104 developmental biology, Biological Tissue, Cartilage, Mixtures, Respiratory Mechanics, lcsh:Q, Lung tissue, Gels, Biomedical engineering

Abstract

Published data on the mechanical strength and elasticity of lung tissue is widely variable, primarily due to differences in how testing was conducted across individual studies. This makes it extremely difficult to find a benchmark modulus of lung tissue when designing synthetic extracellular matrices (ECMs). To address this issue, we tested tissues from various areas of the lung using multiple characterization techniques, including micro-indentation, small amplitude oscillatory shear (SAOS), uniaxial tension, and cavitation rheology. We report the sample preparation required and data obtainable across these unique but complimentary methods to quantify the modulus of lung tissue. We highlight cavitation rheology as a new method, which can measure the modulus of intact tissue with precise spatial control, and reports a modulus on the length scale of typical tissue heterogeneities. Shear rheology, uniaxial, and indentation testing require heavy sample manipulation and destruction; however, cavitation rheology can be performed in situ across nearly all areas of the lung with minimal preparation. The Young’s modulus of bulk lung tissue using microindentation (1.9±0.5 kPa), SAOS (3.2±0.6 kPa), uniaxial testing (3.4±0.4 kPa), and cavitation rheology (6.1±1.6 kPa) were within the same order of magnitude, with higher values consistently reported from cavitation, likely due to our ability to keep the tissue intact. Although cavitation rheology does not capture the non-linear strains revealed by uniaxial testing and SAOS, it provides an opportunity to measure mechanical characteristics of lung tissue on a microscale level on intact tissues. Overall, our study demonstrates that each technique has independent benefits, and each technique revealed unique mechanical features of lung tissue that can contribute to a deeper understanding of lung tissue mechanics.

Published

2018

8. Antifouling Stripes Prepared from Clickable Zwitterionic Copolymers

Author

Kristopher W. Kolewe, Ying Bai, Eric W. Rice, Pornpen Sae-ung, Voravee P. Hoven, Jessica D. Schiffman, and Todd Emrick

Subjects

Materials science, Silicon, Biocompatibility, Biofouling, Polymers, Surface Properties, Phosphorylcholine, chemistry.chemical_element, Nanotechnology, 02 engineering and technology, 010402 general chemistry, Microscopy, Atomic Force, 01 natural sciences, Article, Rhodamine 6G, chemistry.chemical_compound, X-ray photoelectron spectroscopy, immune system diseases, Electrochemistry, Copolymer, General Materials Science, Thin film, Spectroscopy, Ions, technology, industry, and agriculture, Surfaces and Interfaces, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 0104 chemical sciences, chemistry, Surface modification, Methacrylates, 0210 nano-technology

Abstract

In this study, we have fabricated robust patterned surfaces that contain biocompatible and antifouling stripes, which cause microorganisms to consolidate into bare silicon spaces. Copolymers of methacryloyloxyethyl phosphorylcholine (MPC) and a methacrylate-substituted dihydrolipoic acid (DHLA) were spin-coated onto silicon substrates. The MPC units contributed biocompatibility and antifouling properties, while the DHLA units enabled crosslinking and the formation of robust thin films. Photolithography enabled the formation of 200 μm wide poly(MPC-DHLA) stripped patterns that were characterized using atomic force microscopy (AFM), X-ray photoelectron spectroscopy (XPS) and rhodamine 6G staining. Regardless of the spacing between the poly(MPC-DHLA) stripes (10, 50, or 100 μm) Escherichia coli (E. coli) rapidly adhered to the bare silicon gaps that lacked the copolymer, confirming the antifouling nature of MPC. Overall, this work provides a surface modification strategy to generate alternating bio-fouling and non-fouling surface structures that are potentially applicable for researchers studying cell biology, drug screening, and biosensor technology.

