Your search keyword '"polymers"' showing total 13,013 results

1. Core–Shell Quantum Dot-Embedded Polymers for Antistatic Applications.

Author

Ekim, Sunay Dilara, Aydın, Firdevs, Kaya, Görkem Eylül, Baytekin, H. Tarik, Asil, Demet, and Baytekin, Bilge

Abstract

Electrical charges develop on the surfaces of two insulator materials when they are in contact and separated. The retention of charges on insulator polymers causes material losses and hazards in industries using these polymers. Here, we show that a set of core–shell quantum dots embedded into a common polymer can destabilize the charges on the polymer. The locations of the charge carriers in the nanostructure, or the "type" of the dots, affect their discharging ability, which can also be manipulated or reverted remotely by light. The mechanism of antistatic action is presumed to contain interaction with polymer mechanospecies. The quantum dot embedding renders the polymers antistatic without changing their conductivity. Such antistatic additives, by which the polymers remain insulating, can be used to prevent static charges, e.g., in electronic coatings and in other antistatic applications. [ABSTRACT FROM AUTHOR]

Published

2023

2. Computational Investigation of Interacting Nanohole Defects for Carbon Nanotube Cross-Linking and Functionalization with Bismaleimide: Implications for Ultrastrong, Lightweight Nanocomposites.

Author

Kataria, Aditya, Liang, Zhiyong, and Dumitricǎ, Traian

Abstract

Carbon nanotubes (CNTs) reinforced with bismaleimide (BMI) are promising extreme materials for space exploration. Irradiation is a potential method to improve their mechanical properties, but the atomic-level details of how radiation affects CNTs are not well understood. Using density functional theory based tight-binding, we investigate interacting nanohole defects in bilayer graphene as model systems for radiation-treated, flattened CNTs. The covalent cross-linking improves the load transfer between the graphitic layers. While the nanoholes reduce the in-plane mechanical properties, they provide favorable sites for the cycloaddition reaction of BMI monomers. Our catalog of interacting nanohole defects can be used to inform mesoscopic models of irradiated CNTs. [ABSTRACT FROM AUTHOR]

Published

2023

3. Nonleaching Biocidal N-Halamine-Functionalized Polyamine-, Guanidine-, and Hydantoin-Based Coatings

Author

Universidade de Santiago de Compostela. Departamento de Farmacoloxía, Farmacia e Tecnoloxía Farmacéutica, Universidade de Santiago de Compostela. Departamento de Microbioloxía e Parasitoloxía, Bromberg, Lev, Magariños Ferro, Beatriz, Concheiro Nine, Ángel Joaquín, Hatton, T. Alan, Álvarez Lorenzo, Carmen Isabel, Universidade de Santiago de Compostela. Departamento de Farmacoloxía, Farmacia e Tecnoloxía Farmacéutica, Universidade de Santiago de Compostela. Departamento de Microbioloxía e Parasitoloxía, Bromberg, Lev, Magariños Ferro, Beatriz, Concheiro Nine, Ángel Joaquín, Hatton, T. Alan, and Álvarez Lorenzo, Carmen Isabel

Abstract

Fibrous materials with inherent antimicrobial properties can help in real-time deactivation of microorganisms, enabling multiple uses while reducing secondary infections. Coatings with antiviral polymers enhance the surface functionality for existing and potential future pandemics. Herein, we demonstrated a straightforward route toward biocidal surface creation using polymers with nucleophilic biguanide, guanidine, and hydantoin groups that are covalently attached onto a solid support. Biocidal poly(N-vinylguanidine) (PVG) and poly(allylamine-co-4-aminopyridine-co-5-(4-hydroxybenzylidene)hydantoin) (PAH) were introduced for coating applications along with commercially available polyvinylamine (PVAm) and poly(hexamethylene biguanide) (PHMB). Nonleaching coatings were created by first fabricating bifunctional siloxane or isocyanate precursor coatings on the cotton, nylon–cotton, and glass fiber fabric, followed by the polymer attachment. The developed grafting methods ensured the stability of the coating and the reuse of the material while maintaining the biocidal properties. Halogenation of polymer-coated fabric was conducted by aqueous solutions of sodium hypochlorite or in situ generation of hypobromous acid (HOBr), resulting in surfaces coated by N-halamines with high contents of active > N–Cl or > N–Br groups. The polymer-coated fabrics were stable in multiple laundry cycles and maintained hydrophilic character after coating and halogenation. Halogenated polymer-coated fabrics completely inactivated human respiratory coronavirus based on a contact-killing mechanism and were shown to be reusable after recharging with bromine or chlorine

Published

2024

4. Atomic Layer Deposition for Stable InP-Based On-Chip Quantum Dot microLEDs: Hybrid Quantum Dot Pockets.

Author

Petit RR, Ozdemir R, Van Avermaet H, Giordano L, Kuhs J, Werbrouck A, Filez M, Dendooven J, Hens Z, Smet PF, and Detavernier C

Abstract

Recent advances in synthesis techniques yield InP-based QDs with optical properties comparable to those of benchmark Cd-based QDs, making InP-based QDs viable alternatives to toxic Cd-based QDs for applications such as quantum dot LEDs (QLEDs). However, QLEDs typically suffer from a loss of luminescence over time due to exposure of the QDs to ambient air. To avoid this, state-of-the-art hybrid barrier layers are explored consisting of alternating organic/inorganic layers. In this study, InP-based QD thin films and InP-based QDs embedded in Kraton polymers are encapsulated with a thin metal oxide barrier layer by atomic layer deposition (ALD). Specifically, Al 2 O 3 , TiO 2 , and ZnO thin films are deposited using trimethylaluminum (TMA), tetrakis(dimethylamino)titanium (TDMAT), and diethylzinc (DEZ), with H 2 O as the reactant. In situ photoluminescence (PL) is used to evaluate the optical response of the InP-based QDs during the ALD coating. The results show that ALD on pristine QD thin films causes degradation of luminescence, while this is not observed for polymer-embedded QDs. The long-term stability of the (ALD-coated) samples is investigated by accelerated degradation in a humidity chamber at a high temperature. Using a single Al 2 O 3 ALD thin film as a capping layer for polymer-embedded QDs, greater stability of the QD-PL over a period of at least 300 h is found compared to pristine QD samples. A similar study is performed with InP-based QDs embedded in UV-patterned polymer (thiol-ene) structures, the so-called QD pockets, envisioned for use in on-chip quantum dot microLEDs. These QD pockets are purposefully designed for pick-and-place operations to reduce the complexity of the on-chip quantum dot microLED manufacturing process. The PL stability was significantly improved after incorporating Al 2 O 3 ALD thin films, with these hybrid QD pockets showing no clear signs of degradation after 140 h. The combination of polymer embedding and ALD with the merits and scalability of the QD pocket structure is demonstrated to be an effective approach to improving the long-term QD stability and shows promise for the development of stable, InP-based on-chip quantum dot microLEDs.

Published

2024

5. Supramolecular Luminescent Copper-Nanocluster-Based Dough with Excellent Electrical Conductivity Sensing Properties.

Author

Sun M, Li S, Wang Q, Li Y, Jing H, Li X, Liu Y, Ren W, and Xin X

Abstract

In recent years, the rapid advancement of flexible conductive materials has significantly increased the demand for dough materials that offer high flexibility and conductivity for diverse applications. Here, we developed a flexible, stretchable, and self-healing dough utilizing hydrogen-bonding interactions between glutathione-stabilized copper nanoclusters (GSH-Cu NCs) and poly(acrylic acid) (PAA). The dough materials can be kneaded, readily reshaped, and further processed to create bulk materials of arbitrary form factors. The incorporation of PAA not only preserved the vibrant blue emission of GSH-Cu NCs but also enhanced their electrical conductivity and stretchability. The dough can be stretched up to 25 times its initial length and achieves complete self-healing in a short time. Moreover, the dough can automatically repair physical damage and return to its initial conductivity levels after healing. Surprisingly, the electrical conductivity of the dough can reach as high as 2.97 S/m, which is relatively superior compared to that of conventional conductive materials. This study presents a dough that serves as a highly sensitive strain sensor, capable of effectively monitoring human movement across a broad range of strains.

Published

2024

6. Fully Atom-Efficient Solvent-Mediated Biopolymer Manufacturing: A Base Case Illustrated with Macromolecular Surfactants Tailored to Stable Polymer-Water Interfaces.

Author

Kuehl B, Raman S, Becker A, Garg V, Roberts-Dobie J, McCaslin A, Brensdal J, Attinger J, Burton L, Forrester M, Hohmann A, and Cochran EW

Abstract

This work introduces a novel 1-pot, 0-waste, 0-VOC methodology for synthesizing polymeric surfactants using acrylated epoxidized soybean oil and acrylated glycerol as primary monomers. These macromolecular surfactants are synthesized via reversible addition-fragmentation chain transfer (RAFT) polymerization, allowing for tunable hydrophilic-lipophilic balance (HLB) and ionic properties. We characterize the copolymers' chemical composition and surface-active properties, and evaluate their effectiveness in forming and stabilizing emulsions of semiepoxidized soybean oil and poly(acrylated epoxidized high oleic soybean oil). Comprehensive analyses, including gel permeation chromatography, nuclear magnetic resonance spectroscopy, dynamic light scattering, particle size distribution, zeta potential, and critical micelle concentration, provide detailed insights into the copolymers and the emulsions they form. The results demonstrate that the RAFT-polymerized surfactants offer long-lasting stability and effectively disperse both common oil-in-water emulsions and highly viscous and hydrophobic polymer latexes. These surfactants outperform traditional small molecule surfactants by reducing particle size and preventing phase separation, even over extended storage periods. Stable polymer-water interfaces are achieved through HLB control, tailored by monomer composition, and the final product requires no additional purification since polymerization occurs in liquid surfactants. While small molecules contribute to rapid micelle formation, the polymeric components enhance long-term stability through steric repulsion and slower dynamics. This method enables even the emulsification of polymers with submicron particle size, which ordinarily requires emulsion polymerization. Integrating biobased polymeric surfactants with advanced polymer processing techniques opens new possibilities for transforming highly hydrophobic polymers into latexes, facilitating downstream applications. This innovation enhances the environmental sustainability of surfactant production and broadens the potential for polymer emulsification technologies. Additionally, the integrated solution-processing approach demonstrated here can be applied to other emerging polymers, where judiciously selected nonvolatile solvents facilitate the polymerization and play a role in the final application.

