Hemocompatibility of hydrophilic antimicrobial copolymers of alkylated 4-vinylpyridine

Quaternized poly(vinylpyridine) (PVP) is a polymer with inherent antimicrobial properties that is effective against Gram-positive bacteria, Gram-negative bacteria, viruses, and yeast cells. However, quaternized PVP has poor biocompatibility, which prevents its use in biomaterial applications. Copolymerization was examined as a method of modifying the structure to incorporate biocompatibility. Polyethyleneglycol methyl ether methacrylate (PEGMA) and hydroxyethyl methacrylate (HEMA) are polymers generally known to be biocompatible and thus were chosen as comonomers. Random copolymers of 4-vinylpyridine and PEGMA or HEMA were synthesized via free radical polymerization and quaternized with bromohexane. Copolymer biocompatibility was characterized by interaction with human red blood cells to analyze hemolysis. Hemolysis of human red blood cells was conducted on insoluble films and on water-soluble polymers in a serial dilution study. Hemolysis results demonstrated that blood compatibility does not depend on PEG chain length in PEGMA incorporated copolymers. Results indicate a critical weight ratio of PEGMA to VP in copolymers separating the no-hemolysis regime from 100% hemolysis.     

Synergistic activity of hydrophilic modification in antibiotic polymers

Quaternized poly(vinylpyridine) is known to kill up to 99% of drug-resistant gram-positive and -negative bacteria but shows minimal biocompatibility. We report enhanced bactericidal activity of vinylpyridine through copolymerization with hydroxyethyl methacrylate and poly(ethylene gycol) methyl ether methacrylate. Copolymers with increasing comonomer content were synthesized by radical polymerization and quaternized with hexylbromide. We assessed the effects of the changes in polymer composition on the bactericidal activity of the surface activity using a bioluminescent pathogenic strain of Escherichia coli (O157:H7). By recording the photoluminescence emitted by these bacteria in contact with the copolymers, it was shown that several of the copolymers possess better antibacterial efficiency than quaternized poly(vinylpyridine). Results indicate that several of the copolymers synthesized possess antibacterial activity approximately 20 times greater than the pure quaternized poly(vinylpyridine) homopolymer, while only containing 1 wt % hexylated pyridinium. This behavior is explained by the increased surface wettability of the copolymers containing lesser amounts of poly(vinylpyridine), as bactericidal behavior correlates to the hydrophilicity of the system as measured by contact angles. A hydrophilicity based design-paradigm can significantly improve both the efficacy and the biocompatibility of antibacterial materials.     

Self-assembly of reactive amphiphilic block copolymers as mimetics for biological membranes

Over the years, polymers have attracted a great deal of interest because they offer a unique platform for the development of materials in fields as diverse as biomedicine and packaging. Many of these purposes use polymers that had been developed for totally different applications. Recently, however, chemical tailoring and molecular and supramolecular control of the chemistry and, thus, the physical and biological response have become a key interest of many researchers. In particular, systems that operate in aqueous media have become an intensely researched field. This is mostly because many devices must be biocompatible, which implies that they have to function in aqueous solutions. Over the past few years, new approaches for mimicking cell surfaces, for generating biocompatible and bioactive drug delivery systems, and for directed targeting have been developed. One recent development is polymeric systems with an enhanced biofunctionality, such as amphiphilic block copolymers that can act as mimetics for biological membranes. Because there are virtually no limits to combinations of monomers, biological and synthetic building blocks, ligands, receptors, and other proteins, polymer hybrid materials show a great promise for applications in biomedicine and biotechnology.     

Solution‐Processable Conjugated Polymers as Anode Interfacial Layer Materials for Organic Solar Cells