Published

2017

9. Polyelectrolyte-Functionalized Nanofiber Mats Control the Collection and Inactivation of Escherichia coli

Author

Michael Porter, Jessica D. Schiffman, and Katrina A. Rieger

Subjects

Materials science, 02 engineering and technology, poly (acrylic acid), 010402 general chemistry, 01 natural sciences, lcsh:Technology, Article, Chitosan, Contact angle, chemistry.chemical_compound, Polymer chemistry, General Materials Science, Surface charge, inactivation, Cellulose, bacteria, nanofiber, lcsh:Microscopy, antibacterial, cellulose, chitosan, electrospun, polyelectrolyte, Acrylic acid, lcsh:QC120-168.85, lcsh:QH201-278.5, lcsh:T, 021001 nanoscience & nanotechnology, Polyelectrolyte, 0104 chemical sciences, chemistry, Chemical engineering, lcsh:TA1-2040, Nanofiber, Surface modification, lcsh:Descriptive and experimental mechanics, lcsh:Electrical engineering. Electronics. Nuclear engineering, 0210 nano-technology, lcsh:Engineering (General). Civil engineering (General), lcsh:TK1-9971

Abstract

Quantifying the effect that nanofiber mat chemistry and hydrophilicity have on microorganism collection and inactivation is critical in biomedical applications. In this study, the collection and inactivation of Escherichia coli K12 was examined using cellulose nanofiber mats that were surface-functionalized using three polyelectrolytes: poly (acrylic acid) (PAA), chitosan (CS), and polydiallyldimethylammonium chloride (pDADMAC). The polyelectrolyte functionalized nanofiber mats retained the cylindrical morphology and average fiber diameter (~0.84 µm) of the underlying cellulose nanofibers. X-ray photoelectron spectroscopy (XPS) and contact angle measurements confirmed the presence of polycations or polyanions on the surface of the nanofiber mats. Both the control cellulose and pDADMAC-functionalized nanofiber mats exhibited a high collection of E. coli K12, which suggests that mat hydrophilicity may play a larger role than surface charge on cell collection. While the minimum concentration of polycations needed to inhibit E. coli K12 was 800 µg/mL for both CS and pDADMAC, once immobilized, pDADMAC-functionalized nanofiber mats exhibited a higher inactivation of E. coli K12, (~97%). Here, we demonstrate that the collection and inactivation of microorganisms by electrospun cellulose nanofiber mats can be tailored through a facile polyelectrolyte functionalization process.

Published

2016

10. Underwater Superoleophobic Surfaces Prepared from Polymer Zwitterion/Dopamine Composite Coatings

Author

Chia Chih Chang, Kristopher W. Kolewe, Yinyong Li, Kenneth R. Carter, Benny D. Freeman, Jessica D. Schiffman, Irem Kosif, and Todd Emrick

Subjects

Materials science, Biocompatibility, Fouling, Mechanical Engineering, 02 engineering and technology, engineering.material, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Article, 0104 chemical sciences, Contact angle, Biofouling, Coating, Chemical engineering, Mechanics of Materials, Superhydrophilicity, Polymer chemistry, engineering, Surface roughness, Surface modification, 0210 nano-technology

Abstract

Hydration is central to mitigating surface fouling by oil and microorganisms. Immobilization of hydrophilic polymers on surfaces promotes retention of water and a reduction of direct interactions with potential foulants. While conventional surface modification techniques are surface-specific, mussel-inspired adhesives based on dopamine effectively coat many types of surfaces and thus hold potential as a universal solution to surface modification. Here, we describe a facile, one-step surface modification strategy that affords hydrophilic, and underwater superoleophobic, coatings by the simultaneous deposition of polydopamine (PDA) with poly(methacryloyloxyethyl phosphorylcholine) (polyMPC). The resultant composite coating features enhanced hydrophilicity (i.e., water contact angle of ~10° in air) and antifouling performance relative to PDA coatings. PolyMPC affords control over coating thickness and surface roughness, and results in a nearly 10 fold reduction in Escherichia coli adhesion relative to unmodified glass. The substrate-independent nature of PDA coatings further promotes facile surface modification without tedious surface pretreatment, and offers a robust template for codepositing polyMPC to enhance biocompatibility, hydrophilicity and fouling resistance.

Published

2016

11. Scaling up Nature — Large Area Flexible Biomimetic Surfaces

Author

Kristopher W. Kolewe, Kenneth R. Carter, Jessica D. Schiffman, Jacob John, and Yinyong Li

Subjects

Fabrication, Nanostructure, Materials science, Surface Properties, Water, Nanotechnology, engineering.material, Article, Nanostructures, Contact angle, chemistry.chemical_compound, chemistry, Coating, Biomimetic Materials, Polyethylene terephthalate, engineering, Surface modification, General Materials Science, Biomimetics, Lubricant, Hydrophobic and Hydrophilic Interactions, Lubricants