Published

2024

7. Microplastics at Environmentally Relevant Concentrations Had Minimal Impacts on Pelagic Zooplankton Communities in a Large In-Lake Mesocosm Experiment.

Author

Langenfeld D, Bucci K, Veneruzzo C, McNamee R, Gao G, Rochman CM, Rennie MD, Hoffman MJ, Orihel DM, Provencher JF, Higgins SN, and Paterson MJ

Subjects

Animals, Copepoda drug effects, Environmental Monitoring, Ecosystem, Plastics, Zooplankton, Microplastics, Water Pollutants, Chemical, Lakes

Abstract

To assess the potential risks of contemporary levels of plastic pollution in freshwater ecosystems, a large-scale experiment was conducted over 10 weeks in a boreal lake at the IISD-Experimental Lakes Area (Ontario, Canada). Fragments of common polymers (polyethylene, polystyrene, and polyethylene terephthalate), each with distinct colors and buoyancies, were added as a single pulse to seven in-lake mesocosms in equal contributions in a range of environmentally relevant nominal concentrations (6-29,240 particles/L). Two additional mesocosms with no added microplastics were used as controls. Zooplankton ingested low levels of microplastics (mean of 0.06 particles/individual ± SD 0.07) and generally their total abundance and community composition were not negatively impacted. Temporary changes were however observed; total zooplankton abundance and abundance of calanoid copepods were temporarily stimulated by increasing nominal microplastic concentrations, and modest, short-term reductions in egg production of the cyclopoid copepod Tropocyclops extensus and abundance of copepod nauplii occurred. Collectively, these results suggest that microplastics could have complex impacts on zooplankton communities, stimulating some species while negatively impacting others.

Published

2024

8. Occurrence and Fate of Fluoroalkyl Sulfonamide-Based Copolymers in Earthworms-Bioavailability, Transformation, and Potential Impact of Sludge Application.

Author

Fredriksson F, Kärrman A, Eriksson U, and Yeung LW

Subjects

Animals, Soil chemistry, Biological Availability, Oligochaeta metabolism, Sewage chemistry, Sulfonamides, Polymers, Soil Pollutants metabolism

Abstract

To date, considerable knowledge and data gaps regarding the occurrence, environmental levels, and fate of polymeric perfluoroalkyl and polyfluoroalkyl substances (PFAS) exist. In the present study availability, accumulation, and transformation of C4- and C8-fluoroalkylsulfonamide (FASA)-based copolymers were assessed in laboratory-grown earthworms ( Eisenia fetida , triplicate of exposure tests and control). Further, a field study on earthworms (18 pooled samples) in sludge-amended soil was conducted to assess the environmental impact of sludge-amended soil with regard to the FASA-based copolymers, together with the applied sludge ( n = 3), and the field soils during the period ( n = 4). In the laboratory study, the FASA-based copolymers were taken up by the earthworms in concentrations between 19 and 33 ng/g of dw for the C8- and between 767 and 1735 ng/g of dw for the C4-FASA-based copolymer. Higher biota soil accumulation factors (BAFs) were observed for the copolymer with a longer perfluorinated side-chain length (C8, average BAF value of 0.7) compared to the copolymer with a shorter side-chain length (C4, average BAF value of 0.02). Perfluorooctane sulfonamidoacetates (FOSAAs) and perfluorooctane sulfonamide (FOSA), including both branched and linear isomers, were detected after exposure to the C8-FASA-based copolymer. Two metabolites were detected in the earthworms exposed to the C4-FASA-based copolymer: perfluorobutanesulfonamide (FBSA) and perfluorobutanesulfonic acid (PFBS). Although the presence of other monomers or impurities in the copolymer formulation cannot be ruled out, the present laboratory study suggests that the FASA-based copolymers may be an indirect source of lower molecular weight PFAS in the environment through transformation. Elevated levels of C8-FASA-based copolymer were found in the field sludge-amended soil compared to nontreated soil (32 versus 11 ng/g d.w.), and higher concentrations of PFAS in earthworms living in sludge-amended soil compared to nontreated soil (566 versus 103 ng/g d.w.) were observed. These findings imply that the application of sludge is a potential pathway of PFAS to the environment.

Published

2024

9. Spacer Twisting Strategy to Realize Ultrabright Near-Infrared II Polymer Nanoparticles for Fluorescence Imaging-Guided Tumor Phototheranostics.

Author

Wu Y, Yu H, Li C, Liu L, Zhang Y, Gong J, Sha R, Feng L, Yan H, Jiang G, Wang J, and Tang BZ

Subjects

Mice, Animals, Humans, Phototherapy, Mice, Inbred BALB C, Neoplasms diagnostic imaging, Neoplasms therapy, Antineoplastic Agents chemistry, Antineoplastic Agents pharmacology, Cell Survival drug effects, Fluorescent Dyes chemistry, Cell Line, Tumor, Nanoparticles chemistry, Polymers chemistry, Infrared Rays, Optical Imaging, Theranostic Nanomedicine

Abstract

Conjugated polymers are becoming popular near-infrared II (NIR-II) phototheranostic agents (PTAs) due to their numerous advantages, such as high photostability, large molar extinction coefficients, and excellent photothermal properties. However, the strong π-π interactions between the chains of the conjugated polymers resulted in their generally low NIR-II emission quantum yields (QY). Therefore, the synthesis of conjugated polymers with high QY is an interesting but challenging task. Herein, we proposed a spacer twisting strategy to realize ultrabright NIR-II polymer nanoparticles for fluorescence imaging-guided tumor phototheranostics. Theoretical calculations indicated that the polymer PY-IT has the largest dihedral angle between the largely π-conjugated skeleton and the spacer, which can effectively inhibit intermolecular π-π stacking, resulting in an improved QY as high as 16.5% in nanoparticles. In addition, PY-IT NPs can effectively perform NIR-II imaging and photothermal treatment of tumors. The work presents some valuable guides for achieving ultrabright NIR-II polymeric PTAs with high QY.

Published

2024

10. Advances in Mussel Adhesion Proteins and Mussel-Inspired Material Electrospun Nanofibers for Their Application in Wound Repair.

Author

Dai Q, Liu H, Gao C, Sun W, Lu C, Zhang Y, Cai W, Qiao H, Jin A, Wang Y, and Liu Y

Subjects

Animals, Humans, Proteins chemistry, Proteins metabolism, Biomimetic Materials chemistry, Biomimetic Materials pharmacology, Tissue Engineering methods, Biocompatible Materials chemistry, Biocompatible Materials pharmacology, Indoles, Polymers, Nanofibers chemistry, Wound Healing drug effects, Bivalvia chemistry

Abstract

Mussel refers to a marine organism with strong adhesive properties, and it secretes mussel adhesion protein (MAP). The most vital feature of MAP is the abundance of the 3,4-dihydroxyphenylalanine (DOPA) group and lysine, which have antimicrobial, anti-inflammatory, antioxidant, and cell adhesion-promoting properties and can accelerate wound healing. Polydopamine (PDA) is currently the most widely used mussel-inspired material characterized by good adhesion, biocompatibility, and biodegradability. It can mediate various interactions to form functional coatings on cell-material surfaces. Nanofibers based on MAP and mussel-inspired materials have been exerting a vital role in wound repair, while there is no comprehensive review presenting them. This Review introduces the structure of MAPs and their adhesion mechanisms and mussel-inspired materials. Second, it introduces the functionalized modification of MAPs and their inspired materials in electrospun nanofibers and application in wound repair. Finally, the future development direction and coping strategies of MAP and mussel-inspired materials are discussed. Moreover, this Review can offer novel strategies for the application of nanofibers in wound repair and bring about new breakthroughs and innovations in tissue engineering and regenerative medicine.

Published

2024

11. Hierarchically Nano-Decorated Poly(lactic acid) Nanofibers for Humidity-Resistant Respiratory Healthcare and High-Accuracy Disease Diagnosis.

Author

Li J, He X, Ke L, Wang C, Chen Y, Zhu G, Shao J, Zhang Y, Zhang M, Gao J, and Xu H

Subjects

Humans, Humidity, Zinc Oxide chemistry, Dopamine chemistry, Wearable Electronic Devices, Indoles, Polymers, Polyesters chemistry, Nanofibers chemistry

Abstract

The application of biodegradable and eco-friendly poly(lactic acid) (PLA) nanofibrous membranes (NFMs) toward respiratory healthcare has long been thwarted by the poor electroactivity and low surface activity of PLA. Herein, we unravel a microwave-assisted route to fabricate rod-like ZnO nanodielectrics, which were decorated with dopamine (ZnO@PDA) and anchored at the PLA nanofibers via an electrospinning-electrospray approach. The PLA/ZnO@PDA NFMs featured a substantially elevated specific surface area (up to 20.7 m 2 /g), increased dielectric constant (nearly 1.8) and a surface potential as high as 9.5 kV, resulting in superior air filtering performance (99.45% for PM 0.3 , 94.1 Pa, 32 L/min) compared with the pure PLA counterpart (90.04%, 169.0 Pa, 32 L/min). The notably increased electroactivity endowed the PLA/ZnO@PDA NFMs with significant improvements in triboelectric properties (output voltage of 11.5 V at 10 N, 0.5 Hz), laying down the cornerstone for self-powered monitoring of personal respiration. More importantly, a deep learning-assisted diagnostic system was developed based on respiration-driven signal patterns, enabling intelligent and real-time disease diagnosis with 100% accuracy for the protective membranes. The proposed hierarchical nanodecoration strategy opens up new possibilities for engendering eco-friendly nanofibers with an exceptional combination of efficient respiratory healthcare and intelligent diagnosis.

Published

2024

12. Role of Underlying Substrates on the Interfacial Thermal Transport in Supported Graphene Nanochannels: Implications of Thermal Translucency.

Author

Becerra D, Walther JH, and Zambrano HA

Abstract

We study the role of underlying substrates on interfacial heat transfer within supported graphene nanochannels. Due to graphene's translucency, the underlying substrate, apart from its known hydrodynamic impact on fluid flow, also influences heat transport. We introduce the term "thermal translucency" to describe this phenomenon in the context of interfacial heat transfer. Our findings reveal that the Kapitza resistance, R K , is dependent on the specific underlying substrate. The specific underlying substrate alters the water-graphene interface potential landscape due to graphene's translucency, leading to a breakdown in the inverse relationship between interfacial water density peaks and R K values, typically observed at water-graphene and water-graphite interfaces. Remarkably, higher interfacial water density peaks correlate with more ordered energy patterns, not necessarily tied to more hydrophilic substrates as the literature commonly suggests for lower R K values. The insights provided have implications for controlling and tuning thermal transport and heat storage in nanofluidic devices.