Abstract

The fabrication and advanced function of large area biomimetic superhydrophobic surfaces (SHS) and slippery lubricant infused porous surfaces (SLIPS) are reported. The use of roll-to-roll nanoimprinting techniques enabled the continuous fabrication of SHS and SLIPS based on hierarchically wrinkled surfaces. Perfluoropolyether (PFPE) hybrid molds were used as flexible molds for roll-to-roll imprinting into a newly designed thiol-ene based photopolymer resin coated on flexible polyethylene terephthalate (PET) films. The patterned surfaces exhibit feasible superhydrophobicity with a water contact angle around 160° without any further surface modification. The SHS can be easily converted into SLIPS by roll-to-roll coating of a fluorinated lubricant, and these surfaces have outstanding repellence to a variety of liquids. Furthermore, both SHS and SLIPS display anti-biofouling properties when challenged with Escherichia coli K12 MG1655. The current report describes the transformation of artificial biomimetic structures from small, lab scale coupons to low cost, large area platforms.

Published

2015

12. Thin-Film Composite Pressure Retarded Osmosis Membranes for Sustainable Power Generation from Salinity Gradients

Author

Ngai Yin Yip, Menachem Elimelech, Jessica D. Schiffman, William A. Phillip, Yu Chang Kim, Laura A. Hoover, and Alberto Tiraferri

Subjects

Electric power production, Salinity, Osmosis, Forward osmosis, Conservation of Energy Resources, Mechanical engineering, Environmental engineering, Fresh Water, Membranes (Technology), Permeability, Chemical engineering, Thin-film composite membrane, Pressure, Osmotic power, Environmental Chemistry, Seawater, Composite material, FOS: Chemical engineering, Concentration polarization, Pressure-retarded osmosis, FOS: Environmental engineering, Membranes, Artificial, General Chemistry, Environmental sciences, Membrane, Layer (electronics), Power Plants, Composite materials--Technological innovations

Abstract

Pressure retarded osmosis has the potential to produce renewable energy from natural salinity gradients. This work presents the fabrication of thin-film composite membranes customized for high performance in pressure retarded osmosis. We also present the development of a theoretical model to predict the water flux in pressure retarded osmosis, from which we can predict the power density that can be achieved by a membrane. The model is the first to incorporate external concentration polarization, a performance limiting phenomenon that becomes significant for high-performance membranes. The fabricated membranes consist of a selective polyamide layer formed by interfacial polymerization on top of a polysulfone support layer made by phase separation. The highly porous support layer (structural parameter S = 349 μm), which minimizes internal concentration polarization, allows the transport properties of the active layer to be customized to enhance PRO performance. It is shown that a hand-cast membrane that balances permeability and selectivity (A = 5.81 L m(-2) h(-1) bar(-1), B = 0.88 L m(-2) h(-1)) is projected to achieve the highest potential peak power density of 10.0 W/m(2) for a river water feed solution and seawater draw solution. The outstanding performance of this membrane is attributed to the high water permeability of the active layer, coupled with a moderate salt permeability and the ability of the support layer to suppress the undesirable accumulation of leaked salt in the porous support. Membranes with greater selectivity (i.e., lower salt permeability, B = 0.16 L m(-2) h(-1)) suffered from a lower water permeability (A = 1.74 L m(-2) h(-1) bar(-1)) and would yield a lower peak power density of 6.1 W/m(2), while membranes with a higher permeability and lower selectivity (A = 7.55 L m(-2) h(-1) bar(-1), B = 5.45 L m(-2) h(-1)) performed poorly due to severe reverse salt permeation, resulting in a similar projected peak power density of 6.1 W/m(2).

Published

2011

13. Thermal-ResponsiveBehavior of a Cell Compatible Chitosan/PectinHydrogel.

Author

NathanP. Birch, Lauren E. Barney, Elena Pandres, Shelly R. Peyton, and Jessica D. Schiffman

Published

2015

14. Biocidal Activity of Plasma Modified Electrospun Polysulfone Mats Functionalized with Polyethyleneimine-Capped Silver Nanoparticles.