Published

2024

13. Engineered Bacteriophage-Polymer Nanoassemblies for Treatment of Wound Biofilm Infections.

Author

Park J, Hassan MA, Nabawy A, Li CH, Jiang M, Parmar K, Reddivari A, Goswami R, Jeon T, Patel R, and Rotello VM

Subjects

Animals, Mice, Wound Infection microbiology, Wound Infection therapy, Wound Infection drug therapy, Bacteriophages, Hydrogels chemistry, Hydrogels pharmacology, Staphylococcus aureus drug effects, Staphylococcus aureus virology, Staphylococcus aureus physiology, Microbial Sensitivity Tests, Staphylococcal Infections therapy, Staphylococcal Infections drug therapy, Nanostructures chemistry, Biofilms drug effects, Methicillin-Resistant Staphylococcus aureus drug effects, Methicillin-Resistant Staphylococcus aureus virology, Polymers chemistry, Polymers pharmacology, Anti-Bacterial Agents pharmacology, Anti-Bacterial Agents chemistry

Abstract

The antibacterial efficacy and specificity of lytic bacteriophages (phages) make them promising therapeutics for treatment of multidrug-resistant bacterial infections. Restricted penetration of phages through the protective matrix of biofilms, however, may limit their efficacy against biofilm infections. Here, engineered polymers were used to generate noncovalent phage-polymer nanoassemblies (PPNs) that penetrate bacterial biofilms and kill resident bacteria. Phage K, active against multiple strains of Staphylococcus aureus , including methicillin-resistant S. aureus (MRSA), was assembled with cationic poly(oxanorbornene) polymers into PPNs. The PPNs retained phage infectivity, while demonstrating enhanced biofilm penetration and killing relative to free phages. PPNs achieved 3-log 10 bacterial reduction (∼99.9%) against MRSA biofilms in vitro. PPNs were then incorporated into Poloxamer 407 (P407) hydrogels and applied onto in vivo wound biofilms, demonstrating controlled and sustained release. Hydrogel-incorporated PPNs were effective in a murine MRSA wound biofilm model, showing a 1.5-log 10 reduction in bacterial load compared to a 0.5 log reduction with phage K in P407 hydrogel. Overall, this work showcases the therapeutic potential of phage K engineered with cationic polymers for treating wound biofilm infections.

Published

2024

14. Cellular Output and Physicochemical Properties of the Membrane-Derived Vesicles Depend on Chemical Stimulants.

Author

Shrestha D, Bahasoan Y, and Eggeling C

Subjects

Humans, Extracellular Vesicles chemistry, Extracellular Vesicles metabolism, Liposomes chemistry, THP-1 Cells, COVID-19 virology, Formaldehyde, Polymers, Cell Membrane metabolism, Cell Membrane chemistry, SARS-CoV-2 metabolism

Abstract

Synthetic liposomes are widely used as drug delivery vehicles in biomedical treatments, such as for mRNA-based antiviral vaccines like those recently developed against SARS-CoV-2. Extracellular vesicles (EVs), which are naturally produced by cells, have emerged as a next-generation delivery system. However, key questions regarding their origin within cells remain unresolved. In this regard, plasma membrane vesicles (PMVs), which are essentially produced from the cellular plasma membrane (PM), present a promising alternative. Unfortunately, their properties relevant to biomedical applications have not be extensively studied. Therefore, we conducted a thorough investigation of the methods used in the production of PMVs. By leveraging advanced fluorescence techniques in microscopy and flow cytometry, we demonstrated a strong dependence of the physicochemical attributes of PMVs on the chemicals used during their production. Following established protocols employing chemicals such as paraformaldehyde (PFA), N- ethylmaleimide (NEM) or dl-dithiothreitol (DTT) and by developing a modified NEM-based method that involved a hypotonic shock step, we generated PMVs from THP-1 CD1d cells. We systematically compared key parameters such as vesicle output, their size distribution, vesicular content analysis, vesicular membrane lipid organization and the mobility of a transmembrane protein. Our results revealed distinct trends: PMVs isolated using NEM-based protocols closely resembled natural vesicles, whereas PFA induced significant molecular cross-linking, leading to notable changes in the biophysical properties of the vesicles. Furthermore, our novel NEM protocol enhanced the efficiency of PMV production. In conclusion, our study highlights the unique characteristics of chemically produced PMVs and offers insights into their potentially diverse yet valuable biological functions.

Published

2024

15. Bispillar[5]arene-Based Slide-Ring Polyrotaxanation Enables Enhanced Toughness, Recyclability, Impact, and Puncture Resistance of Polyisoprene Elastomers.

Author

Li Q, Yang Y, Yu SM, Wu Z, Xing J, Lin Q, Miao Y, Wang H, Zhang DW, Wang W, Li ZT, and Xu YX

Abstract

A series of slide-ring polyrotaxanes (SRPs) have been constructed by the solvent-free blending of a ditopic pillar[5]arene ( DP5A ) and polyisoprene (PIP) after thermal annealing. Solid-state 13 C NMR experiments supported the fact that the pillar[5]arene rings of DP5A were threaded by PIP chains to afford physically interlocked networks. Tensile tests revealed that 1% of DP5A can improve the elongation at break from 50 to 239%, the tensile modulus from 2.1 to 3.9 MPa, and the toughness from 0.35 to 4.5 MJ/m 3 . Impact and puncture resistance experiments show that the DP5A -doped materials exhibit remarkable enhancement of protective and impalement-resistant performance. The samples can be also recycled repeatedly due to their physical crosslinking nature. The important stress delocalization effects have been attributed to the pulley effect of DP5A in the SRP materials, which represents a supramolecular approach for improving the performance of PIP elastomers.

Published

2024

16. Sustainable Epoxy Thermosets and Nanocomposites

Author

Niranjan Karak and Niranjan Karak

Subjects

Nanocomposites (Materials), Thermosetting composites, Polymers

Published

2021

17. Polymer-Based Additive Manufacturing: Recent Developments

Author

Jonathan E. Seppala, Anthony P. Kotula, Chad R. Snyder, Anthony Kotula, Jonathan Seppala, Chad Snyder, Erich D. Bain, Nicole E. Zander, Robert A. Bubeck, Michael Most, Tracy Zhang, Eric L. Gilmer, Craig Mansfield, John M. Gardner, Emilie J. Siochi, Donald G. Baird, Michael J. Bortner, Claire McIlroy, Masoumeh Pourali, Amy M. Peterson, Leanne Friedrich, Matthew Begley, Rashi Sharma, Stephen M. Kuebler, Christopher N. Grabill, Jennefir L. Digaum, Nicholas R. Kosan, Alexander R. Cockerham, Noel Martinez, Raymond C. Rumpf, Jonathan E. Seppala, Anthony P. Kotula, Chad R. Snyder, Anthony Kotula, Jonathan Seppala, Chad Snyder, Erich D. Bain, Nicole E. Zander, Robert A. Bubeck, Michael Most, Tracy Zhang, Eric L. Gilmer, Craig Mansfield, John M. Gardner, Emilie J. Siochi, Donald G. Baird, Michael J. Bortner, Claire McIlroy, Masoumeh Pourali, Amy M. Peterson, Leanne Friedrich, Matthew Begley, Rashi Sharma, Stephen M. Kuebler, Christopher N. Grabill, Jennefir L. Digaum, Nicholas R. Kosan, Alexander R. Cockerham, Noel Martinez, and Raymond C. Rumpf

Subjects

Three-dimensional printing, Butadiene, Elastomers, Polymers--Industrial applications, Polymers, Plastics

Abstract

'Additive manufacturing (AM) is a potentially disruptive technology, revolutionizing not only traditional industries but generating entirely new ones through rapid innovation, the democratization of manufacturing, and unprecedented freedom of design. Furthermore, the development of AM technologies has practical implications for economic growth, healthcare, national security, space exploration, and sustainability. For military and space agencies, AM offers the possibility to transform the traditional supply chain system through manufacturing at-point-of-demand, recycling, and indigenous sourcing of raw materials. Similarly, these concepts are being leveraged by remote communities across the globe through efforts such as Fab Labs, which provide low-cost access to manufacturing technologies. AM is transforming healthcare in unexpected ways: doctors and patients have access to high-quality physical 3D models generated directly from computerized tomography (CT) scans. These surgical guides have proved invaluable in surgical preparation and patient consent. In the lab, researchers are developing medical devices or implants which mimic the patient's physiology, are pre-loaded with therapeutics, and are replaced with the patient's cells through natural tissue repair pathways. Pushing the limits of resolution, multi-photon technologies, which allow subdiffraction-limited resolution, are revolutionizing the development of micro-optical components. Unfortunately, adoption of AM technologies by industry has been slow; and while there are numerous success stories and commercial adoption is steadily increasing, AM is hampered by weak parts, incomplete certification methods, and empirical materials development. Regulatory and standards bodies are working to update or develop new standards and policies to deal with the unique material and production issues posed by AM. Many of the challenges facing the industry stem from our limited understanding of structure-process-performance relationships. These challenges fall into many categories and require a broad range of skills to address. For the researcher, AM processes offer unique challenges in materials development, metrology, and modeling, as well as opportunities to combine all three. What makes a polymer printable? What process parameters are important? How should parts be tested? These are all active areas of investigation. This book was inspired by the 2017 ACS Symposium'Additive Manufacturing of Structures and Functional Devices: Materials, Methods, Models, and Testing'and is supplemented by additional experts in the polymer AM field. The chapters discuss the technologies, measurement challenges, manufacturing opportunities, and fabrication potentials. We begin with an introduction to polymer additive manufacturing, identifying the measurement needs and technical challenges facing the industry. A chapter reviewing polymer powder bed fusion follows, providing a complete discussion on methods, materials, and applications. The bulk of the book covers thermoplastic material extrusion, with chapters discussing recycling-based feedstocks, composites materials, and multi-physics modeling linking experimentation and theory. Moving from thermoplastics to conductive inks, a chapter on in situ monitoring and control of direct-ink-write provides a clear example of how theory and modern machine vision can be used to create a practical and responsive control system. The last chapter provides a state-of-the-art review of multi-photon printing, discussing methods, materials, and the stunning capabilities of the technique'--

Published

2019

18. Fabrication of Hierarchical Microstructures via Laser-Induced Shrinkage of Shape Memory Polymers for Flexible Pressure Sensing.

Author

Chen R, Zhang C, Xiao C, Zhao T, Luo T, and Zhou W

Abstract

Hierarchical microstructures are widely recognized as one of the most effective components for enhancing the performance of flexible pressure sensors. However, the rapid and controllable fabrication of pressure sensing layers with hierarchical microstructures remains a significant challenge. In this study, we propose a method that utilizes laser-induced microscale shrinkage of shape memory polymers to enable rapid and controllable fabrication of hierarchical microstructures for high-performance pressure sensing. We systematically investigate the influence of UV laser fabrication parameters on the architecture and morphology of hierarchical microstructures. A flexible pressure sensor, equipped with optimized hierarchical microstructures, exhibits a high sensitivity larger than 15 kPa -1 and excellent linearity ( R = 0.994) in a range from 0 to 200 kPa. It features response and recovery times of 57 and 62 ms, respectively, and maintains good stability, enduring over 5,000 cycles. The laser-induced shrinkage of shape memory polymers offers an effective method for the fabrication of hierarchical microstructures, holding great potential to boost the performance of flexible pressure sensors in applications within intelligent robotics and wearable healthcare.2 = 0.994) in a range from 0 to 200 kPa. It features response and recovery times of 57 and 62 ms, respectively, and maintains good stability, enduring over 5,000 cycles. The laser-induced shrinkage of shape memory polymers offers an effective method for the fabrication of hierarchical microstructures, holding great potential to boost the performance of flexible pressure sensors in applications within intelligent robotics and wearable healthcare.

Published

2024

19. Electrolyte-Electrocatalyst Interfacial Effects of Polymeric Materials for Tandem CO 2 Capture and Conversion Elucidated Using In Situ Electrochemical AFM.

Author

Hamilton ST, Kelly M, Smith WA, and Park AA

Abstract

Integrating CO 2 capture and electrochemical conversion has been proposed as a strategy to reduce the net energy required for CO 2 regeneration in traditional CO 2 capture and conversion schemes and can be coupled with carbon-free renewable electricity. Polyethylenimine (PEI)-based materials have been previously studied as CO 2 capture materials and can be integrated in these reactive capture processes. PEI-based electrolytes have been found to significantly increase the CO 2 loading, and impact selectivity and rate of product formation when compared to the conventional aqueous electrolytes. However, the influence of these materials at the catalyst-electrode interface is currently not well understood. In this study, PEI-based electrolytes were prepared and their impact on the morphology of a silver electrode performing electrochemical CO 2 reduction (CO 2 R) was studied using in situ electrochemical atomic force microscopy (EC-AFM). The presence of PEI on the electrode surface could be distinguished based on nanomechanical properties (DMT modulus), and changes were observed as negative polarization was applied, revealing a reorganization of the PEI chains due to electrostatic interactions. These changes were impacted by the electrolyte composition, including the addition of supporting electrolyte KHCO 3 salt, as well as CO 2 captured by the PEI-based electrolyte, which minimized the change in surface mechanical properties and degree of PEI alignment on the electrode surface. The changes in surface mechanical properties were also dependent on the PEI polymer length, with higher molecular weight PEI showing different reconfiguration than the shorter polymer brushes. The study highlights that the choice of polymer material, the electrolyte composition, and CO 2 captured impact the near-electrode environment, which has implications for CO 2 R, and presents EC-AFM as a new tool that can be used to probe the dynamic behavior of these interfaces during electrocatalysis.

Published

2024

20. Detection of Crude Oil in Subsea Environments Using Organic Electrochemical Transistors.

Author

Porter EB, Adaryan S, Ardebili H, Biswal SL, and Verduzco R

Subjects

Bridged Bicyclo Compounds, Heterocyclic chemistry, Environmental Monitoring instrumentation, Environmental Monitoring methods, Thiophenes, Petroleum analysis, Polystyrenes chemistry, Electrochemical Techniques instrumentation, Electrochemical Techniques methods, Transistors, Electronic

Abstract

Current methods for detecting pipeline oil leaks depend primarily on optical detection, which can be slow and have deployment limitations. An alternative non-optical approach for earlier and faster detection of oil leaks would enable a rapid response and reduce the environmental impact of oil leaks. Here, we demonstrate that organic electrochemical transistors (OECTs) can be used as non-optical sensors for crude oil detection in subsea environments. OECTs are thin film electronic devices that can be used for sensing in a variety of environments, but they have not yet been tested for crude oil detection in subsea environments. We fabricated OECTs with poly(3,4-ethylenedioxythiophene)-poly(styrenesulfonate) as the channel and showed that coating the channel with a polystyrene film results in an OECT with a large and measurable response to oil. Oil that comes in contact with the device will adsorb onto the polystyrene film and increases the impedance at the electrolyte interface. We performed electrochemical impedance spectroscopy measurements to quantify the impedance across the device and found an optimal thickness for the polystyrene coating for the detection of oil. Under optimal device characteristics, as little as 10 μg of oil adsorbed on the channel surface produced a statistically significant change in the source-drain current. The OECTs were operable in seawater for the detection of oil, and we demonstrated that the devices can be transferred to flexible substrates which can be easily implemented in vehicles, pipelines, or other surfaces. This work demonstrates a low-cost device for oil detection in subsea environments and provides a new application of OECT sensors for sensing.

Published

2024

21. Real-Space Visualization of Charged Polymer Network of Hydrogel by Double Network Strategy and Mineral Staining.

Author

Noguchi S, Kiyama R, Yoshida M, Marsudi MA, Kashimura N, Tadanaga K, Gong JP, and Nonoyama T

Abstract

Hydrogels consist of three-dimensional (3D) and complicated polymer networks that determine their physical properties. Among the methods for structural analyses of hydrogels, the real-space imaging of a polymer network of hydrogels on a nanometer scale is one of the optimal methods; however, it is highly challenging. In this study, we propose a direct observation method for cationic polymer networks using transmission electron microscopy (TEM). By combining the double network strategy and the mineral staining technique, we overcame the challenges of polymer aggregation and the low electron density of the polymer. An objective cationic network was incorporated into a neutral skeleton network to suppress shrinkage during subsequent staining. Titania mineralization along the cationic polymer strands provided sufficient electron density for the objective polymer network for TEM observation. This observation method enables the visualization of local structures in real space and plays a complementary role to scattering methods for soft matter structure analysis.

Published

2024

22. Deep-Learning Interatomic Potential Connects Molecular Structural Ordering to the Macroscale Properties of Polyacrylonitrile.

Author

Chahal R, Toomey MD, Kearney LT, Sedova A, Damron JT, Naskar AK, and Roy S

Abstract

Polyacrylonitrile (PAN) is an important commercial polymer, bearing atactic stereochemistry resulting from nonselective radical polymerization. As such, an accurate, fundamental understanding of governing interactions among PAN molecular units is indispensable for advancing the design principles of final products at reduced processability costs. While ab initio molecular dynamics (AIMD) simulations can provide the necessary accuracy for treating key interactions in polar polymers, such as dipole-dipole interactions and hydrogen bonding, and analyzing their influence on the molecular orientation, their implementation is limited to small molecules only. Herein, we show that the neural network interatomic potentials (NNIPs) that are trained on the small-scale AIMD data (acquired for oligomers) can be efficiently employed to examine the structures and properties at large scales (polymers). NNIP provides critical insight into intra- and interchain hydrogen-bonding and dipolar correlations and accurately predicts the amorphous bulk PAN structure validated by modeling the experimental X-ray structure factor. Furthermore, the NNIP-predicted PAN properties, such as density and elastic modulus, are in good agreement with their experimental values. Overall, the trend in the elastic modulus is found to correlate strongly with the PAN structural orientations encoded in the Hermans orientation factor. This study enables the ability to predict the structure-property relations for PAN and analogues with sustainable ab initio accuracy across scales.

Published

2024

23. The Development and Atomic Structure of Zinc Oxide Crystals Grown within Polymers from Vapor Phase Precursors.

Author

Weisbord I, Barzilay M, Cai R, Welter E, Kuzmin A, Anspoks A, and Segal-Peretz T

Abstract

Sequential infiltration synthesis (SIS), also known as vapor phase infiltration (VPI), is a quickly expanding technique that allows growth of inorganic materials within polymers from vapor phase precursors. With an increasing materials library, which encompasses numerous organometallic precursors and polymer chemistries, and an expanding application space, the importance of understanding the mechanisms that govern SIS growth is ever increasing. In this work, we studied the growth of polycrystalline ZnO clusters and particles in three representative polymers: poly(methyl methacrylate), SU-8, and polymethacrolein using vapor phase diethyl zinc and water. Utilizing two atomic resolution methods, high-resolution scanning transmission electron microscopy and synchrotron X-ray absorption spectroscopy, we probed the evolution of ZnO nanocrystals size and crystallinity level inside the polymers with advancing cycles─from early nucleation and growth after a single cycle, through the formation of nanometric particles within the films, and to the coalescence of the particles upon polymer removal and thermal treatment. Through in situ Fourier transform infrared spectroscopy and microgravimetry, we highlight the important role of water molecules throughout the process and the polymers' hygroscopic level that leads to the observed differences in growth patterns between the polymers, in terms of particle size, dispersity, and the evolution of crystalline order. These insights expand our understanding of crystalline materials growth within polymers and enable rational design of hybrid materials and polymer-templated inorganic nanostructures.

Published

2024

24. Surfactant-Polymer Complexation and Competition on Drug Nanocrystal Surfaces Control Crystallinity.

Author

Attia L, Nguyen D, Gokhale D, Zheng T, and Doyle PS

Subjects

Hexoses chemistry, Polysorbates chemistry, Methylcellulose chemistry, Surface Properties, Hydrophobic and Hydrophilic Interactions, Polymers chemistry, Surface-Active Agents chemistry, Nanoparticles chemistry, Crystallization, Fenofibrate chemistry, Molecular Dynamics Simulation

Abstract

Nanosizing drug crystals has emerged as a successful approach to enabling oral bioavailability, as increasing drug crystal surface area improves dissolution kinetics and effective solubility. Recently, bottom-up methods have been developed to directly assemble nanosized crystals by leveraging polymer and surfactant excipients during crystallization to control crystal size, morphology, and structure. However, while significant research has investigated how polymers and other single additives inhibit or promote crystallization in pharmaceutical systems, there is little work studying the mechanistic interactions of multiple excipients on drug crystal structure and the extent of crystallinity, which can influence formulation performance. This study explores how the structure and crystallinity of a model hydrophobic drug crystal, fenofibrate, change as a result of competitive interfacial chemisorption between common nonionic surfactants (polysorbate 80 and sorbitan monooleate) and a surface-active polymer excipient (methylcellulose). Classical molecular dynamics simulations highlight how key intermolecular interactions, including surfactant-polymer complexation and surfactant screening of the crystal surface, modify the resulting crystal structure. In parallel, experiments generating drug nanocrystals in hydrogel thin films validate that drug crystallinity increases with an increasing weight fraction of surfactant. Simulation results reveal a connection between accelerated dynamics in the bulk crystal and the experimentally measured extent of crystallinity. To our knowledge, these are the first simulations that directly characterize structural changes in a drug crystal as a result of excipient surface composition and relate the experimental extent of crystallinity to structural changes in the molecular crystal. Our approach provides a mechanistic understanding of crystallinity in nanocrystallization, which can expand the range of orally deliverable small molecule therapies.