Author

Jessica D. Schiffman, Yue Wang, Emmanuel P. Giannelis, and Menachem Elimelech

Subjects

*BIOCIDES, *ELECTROSPINNING, *SULFONES, *FUNCTIONAL groups, *AZIRIDINES, *COLLOIDAL silver, *ANTI-infective agents, *SURFACE chemistry, *ELECTROSTATICS

Abstract

The incorporation of silver nanoparticles (AgNPs) into polymeric nanofibers has attracted a great deal of attention due to the strong antimicrobial activity that the resulting fibers exhibit. However, bactericidal efficacy of AgNP-coated electrospun fibrous mats has not yet been demonstrated. In this study, polysulfone (PSf) fibers were electrospun and surface-modified using an oxygen plasma treatment, which allowed for facile irreversible deposition of cationically charged polyethyleneimine (PEI)-AgNPs via electrostatic interactions. The PSf–AgNP mats were characterized for relative silver concentration as a function of plasma treatment time using ICP-MS and changes in contact angle. Plasma treatment of 60 s was the shortest time required for maximum loss of bacteria (Escherichia coli) viability. Time-dependent bacterial cytotoxicity studies indicate that the optimized PSf–AgNP mats exhibit a high level of inactivation against both Gram negative bacteria, Escherichia coli, and Gram positive bacteria, Bacillus anthracisand Staphylococcus aureus. [ABSTRACT FROM AUTHOR]

Published

2011

15. Carboxymethyl Chitosan as a Matrix Material for Platinum, Gold, and Silver Nanoparticles.

Author

Michael J. Laudenslager, Jessica D. Schiffman, and Caroline L. Schauer

Subjects

*CHITOSAN, *NANOPARTICLES, *TRANSMISSION electron microscopy, *FOURIER transform infrared spectroscopy

Abstract

Carboxymethyl chitosan (CMC) was evaluated for its use in the synthesis and stabilization of catalytic nanoparticles for the first time. Many studies have reported on the ability of chitosan to bind with metal ions and support metal nanoparticles. CMC has a higher reported chelation capacity than chitosan, which has potential implications for improved catalyst formation and immobilization. Platinum, gold, and silver nanoparticles were synthesized in both chitosan and CMC. Particle size, morphology, and aggregation were examined using transmission electron microscopy (TEM). Complexation of nanoparticles was studied through Fourier transform infrared spectroscopy (FTIR). Similar nanoparticle size distributions were observed in the two polymers; however, CMC was observed to have higher rates of aggregation. This indicates that the carboxymethyl groups did not change nanoparticle formation; however, poor cross-linking and a limited anchoring ability of CMC led to the inability to immobilize the catalyst materials effectively. [ABSTRACT FROM AUTHOR]

Published

2008

16. Cross-Linking Chitosan Nanofibers.

Author

Jessica D. Schiffman and Caroline L. Schauer

Subjects

*CHITOSAN, *SCANNING electron microscopy, *FOURIER transforms, *MOLECULAR weights

Abstract

In the present study, we have electrospun various grades of chitosan and cross-linked them using a novel method involving glutaraldehyde (GA) vapor, utilizing a Schiff base imine functionality. Chemical, structural, and mechanical analyses have been conducted by Fourier transform infrared spectroscopy (FTIR), scanning electron microscopy (SEM), and Kawabata microtensile testing, respectively. Additionally, the solubilities of the as-spun and cross-linked chitosan mats have been evaluated;solubility was greatly improved after cross-linking. SEM images displayed evidence that unfiltered low, medium, and high molecular weight chitosans, as well as practical-grade chitosan, can be electrospun into nanofibrous mats. The as-spun medium molecular weight chitosan nanofibers have a Young's modulus of 154.9 ± 40.0 MPa and display a pseudo-yield point that arose due to the transition from the pulling of a fibrous mat with high cohesive strength to the sliding and elongation of fibers. As-spun mats were highly soluble in acidic and aqueous solutions. After cross-linking, the medium molecular weight fibers increased in diameter by an average of 161 nm, have a decreased Young's modulus of 150.8 ± 43.6 MPa, and were insoluble in basic, acidic, and aqueous solutions. Though the extent to which GA penetrates into the chitosan fibers is currently unknown, it is evident that the cross-linking resulted in increased brittleness, a color change, and the restriction of fiber sliding that resulted in the loss of a pseudo-yield point. [ABSTRACT FROM AUTHOR]

Published

2007

17. One-Step Electrospinning of Cross-Linked Chitosan Fibers.

Author

Jessica D. Schiffman and Caroline L. Schauer

Subjects

*PLANT products, *POLYSACCHARIDES, *ELECTRON microscopy, *PHYSICAL & theoretical chemistry