Published

2024

25. Mineralization or Polymerization: That Is the Question.

Author

Zhang YJ and Yu HQ

Subjects

Polymers, Minerals, Polymerization

Published

2024

26. Nanoparticle Superlattices with Nonequilibrium Crystal Shapes.

Author

Ye M, Hueckel T, Gatenil PP, Nagao K, Carter WC, and Macfarlane RJ

Abstract

Nanoparticle assembly is a material synthesis strategy that enables precise control of nanoscale structural features. Concepts from traditional crystal growth research have been tremendously useful in predicting and programming the unit cell symmetries of these assemblies, as their thermodynamically favored structures are often identical to atomic crystal analogues. However, these analogies have not yielded similar levels of influence in programming crystallite shapes, which are a consequence of both the thermodynamics and kinetics of crystal growth. Here, we demonstrate kinetic control of the colloidal crystal shape using nanoparticle building blocks that rapidly assemble over a broad range of concentrations, thereby producing well-defined crystal habits with symmetrically oriented dendritic protrusions and providing insight into the crystals' morphological evolution. Counterintuitively, these nonequilibrium crystal shapes actually become more common for colloidal crystals synthesized closer to equilibrium growth conditions. This deviation from typical crystal growth processes observed in atomic or molecular crystals is shown to be a function of the drastically different time scales of atomic and colloidal mass transport. Moreover, the particles are spherical with isotropic ligand grafts, and these kinetic crystal habits are achieved without the need for specifically shaped particle building blocks or external templating or shape-directing agents. Thus, this work provides generalizable design principles to expand the morphological diversity of nanoparticle superlattice crystal habits beyond the anhedral or equilibrium polyhedral shapes synthesized to date. Finally, we use this insight to synthesize crystallite shapes that have never before been observed, demonstrating the ability to both predict and program kinetically controlled superlattice morphologies.

Published

2024

27. Engineering Biodegradable Polyurethanes with Precisely Controlled Hierarchical Structures to Access Shape Memory Effect and Enhanced Bioactivities.

Author

Yuan L, Xiao L, Zhang J, Xiao Y, Yu L, Yang KK, and Wang YZ

Subjects

Cell Proliferation drug effects, Biocompatible Materials chemistry, Biocompatible Materials pharmacology, Animals, Porosity, Cell Adhesion drug effects, Osteogenesis drug effects, Mice, Polyesters chemistry, Cell Differentiation drug effects, Lactones chemistry, Lactones pharmacology, Humans, Caproates chemistry, Dioxanes chemistry, Polymers, Polyurethanes chemistry, Polyurethanes pharmacology

Abstract

Biodegradable polymers with shape memory effects (SMEs) offer promising solutions for short-term medical interventions, facilitating minimally invasive procedures and subsequent degradation without requiring secondary surgeries. However, achieving a good balance among desirable SMEs, mechanical performance, degradation rate, and bioactivities remains a significant challenge. To address this issue, we established a strategy to develop a versatile biodegradable polyurethane (PPDO-PLC) with tunable hierarchical structures via precise chain segment control. Initial copolymerization of l-lactide and ε-caprolactone sets a tunable T g close to body temperature, followed by block copolymerization with poly( p -dioxanone) to form a hard domain. This yields a uniform microphase-separation morphology, ensuring robust SME and facilitating the development of roughly porous surface structures in alkaline environments. Cell experiments indicate that these rough surfaces significantly enhance cellular activities, such as adhesion, proliferation, and osteogenic differentiation. Our approach provides a methodology for balancing biodegradability, SMEs, three-dimensional (3D) printability, and bioactivity in materials through hierarchical structure regulation.

Published

2024

28. Aluminum Carboxylate Modification Enabled Efficient and Stable Perovskite-Polystyrene Thin Films for Light-Emitting Applications.

Author

Wang Y, Wang R, Ge Y, Geng C, and Xu S

Abstract

Lead halide perovskite nanocrystals (PNCs) have demonstrated great potential in emerging display technologies. However, the practical application of PNCs is hindered by the inherent instability of their ionic surface. Here, we proposed a surface modification approach to enhance the stability of CsPbBr 3 PNCs by postsynthetic treatment with aluminum phenylbutyrate (Al(PA) 3 ). Our study reveals that Al(PA) 3 displaces ammonium ligands and binds tightly on surface halide, providing excellent air and moisture resistance while preserving a high quantum efficiency of 81.6%. The modified PNCs maintain a constant photoluminescence intensity under continuous UV light illumination for 500 h. Additionally, the Al(PA) 3 ligand is compatible with styrene, enabling homogeneous dispersion of PNCs in polystyrene matrices to form bright and uniform PNC-PS thin films. We demonstrated the application of the composite films for display backlighting, which exhibits a wide color gamut of 125% NTSC. The result highlights the potential of AlPA-modified PNCs in light-emitting and other optoelectronic devices.

Published

2024

29. Polyphosphazenes in Biomedicine, Engineering, and Pioneering Synthesis

Author

Alexander K. Andrianov, Harry R. Allcock, Kenneth S. Ogueri, Cato T. Laurencin, Maryam Hajfathalian, Mathilde Bouché, David P. Cormode, Victoria Albright, Victor Selin, Hanna Hlushko, Anbazhagan Palanisamy, Alexander Marin, Svetlana A. Sukhishvili, Andre P. Martinez, Bareera Qamar, Thomas R. Fuerst, Silvia Muro, Liyan Qiu, Jun Fu, Patty Wisian-Neilson, Robert H. Neilson, Aitziber Iturmendi, Ian Teasdale, Gabino A. Carriedo, Raquel de la Campa, Alejandro Presa Soto, Joel R. Fried, Alexander K. Andrianov, Harry R. Allcock, Kenneth S. Ogueri, Cato T. Laurencin, Maryam Hajfathalian, Mathilde Bouché, David P. Cormode, Victoria Albright, Victor Selin, Hanna Hlushko, Anbazhagan Palanisamy, Alexander Marin, Svetlana A. Sukhishvili, Andre P. Martinez, Bareera Qamar, Thomas R. Fuerst, Silvia Muro, Liyan Qiu, Jun Fu, Patty Wisian-Neilson, Robert H. Neilson, Aitziber Iturmendi, Ian Teasdale, Gabino A. Carriedo, Raquel de la Campa, Alejandro Presa Soto, and Joel R. Fried

Subjects

Polymers, Biomedical engineering, Radiographic contrast media, Polyphosphazenes, Polyphosphazenes--Industrial applications, Organophosphorus compounds, Contrast media (Diagnostic imaging)

Published

2018

30. Green Polymer Chemistry: New Products, Processes, and Applications

Author

H. N. Cheng, Richard A. Gross, Patrick B. Smith, Seiichi Tada, Hideyuki Miyatake, Takanori Uzawa, Yoshihiro Ito, Laura R. Jarboe, Jeffery B. Klauda, Yingxi Chen, Kirsten M. Davis, Miguel C. Santoscoy, Camila Utsunomia, Seiichi Taguchi, Takeshi Kawabata, Masayuki Oda, Nobutaka Numoto, Fusako Kawai, Qian Liu, Cerasela Zoica Dinu, Kousuke Tsuchiya, Keiji Numata, Kai Chi, Jeffrey M. Catchmark, Yusuke Matsumoto, Daisuke Ishii, Tadahisa Iwata, Atanu Biswas, Sanghoon Kim, Megan Buttrum, Roselayne F. Furtado, Carlucio R. Alves, Yue Cao, Kathryn E. Uhrich, Karla A. Barrera-Rivera, Antonio Martínez-Richa, Tracy Zhang, Bob A. Howell, Steven J. Martin, Brandon Zhu, Daniel Zhang, Sumant Dwivedi, Tatsuo Kaneko, Louis Hollande, Florent Allais, Liang Yue, Joseph F. Stanzione, Elyse A. Baroncini, Alexander W. Bassett, Silvio Curia, Christopher N. Kuncho, Wenhao Liu, Johannes Möller, Julia Kammleiter, Julia Stehle, Akshay Kokil, Emmanuelle Reynaud, Daniel F. Schmidt, Léa Bonnot, Christophe Len, Etienne Grau, Henri Cramail, Manuel Hartweg, C. Remzi Becer, Richard D, H. N. Cheng, Richard A. Gross, Patrick B. Smith, Seiichi Tada, Hideyuki Miyatake, Takanori Uzawa, Yoshihiro Ito, Laura R. Jarboe, Jeffery B. Klauda, Yingxi Chen, Kirsten M. Davis, Miguel C. Santoscoy, Camila Utsunomia, Seiichi Taguchi, Takeshi Kawabata, Masayuki Oda, Nobutaka Numoto, Fusako Kawai, Qian Liu, Cerasela Zoica Dinu, Kousuke Tsuchiya, Keiji Numata, Kai Chi, Jeffrey M. Catchmark, Yusuke Matsumoto, Daisuke Ishii, Tadahisa Iwata, Atanu Biswas, Sanghoon Kim, Megan Buttrum, Roselayne F. Furtado, Carlucio R. Alves, Yue Cao, Kathryn E. Uhrich, Karla A. Barrera-Rivera, Antonio Martínez-Richa, Tracy Zhang, Bob A. Howell, Steven J. Martin, Brandon Zhu, Daniel Zhang, Sumant Dwivedi, Tatsuo Kaneko, Louis Hollande, Florent Allais, Liang Yue, Joseph F. Stanzione, Elyse A. Baroncini, Alexander W. Bassett, Silvio Curia, Christopher N. Kuncho, Wenhao Liu, Johannes Möller, Julia Kammleiter, Julia Stehle, Akshay Kokil, Emmanuelle Reynaud, Daniel F. Schmidt, Léa Bonnot, Christophe Len, Etienne Grau, Henri Cramail, Manuel Hartweg, C. Remzi Becer, and Richard D

Subjects

Phenols, Biopolymers, Epoxy resins, Hydrocortisone, Polymerization, Polymers, Green chemistry, Polysaccharides, Cell membranes

Published

2018

31. Control of Amphiphile Self-Assembling at the Molecular Level: Supra-Molecular Assemblies with Tuned Physicochemical Properties for Delivery Applications

Author

Marc A. Ilies, Marc A Ilies, Uttam Satyal, Vishnu D. Sharma, Christina M. Bailey, Ramanathan Nagarajan, Terri A. Camesano, Jamie L. Betker, Long Xu, Ye Zhang, Thomas J. Anchordoquy, Edithe Selwa, Bogdan I. Iorga, Shota Fujii, Mina Sakuragi, Kazuo Sakurai, Sean F. Gilmore, Wei He, Amy Rasley, Nicholas O. Fischer, Yang Chu, Tianbo Liu, D. Pan, G. Cui, C. T. N. Pham, M. H. Tomasson, K. N. Weilbaecher, G. M. Lanza, Vishnu Dutt Sharma, Jennifer A. Shif, Filiz Karagöz, Robert Dorresteijn, Klaus Müllen, Markus Klapper, Robert F. Pagels, Robert K. Prud’homme, Chester E. Markwalter, Weili Ma, Won H. Suh, Marc A. Ilies, Marc A Ilies, Uttam Satyal, Vishnu D. Sharma, Christina M. Bailey, Ramanathan Nagarajan, Terri A. Camesano, Jamie L. Betker, Long Xu, Ye Zhang, Thomas J. Anchordoquy, Edithe Selwa, Bogdan I. Iorga, Shota Fujii, Mina Sakuragi, Kazuo Sakurai, Sean F. Gilmore, Wei He, Amy Rasley, Nicholas O. Fischer, Yang Chu, Tianbo Liu, D. Pan, G. Cui, C. T. N. Pham, M. H. Tomasson, K. N. Weilbaecher, G. M. Lanza, Vishnu Dutt Sharma, Jennifer A. Shif, Filiz Karagöz, Robert Dorresteijn, Klaus Müllen, Markus Klapper, Robert F. Pagels, Robert K. Prud’homme, Chester E. Markwalter, Weili Ma, and Won H. Suh

Subjects

Lipoproteins, Nanotechnology, Drug carriers (Pharmacy), Nanoparticles, Chemotherapy, Nanomedicine, Micelles, Biological transport, Supramolecular chemistry, Amphiphiles, Self-assembly (Chemistry), Polymers, Biomedical materials, Surface active agents, Molecular structure

Published

2017

32. Ordered Mesoporous Silica Delivering siRNA as Cancer Nanotherapeutics: A Comprehensive Review.

Author

Gupta A, Choudhury AM, Meena J, Bauri S, and Maiti P

Subjects

Humans, Porosity, Nanoparticles chemistry, Nanoparticles therapeutic use, Animals, Drug Carriers chemistry, Silicon Dioxide chemistry, RNA, Small Interfering therapeutic use, RNA, Small Interfering administration & dosage, RNA, Small Interfering chemistry, Neoplasms therapy, Neoplasms drug therapy, Neoplasms genetics

Abstract

Nanosized mesoporous silica has emerged as a promising flexible platform delivering siRNA for cancer treatment. This ordered mesoporous nanosized silica provides attractive features of well-defined and tunable porosity, structure, high payload, and multiple functionalizations for targeted delivery and increasing biocompatibility over other polymeric nanocarriers. Moreover, it also overcomes the lacunae associated with traditional administration of drugs. Chemically modified porous silica matrix efficiently entraps siRNA molecules and prevents their enzymatic degradation and premature release. This Review discusses the synthesis of silica using the sol-gel approach and the advantages with different silica mesostructure. Herein, the factors affecting the synthesis of silica at nanometer scale, shape, porosity and nanoparticle surface modification are also highlighted to attain the desired nanostructured silica carriers. Additional emphasis is given to chemically modified silica delivering siRNA, where the silica nanoparticle surface was modified with different chemical moieties such as amine modified with (3-aminoropyl) triethoxysilane, polyethylenimine, chitosan, poly(ethylene glycol), and cyclodextrin polymer modification to attain high therapeutic loading, improved dispersibility and biocompatibility. Upon systemic administration, ordered mesoporous nanosized silica encounters blood cells, immune cells, and organs mainly of the reticuloendothelial system (RES). Thereby, biocompatibility and biodistribution of silica based nanocarriers are deliberated to design principles for smart and efficacious nanostructured silica-siRNA carriers and their clinical trial status. This Review further reports the future scopes and challenges for developing silica nanomaterial as a promising siRNA delivery vehicle demanding FDA approval.

Published

2024

33. Theranostic Bottle-Brush Polymers Tailored for Universal Solid-Tumor Targeting.

Author

Zhang W, Xu Y, Guo R, Zhuang P, Hong H, Tan H, and Wang M

Subjects

Animals, Humans, Mice, Nanoparticles chemistry, Theranostic Nanomedicine, Antineoplastic Agents chemistry, Antineoplastic Agents pharmacology, Antineoplastic Agents administration & dosage, Drug Carriers chemistry, Cell Line, Tumor, Drug Delivery Systems, Methacrylates chemistry, Polyethylene Glycols chemistry, Polymers chemistry

Abstract

Designing an efficient nanocarrier to target multiple types of cancer remains a major challenge in the development of cancer nanomedicines. The majority of systemically administered nanoparticles (NPs) are rapidly cleared by the liver, resulting in poor tumor-targeting efficiency and severe side effects. Here, we present a delicately tailored design and synthesis of fluorescent bottle-brush polymers and screen nine derived NPs, each varying in size and surface coatings, for tumor imaging and targeted delivery. Our optimized polymer bearing (oligo(ethylene glycol) methyl ether methacrylate) in the side chains shows reduced macrophage uptake, prolonged blood-circulation time (up to 27 h), and exceptionally high accumulation in the tumor compared to the liver, elucidating an immune-evasion-induced tumor-targeting mechanism. High tumor accumulation significantly improved the antitumor efficacy. The outstanding tumor-targeting ability has been further validated across five distinct tumor models, including orthotopic glioblastoma and pancreatic cancer, which demonstrate the universality of our polymeric nanocarrier for tumor-targeting delivery.

Published

2024

34. How to Measure Polymer Degradation? An Analysis of Authors' Choices When Calculating the Carbonyl Index.

Author

S Gomes R, Fernandes AN, and Waldman WR

Subjects

Plastics, Polypropylenes chemistry, Polymers

Abstract

The carbonyl index aims to measure the degradation level and is used in plastic degradation research as a proxy for the general degradation level of collected plastic pieces. According to the choices for carbonyl index calculation, comparison using this index is prevented and must be unveiled by the authors, which does not always happen. In order to study the proper usage of the carbonyl index, regarding the choice of the reference band and the usage of the band intensity or the absorption area, we systematically reviewed the methodologies used for polypropylene as a case study. Based on 95 studies gathered from 2000 to 2024, two main methods were used to determine the carbonyl index: the ratio between the carbonyl band area and the reference band area (33.68%) and the ratio between the highest intensity of the carbonyl band and the reference band (66.31%). The reference band of choice and the type of calculation method produce different carbonyl index values for the same spectra and mean different information, preventing comparison among works with different calculations.

Published

2024

35. Cell-Free Protein Expression in Polymer Materials.

Author

Lee MS, Lee JA, Biondo JR, Lux JE, Raig RM, Berger PN, Bernhards CB, Kuhn DL, Gupta MK, and Lux MW

Subjects

Cell-Free System, Synthetic Biology methods, DNA genetics, Polymers, Protein Biosynthesis

Abstract

While synthetic biology has advanced complex capabilities such as sensing and molecular synthesis in aqueous solutions, important applications may also be pursued for biological systems in solid materials. Harsh processing conditions used to produce many synthetic materials such as plastics make the incorporation of biological functionality challenging. One technology that shows promise in circumventing these issues is cell-free protein synthesis (CFPS), where core cellular functionality is reconstituted outside the cell. CFPS enables genetic functions to be implemented without the complications of membrane transport or concerns over the cellular viability or release of genetically modified organisms. Here, we demonstrate that dried CFPS reactions have remarkable tolerance to heat and organic solvent exposure during the casting processes for polymer materials. We demonstrate the utility of this observation by creating plastics that have spatially patterned genetic functionality, produce antimicrobials in situ, and perform sensing reactions. The resulting materials unlock the potential to deliver DNA-programmable biofunctionality in a ubiquitous class of synthetic materials.

Published

2024

36. Study of the Synergistic Immunomodulatory and Antifibrotic Effects of Dual-Loaded Budesonide and Serpine1 siRNA Lipid-Polymer Nanoparticles Targeting Macrophage Dysregulation in Tendinopathy.

Author

López-Cerdá S, Molinaro G, Tello RP, Correia A, Künig S, Steinberger P, Jeltsch M, Hirvonen JT, Barreto G, Stöckl J, and Santos HA

Subjects

Animals, Humans, Mice, Polymers, RNA, Small Interfering genetics, Budesonide, Macrophages, Inflammation, Lipids, Fibrosis, Tendinopathy, Nanoparticles

Abstract

Musculoskeletal diseases involving tissue injury comprise tendon, ligament, and muscle injury. Recently, macrophages have been identified as key players in the tendon repair process, but no therapeutic strategy involving dual drug delivery and gene delivery to macrophages has been developed for targeting the two main dysregulated aspects of macrophages in tendinopathy, i.e., inflammation and fibrosis. Herein, the anti-inflammatory and antifibrotic effects of dual-loaded budesonide and serpine1 siRNA lipid-polymer hybrid nanoparticles (LPNs) are evaluated in murine and human macrophage cells. The modulation of the gene and protein expression of factors associated with inflammation and fibrosis in tendinopathy is demonstrated by real time polymerase chain reaction and Western blot. Macrophage polarization to the M2 phenotype and a decrease in the production of pro-inflammatory cytokines are confirmed in macrophage cell lines and primary cells. The increase in the activity of a matrix metalloproteinase involved in tissue remodelling is proven, and studies evaluating the interactions of LPNs with T cells proved that dual-loaded LPNs act specifically on macrophages and do not induce any collateral effects on T cells. Overall, these dual-loaded LPNs are a promising combinatorial therapeutic strategy with immunomodulatory and antifibrotic effects in dysregulated macrophages in the context of tendinopathy.