Abstract

Chitin is a nitrogen-rich polysaccharide that is abundant in crustaceans, mollusks, insects, and fungi and is the second most abundant organic material found in nature next to cellulose. Chitosan, the N-deacetylated derivative of chitin, is environmentally friendly, nontoxic, biodegradable, and antibacterial. Fibrous mats are typically used in industries for filter media, catalysis, and sensors. Decreasing fiber diameters within these mats causes many beneficial effects such as increased specific surface area to volume ratios. When the intrinsically beneficial effects of chitosan are combined with the enhanced properties of nanofibrous mats, applications arise in a wide range of fields, including medical, packaging, agricultural, and automotive. This is particularly important as innovative technologies that focus around bio-based materials are currently of high urgency, as they can decrease dependencies on fossil fuels. We have demonstrated that Schiff base cross-linked chitosan fibrous mats can be produced utilizing a one-step electrospinning process that is 25 times faster and, therefore, more economical than a previously reported two-step vapor-cross-linking method. These fibrous mats are insoluble in acidic, basic, and aqueous solutions for 72 h. Additionally, this improved production method results in a decreased average fiber diameter, which measures 128 ± 40 nm. Chemical and structural analyses were conducted utilizing Fourier transform infrared spectroscopy, solubility studies, and scanning electron microscopy. [ABSTRACT FROM AUTHOR]

Published

2007

18. Cross-platform mechanical characterization of lung tissue.

Author

Samuel R Polio, Aritra Nath Kundu, Carey E Dougan, Nathan P Birch, D Ezra Aurian-Blajeni, Jessica D Schiffman, Alfred J Crosby, and Shelly R Peyton

Subjects

Medicine, Science

Abstract

Published data on the mechanical strength and elasticity of lung tissue is widely variable, primarily due to differences in how testing was conducted across individual studies. This makes it extremely difficult to find a benchmark modulus of lung tissue when designing synthetic extracellular matrices (ECMs). To address this issue, we tested tissues from various areas of the lung using multiple characterization techniques, including micro-indentation, small amplitude oscillatory shear (SAOS), uniaxial tension, and cavitation rheology. We report the sample preparation required and data obtainable across these unique but complimentary methods to quantify the modulus of lung tissue. We highlight cavitation rheology as a new method, which can measure the modulus of intact tissue with precise spatial control, and reports a modulus on the length scale of typical tissue heterogeneities. Shear rheology, uniaxial, and indentation testing require heavy sample manipulation and destruction; however, cavitation rheology can be performed in situ across nearly all areas of the lung with minimal preparation. The Young's modulus of bulk lung tissue using micro-indentation (1.4±0.4 kPa), SAOS (3.3±0.5 kPa), uniaxial testing (3.4±0.4 kPa), and cavitation rheology (6.1±1.6 kPa) were within the same order of magnitude, with higher values consistently reported from cavitation, likely due to our ability to keep the tissue intact. Although cavitation rheology does not capture the non-linear strains revealed by uniaxial testing and SAOS, it provides an opportunity to measure mechanical characteristics of lung tissue on a microscale level on intact tissues. Overall, our study demonstrates that each technique has independent benefits, and each technique revealed unique mechanical features of lung tissue that can contribute to a deeper understanding of lung tissue mechanics.

Published

2018

19. Green Materials Science and Engineering Reduces Biofouling: Approaches for Medical and Membrane-based Technologies

Author

Kerianne M Dobosz, Kristopher W Kolewe, and Jessica D Schiffman

Subjects

Biofouling, Resistance genes, antibiotic resistance, Drug Development, green chemistry, antifouling, Microbiology, QR1-502

Abstract

Numerous engineered and natural environments suffer deleterious effects from biofouling and/or biofilm formation. For instance, bacterial contamination on biomedical devices pose serious health concerns. In membrane-based technologies, such as desalination and wastewater reuse, biofouling decreases membrane lifetime and increases the energy required to produce clean water. Traditionally, approaches have combatted bacteria using bactericidal agents. However, due to globalization, a decline in antibiotic discovery, and the widespread resistance of microbes to many commercial antibiotics and metallic nanoparticles, new materials and approaches to reduce biofilm formation are needed. In this mini-review, we cover the recent strategies that have been explored to combat microbial contamination without exerting evolutionary pressure on microorganisms. Renewable feedstocks, relying on structure-property relationships, bioinspired/nature-derived compounds, and green processing methods are discussed. Greener strategies that mitigate biofouling hold great potential to positively impact human health and safety.

Published

2015