Published

2024

37. Drug-Polymer Nanodroplet Formation and Morphology Drive Solubility Enhancement of GDC-0810.

Author

Barr KE, Ohnsorg ML, Liberman L, Corcoran LG, Sarode A, Nagapudi K, Feder CR, Bates FS, and Reineke TM

Subjects

Solubility, Polymers, Povidone analogs & derivatives, Cinnamates, Indazoles

Abstract

Nanodroplet formation is important to achieve supersaturation of active pharmaceutical ingredients (APIs) in an amorphous solid dispersion. The aim of the current study was to explore how polymer composition, architecture, molar mass, and surfactant concentration affect polymer-drug nanodroplet morphology with the breast cancer API, GDC-0810. The impact of nanodroplet size and morphology on dissolution efficacy and drug loading capacity was explored using polarized light microscopy, dynamic light scattering, and cryogenic transmission electron microscopy. Poly( N -isopropylacrylamide- stat - N,N -dimethylacrylamide) (PND) was synthesized as two linear derivatives and two bottlebrush derivatives with carboxylated or PEGylated end-groups. Hydroxypropyl methylcellulose acetate succinate grade MF (HPMCAS-MF) and poly(vinylpyrrolidone- co -vinyl acetate) (PVPVA) were included as commercial polymer controls. We report the first copolymerization synthesis of a PVPVA bottlebrush copolymer, which was the highest performing excipient in this study, maintaining 688 μg/mL GDC-0810 concentration at 60 wt % drug loading. This is likely due to strong polymer-drug noncovalent interactions and the compaction of GDC-0810 along the PVPVA bottlebrush backbone. Overall, it was observed that the most effective formulations had a hydrodynamic radius less than 25 nm with tightly compacted nanodroplet morphologies.

Published

2024

38. Polysarcosine as PEG Alternative for Enhanced Camptothecin-Induced Cancer Immunogenic Cell Death.

Author

Yao X, Sun C, Xiong F, Zhang W, Yao W, Xu Y, Fan W, and Huo F

Subjects

Humans, Camptothecin, Immunogenic Cell Death, Polymers, Polyethylene Glycols, Sarcosine analogs & derivatives, Neoplasms, Peptides

Abstract

Nanomedicine-enhanced immunogenic cell death (ICD) has attracted considerable attention for its great potential in cancer treatment. Even though polyethylene glycol (PEG) is widely recognized as the gold standard for surface modification of nanomedicines, some shortcomings associated with this PEGylation, such as hindered cell endocytosis and accelerated blood clearance phenomenon, have been revealed in recent years. Notably, polysarcosine (PSar) as a highly biocompatible polymer can be finely synthesized by mild ring-opening polymerization (ROP) of sarcosine N -carboxyanhydrides (Sar-NCAs) and exhibit great potential as an alternative to PEG. In this article, PSar- b -polycamptothecin block copolymers are synthesized by sequential ROP of camptothecin-based NCAs (CPT-NCAs) and Sar-NCAs. Then, the detailed and systematic comparison between PEGylation and PSarylation against the 4T1 tumor model indicates that PSar decoration can facilitate the cell endocytosis, greatly enhancing the ICD effects and antitumor efficacy. Therefore, it is believed that this well-developed PSarylation technique will achieve effective and precise cancer treatment in the near future.

Published

2024

39. Tailored Branched Polymer-Protein Bioconjugates for Tunable Sieving Performance.

Author

Kapil K, Murata H, Szczepaniak G, Russell AJ, and Matyjaszewski K

Subjects

Polymerization, Membrane Proteins, Polymers, Chymotrypsin metabolism

Abstract

Protein-polymer conjugates combine the unique properties of both proteins and synthetic polymers, making them important materials for biomedical applications. In this work, we synthesized and characterized protein-branched polymer bioconjugates that were precisely designed to retain protein functionality while preventing unwanted interactions. Using chymotrypsin as a model protein, we employed a controlled radical branching polymerization (CRBP) technique utilizing a water-soluble inibramer, sodium 2-bromoacrylate. The green-light-induced atom transfer radical polymerization (ATRP) enabled the grafting of branched polymers directly from the protein surface in the open air. The resulting bioconjugates exhibited a predetermined molecular weight, well-defined architecture, and high branching density. Conformational analysis by SEC-MALS validated the controlled grafting of branched polymers. Furthermore, enzymatic assays revealed that densely grafted polymers prevented protein inhibitor penetration, and the resulting conjugates retained up to 90% of their enzymatic activity. This study demonstrates a promising strategy for designing protein-polymer bioconjugates with tunable sieving behavior, opening avenues for applications in drug delivery and biotechnology.

Published

2024

40. Comparative Study on the Lubrication Mechanism and Performance of Two Representative Ionic and Nonionic Self-Adhesive Polymer Coatings.

Author

Jia Y, Yang Y, and Zhang H

Subjects

Humans, Lubrication, Water, Polymers, Resin Cements

Abstract

Surface modification of lubricating coatings on biomedical devices is a pivotal strategy to improve the overall performance and clinical efficacy, significantly reducing friction between devices and human tissues and mitigating tissue damage during intervention and long-term implantation. Recently, various hydrophilic polymeric materials have been used for achieving surface functionalization, endowing the biomedical device with excellent superlubrication performance. N -Vinylpyrrolidone (NVP) and 2-methacryloyloxyethyl phosphorylcholine (MPC) are two typical representatives of nonionic and zwitterionic materials. However, there is still a research gap in a comparative study of the lubrication mechanisms and properties between them. In this study, a bioinspired and dopamine-assisted codeposition technique was used to fabricate biomimetic hydrophilic coatings, including P(DMA-NVP) and P(DMA-MPC), on polyurethane. To achieve a thorough comparative analysis of the self-adhesive coating performance, 3 M ratios of the copolymers were synthesized and comprehensive material evaluations were conducted. Additionally, surface morphology, hydrophilicity, and lubrication at both the microscale and macroscale were performed. It was found that both hydrophilic coatings exhibited good stability. The P(DMA-MPC) coating, due to the ability to attract and bind a large number of water molecules, demonstrated superior lubrication effects compared to the P(DMA-NVP) coating. The study provides an in-depth understanding of the lubrication behavior of the self-adhesive coatings to enhance the functionality and application in biomedical engineering.

Published

2024

41. Highly Efficient Photoswitchable Smart Polymeric Nanovehicle for Gene and Anticancer Drug Delivery in Triple-Negative Breast Cancer.

Author

Patra R, Halder S, Saha R, Jana K, and Sarkar K

Subjects

Humans, Drug Delivery Systems, Polymers, Ions, Triple Negative Breast Neoplasms drug therapy, Triple Negative Breast Neoplasms genetics, Antineoplastic Agents pharmacology

Abstract

Over the past few decades, there has been significant interest in smart drug delivery systems capable of carrying multiple drugs efficiently, particularly for treating genetic diseases such as cancer. Despite the development of various drug delivery systems, a safe and effective method for delivering both anticancer drugs and therapeutic genes for cancer therapy remains elusive. In this study, we describe the synthesis of a photoswitchable smart polymeric vehicle comprising a photoswitchable spiropyran moiety and an amino-acid-based cationic monomer-based block copolymer using reversible addition-fragmentation chain transfer (RAFT) polymerization. This system aims at diagnosing triple-negative breast cancer and subsequently delivering genes and anticancer agents. Triple-negative breast cancer patients have elevated concentrations of Cu 2+ ions, making them excellent targets for diagnosis. The polymer can detect Cu 2+ ions with a low limit of detection value of 9.06 nM. In vitro studies on doxorubicin drug release demonstrated sustained delivery at acidic pH level similar to the tumor environment. Furthermore, the polymer exhibited excellent blood compatibility even at the concentration as high as 500 μg/mL. Additionally, it displayed a high transfection efficiency of approximately 82 ± 5% in MDA-MB-231 triple-negative breast cancer cells at an N/P ratio of 50:1. It is observed that mitochondrial membrane depolarization and intracellular reactive oxygen species generation are responsible for apoptosis and the higher number of apoptotic cells, which occurred through the arrest of the G2/M phase of the cell cycle were observed. Therefore, the synthesized light-responsive cationic polymer may be an effective system for diagnosis, with an efficient anticancer drug and gene carrier for the treatment of triple-negative breast cancer in the future.

Published

2024

42. Benchmarking the Humidity-Dependent Mechanical Response of (Nano)fibrillated Cellulose and Dissolved Polysaccharides as Sustainable Sand Amendments.

Author

Dali MA, Abidnejad R, Salim MH, Bhattarai M, Imani M, Rojas OJ, Greca LG, and Tardy BL

Subjects

Benchmarking, Humidity, Soil chemistry, Water chemistry, Polymers, Sand, Cellulose

Abstract

Soil quality is one of the main limiting factor in the development of the food sector in arid areas, mainly due to its poor mechanics and lack of water retention. Soil's organic carbon is nearly absent in arid soils, though it is important for water and nutrient transport, to soil mechanics, to prevent erosion, and as a long-term carbon sink. In this study, we evaluate the potential benefits that are brought to inert sand by the incorporation of a range of, mainly, cellulosic networks in their polymeric or structured (fiber) forms, analogously to those found in healthy soils. We explore the impact of a wide range of nonfood polysaccharide-based amendments, including pulp fibers, nanocellulose, cellulose derivatives, and other readily available polysaccharide structures derived from arthropods (chitosan) or fruit peels (pectin) residues. A practical methodology is presented to form sand-polymer composites, which are evaluated for their soil mechanics as a function of humidity and the dynamics of their response to water. The mechanics are correlated to the network of polymers formed within the pores of the sandy soil, as observed by electron microscopy. The response to water is correlated to both the features of the network and the individual polysaccharides' physicochemical features. We expect this work to provide a rapid and reproducible methodology to benchmark sustainable organic amendments for arid soils.

Published

2024

43. Graph Network-Based Simulation of Multicellular Dynamics Driven by Concentrated Polymer Brush-Modified Cellulose Nanofibers.

Author

Yoshikawa C, Nguyen DA, Nakaji-Hirabayashi T, Takigawa I, and Mamitsuka H

Subjects

Cellulose chemistry, Polymers, Nanofibers chemistry

Abstract

Manipulating the three-dimensional (3D) structures of cells is important for facilitating to repair or regenerate tissues. A self-assembly system of cells with cellulose nanofibers (CNFs) and concentrated polymer brushes (CPBs) has been developed to fabricate various cell 3D structures. To further generate tissues at an implantable level, it is necessary to carry out a large number of experiments using different cell culture conditions and material properties; however this is practically intractable. To address this issue, we present a graph-neural network-based simulator (GNS) that can be trained by using assembly process images to predict the assembly status of future time steps. A total of 24 (25 steps) time-series images were recorded (four repeats for each of six different conditions), and each image was transformed into a graph by regarding the cells as nodes and the connecting neighboring cells as edges. Using the obtained data, the performances of the GNS were examined under three scenarios (i.e., changing a pair of the training and testing data) to verify the possibility of using the GNS as a predictor for further time steps. It was confirmed that the GNS could reasonably reproduce the assembly process, even under the toughest scenario, in which the experimental conditions differed between the training and testing data. Practically, this means that the GNS trained by the first 24 h images could predict the cell types obtained 3 weeks later. This result could reduce the number of experiments required to find the optimal conditions for generating cells with desired 3D structures. Ultimately, our approach could accelerate progress in regenerative medicine.

Published

2024

44. Regulation of Photophysical Behaviors in Hyperbranched Aggregation-Induced Emission Polymers for Reactive Oxygen Species Scavenging.

Author

Zhao Y, Xu L, Feng Z, Yin S, Feng W, and Yan H

Subjects

Reactive Oxygen Species, Biocompatible Materials, Polymers, Electrons

Abstract

Developing nonconjugated materials with large Stokes shifts is highly desired. In this work, three kinds of hyperbranched aggregation-induced emission (AIE) polymers with tunable n/π electronic effects were synthesized. HBPSi-CBD contains alkenyl groups in the backbone and possesses a promoted n-π* transition and red-shifted emission wavelength with a large Stokes shift of 186 nm. Experiments and theoretical simulations confirmed that the planar π electrons in the backbone are responsible for the red-shifted emission due to the strong through-space n···π interactions and restricted backbone motions. Additionally, the designed HBPSi-CBD could be utilized as an ROS scavenger after coupling with l-methionine. The HBPSi-Met exhibits remarkable ROS scavenging properties with a scavenging capacity of 77%. This work not only gains further insight into the structure-property relationship of nonconjugated hyperbranched AIE polymers but also provides a promising ROS-scavenging biomaterial for the treatment of ROS-related diseases.

Published

2024

45. MicroRNA-200c Release from Gelatin-Coated 3D-Printed PCL Scaffolds Enhances Bone Regeneration.

Author

Remy MT, Upara C, Ding QJ, Miszuk JM, Sun H, and Hong L

Subjects

Animals, Gelatin pharmacology, Gelatin chemistry, Tissue Scaffolds chemistry, Bone Regeneration genetics, Polymers, Printing, Three-Dimensional, Osteogenesis genetics, MicroRNAs genetics

Abstract

The fabrication of clinically relevant synthetic bone grafts relies on combining multiple biodegradable biomaterials to create a structure that supports the regeneration of defects while delivering osteogenic biomolecules that enhance regeneration. MicroRNA-200c ( miR-200c ) functions as a potent osteoinductive biomolecule to enhance osteogenic differentiation and bone formation; however, synthetic tissue-engineered bone grafts that sustain the delivery of miR-200c for bone regeneration have not yet been evaluated. In this study, we created novel, multimaterial, synthetic bone grafts from gelatin-coated 3D-printed polycaprolactone (PCL) scaffolds. We attempted to optimize the release of pDNA encoding miR-200c by varying gelatin types, concentrations, and polymer crosslinking materials to improve its functions for bone regeneration. We revealed that by modulating gelatin type, coating material concentration, and polymer crosslinking, we effectively altered the release rates of pDNA encoding miR-200c, which promoted osteogenic differentiation in vitro and bone regeneration in a critical-sized calvarial bone defect animal model. We also demonstrated that crosslinking the gelatin coatings on the PCL scaffolds with low-concentration glutaraldehyde was biocompatible and increased cell attachment. These results strongly indicate the potential use of gelatin-based systems for pDNA encoding microRNA delivery in gene therapy and further demonstrate the effectiveness of miR-200c for enhancing bone regeneration from synthetic bone grafts.

Published

2024

46. Polymersomes in Drug Delivery─From Experiment to Computational Modeling.

Author

Xu Q, Wang Y, Zheng Y, Zhu Y, Li Z, Liu Y, and Ding M

Subjects

Pharmaceutical Preparations, Polymers, Drug Delivery Systems methods

Abstract

Polymersomes, composed of amphiphilic block copolymers, are self-assembled vesicles that have gained attention as potential drug delivery systems due to their good biocompatibility, stability, and versatility. Various experimental techniques have been employed to characterize the self-assembly behaviors and properties of polymersomes. However, they have limitations in revealing molecular details and underlying mechanisms. Computational modeling techniques have emerged as powerful tools to complement experimental studies and enabled researchers to examine drug delivery mechanisms at molecular resolution. This review aims to provide a comprehensive overview of the state of the art in the field of polymersome-based drug delivery systems, with an emphasis on insights gained from both experimental and computational studies. Specifically, we focus on polymersome morphologies, self-assembly kinetics, fusion and fission, behaviors in flow, as well as drug encapsulation and release mechanisms. Furthermore, we also identify existing challenges and limitations in this rapidly evolving field and suggest possible directions for future research.

Published

2024

47. Simultaneous Regulation of the Mechanical/Osteogenic Capacity of Brushite Calcium Phosphate Cement by Incorporating with Poly(ethylene glycol) Dicarboxylic Acid.

Author

Gao W, Wang H, Liu R, Ba X, Deng K, and Liu F

Subjects

Prospective Studies, Calcium Phosphates pharmacology, Polymers, Dicarboxylic Acids pharmacology, Polyethylene Glycols pharmacology, Bone Cements pharmacology

Abstract

Brushite calcium phosphate cement (brushite CPC) is a prospective bone repair material due to its ideal resorption rates in vivo. However, the undesirable mechanical property and bioactivity limited its availability in clinic application. To address this issue, incorporating polymeric additives has emerged as a viable solution. In this study, poly(ethylene glycol) dicarboxylic acid, PEG(COOH), was synthesized and employed as the polymeric additive. The setting behavior, anti-washout ability, mechanical property, degradation rate, and osteogenic capacity of brushite CPC were regulated by incorporating PEG(COOH). The incorporation of PEG(COOH) with carboxylic acid groups demonstrated a positive effect on both mechanical properties and osteogenic activity in bone repair. This study offers valuable insights and suggests a promising strategy for the development of materials in bone tissue engineering.

Published

2024

48. Multimodal Transformer for Property Prediction in Polymers.

Author

Han S, Kang Y, Park H, Yi J, Park G, and Kim J

Abstract

In this work, we designed a multimodal transformer that combines both the Simplified Molecular Input Line Entry System (SMILES) and molecular graph representations to enhance the prediction of polymer properties. Three models with different embeddings (SMILES, SMILES + monomer, and SMILES + dimer) were employed to assess the performance of incorporating multimodal features into transformer architectures. Fine-tuning results across five properties (i.e., density, glass-transition temperature ( T g ), melting temperature ( T m ), volume resistivity, and conductivity) demonstrated that the multimodal transformer with both the SMILES and the dimer configuration as inputs outperformed the transformer using only SMILES across all five properties. Furthermore, our model facilitates in-depth analysis by examining attention scores, providing deeper insights into the relationship between the deep learning model and the polymer attributes. We believe that our work, shedding light on the potential of multimodal transformers in predicting polymer properties, paves a new direction for understanding and refining polymer properties.

Published

2024

49. Polymer Microspheres Copolymerized with Deep Red Fluorescent Molecules as a Label for Lateral Flow Immunochromatography.

Author

Han J, Lv Q, Su D, Chen L, Zhu S, Liu Q, Jiang Y, Li X, Jiang Y, and Wang Z

Subjects

Microspheres, Immunoassay, Chromatography, Affinity methods, Fluorescent Dyes chemistry, Polymers

Abstract

The development of fluorescently labeled microspheres is a critical aspect of advancing the technology of lateral flow immunochromatography (LFIA) for biological detection. Nevertheless, potential interference posed by the background fluorescence originating from the nitrocellulose (NC) membrane would significantly impact the sensitivity and accuracy of microsphere-based detection in LFIA. In this work, an attempt was made to extend the π-conjugated system and asymmetric structure of rhodamine fluorophore, resulting in the synthesis of dye molecules (RB2) incorporating double bonds, which can reach an absolute photoluminescence quantum yield (PLQY) of 30.01% in EtOH. Subsequently, carboxyl group functionalized fluorescent microspheres were prepared in a two-step copolymerization via soap-free emulsion polymerization. The obtained microspheres were characterized by scanning electron microscopy, transmission electron microscopy, DLS, Fourier transform infrared spectroscopy, ultraviolet spectrophotometry, and fluorescence spectrophotometry. The results showed that RB2 was successfully copolymerized into the microspheres, and the resulting microspheres had good dispersion and stability with high red fluorescence intensity (λ abs ∼ 610 nm, λ em ∼ 660 nm). Utilizing these microspheres, the resulting lateral flow immunoassay was successfully found to detect SARS-CoV-2 N protein with a detection limit of 2.5 pg/mL and the linear concentration spanning from 2.5 pg/mL to 10 ng/mL. The results confirm the effectiveness of the synthetic fluorescent microspheres as the label for LFIA.

Published

2024

50. All-Natural Plant-Derived Polyurethane as a Substitute of a Petroleum-Based Polymer Coating Material.

Author

Yang M, Zhang J, Sun Z, and Sun D

Subjects

Delayed-Action Preparations, Polymers, Isocyanates, Polyurethanes, Fertilizers

Abstract

The development of efficient, biobased polyurethane controlled-release fertilizers from sustainable and eco-friendly biomaterials has received increased research attention, owing to concerns regarding global food security and environmental sustainability. Most previous studies focused on replacing petroleum-based polyols with biopolyols; however, the other main raw material, isocyanate, remained a petrochemical product. Herein, all-natural, plant-derived polyurethane-coated urea was successfully developed using castor oil and biobased isocyanate, and the performance of the coating shell before and after modification was compared. The results showed that the incorporation of a low dose of lauric acid copper into the coating material simultaneously enhanced the hydrophobicity and elasticity of the all-biobased polyurethane membrane, which prolonged the nitrogen release longevity from 3 to 112 days. In addition, the modified membrane showed excellent biodegradability in a soil environment. The novel all-biobased polyurethane coating material and modification technique provide insight for developing sustainable and eco-friendly controlled-release fertilizers.

Published

2024