In recent years, solution‐processed conjugated polymers have been extensively used as anode interfacial layer (AIL) materials in organic solar cells (OSCs) due to their excellent film‐forming property and low‐temperature processing advantages. In this review, the authors focus on the recent advances in conjugated polymers as AIL materials in OSCs. Several of the main classes of solution‐processable conjugated polymers, including poly(3,4‐ethylenedioxythiophene):(styrenesulfonate), polyaniline, polythiophene, conjugated polyelectrolytes, sulfonated poly(diphenylamine), and crosslinked polymers as AIL materials are discussed in depth, and the mechanisms of these AIL materials in enhancing OSC performances are also elucidated. The structure–property relationships of various conjugated polymer AIL materials are analyzed, and some important design rules for such materials toward high efficiencies and stable OSCs are presented. In addition, some chemical and physical approaches to optimize the photoelectronic and physic properties of conjugated polymer AIL materials, which improve their performance in modifying OSCs, are also highlighted. Considering the significance of tandem OSCs, the relevant applications of conjugated polymer AIL materials in constructing interconnection layers for tandem OSCs are also mentioned. Finally, a brief summary is presented and some perspectives to help researchers understand the current challenges and opportunities in this area are proposed.     

Genetic engineering of structural protein polymers.

Genetic and protein engineering are components of a new polymer chemistry that provide the tools for producing macromolecular polyamide copolymers of diversity and precision far beyond the current capabilities of synthetic polymer chemistry. The genetic machinery allows molecular control of chemical and physical chain properties. Nature utilizes this control to formulate protein polymers into materials with extraordinary mechanical properties, such as the strength and toughness of silk and the elasticity and resilience of mammalian elastin. The properties of these materials have been attributed to the presence of short repeating oligopeptide sequences contained in the proteins, fibroin, and elastin. We have produced homoblock protein polymers consisting exclusively of silk-like crystalline blocks and elastin-like flexible blocks. We have demonstrated that each homoblock polymer as produced by microbial fermentation exhibits measurable properties of crystallinity and elasticity. Additionally, we have produced alternating block copolymers of various amounts of silk-like and elastin-like blocks, ranging from a ratio of 1:4 to 2:1, respectively. The crystallinity of each copolymer varies with the amount of crystalline block interruptions. The production of fiber materials with custom-engineered mechanical properties is a potential outcome of this technology.     

Poly(3-hydroxyalkanoate)s functionalized with carboxylic acid groups in the side chain

Biodegradable polyesters represent an important class of materials, and one subset of these polymers are the bacterially produced poly(3-hydroxyalkanoate)s (PHA), a bacterially produced material. These polymers are very hydrophobic, and chemical methods to increase their hydrophilicity will ultimately lead to new applications. Many copolymers of PHA are known that contain simple, nonpolar functionality in the side chain, and we explored the conversion of side-chain olefins to carboxylic acids under conditions that minimize molecular weight degradation. With the use of osmium tetraoxide and oxone, the conversion proceeded to completion with little backbone degradation, which was confirmed with NMR, IR, and gel permeation chromatography (GPC). The solubility character of the polymer before and after reaction is very different, and several solvents were explored including acetone, tetrahydrofuran (THF), and water.     

Synthesis and biologically relevant properties of polyphosphazene polyacids

Polyphosphazene polyacids show potential as immunostimulating compounds and materials for microencapsulation. Their synthesis requires multistep chemical transition from a hydrolytically unstable macromolecular precursor, poly(dichlorophosphazene), to a water-soluble polyelectrolyte. Insufficient synthetic control in these reactions can lead to molecular weight variations and formation of macromolecules with "structural defects" resulting in significant variations in polymer performance. Simple and reproducible "one pot-one solvent" method is reported for the preparation of polyphosphazene polyacids-poly[di(carboxylatophenoxy)phosphazene] and its copolymers. Molecular weight characteristics and polymer compositions were studied as a function of reaction parameters. Macromolecular byproducts, incompletely substituted polymers containing hydroxyl groups and partially deprotected polymers containing propyl ester functionalities, were synthesized and characterized. It was demonstrated, that the presence of such groups can affect polymer characteristics, such as hydrolytic degradation profiles, immunostimulating activity, and microsphere forming properties. In vivo studies showed that the immunostimulating activity of polyphosphazene polyacids correlates with the content of acid functionalities in the polymer.     

Biosynthesis, modification, and biodegradation of bacterial medium-chain-length polyhydroxyalkanoates

Medium-chain-length polyhydroxyalkanoates (MCL-PHAs), which have constituents with a typical chain length of C6-C14, are polyesters that are synthesized and accumulated in a wide variety of Gram-negative bacteria, mainly pseudomonads. These biopolyesters are promising materials for various applications because they have useful mechanical properties and are biodegradable and biocompatible. The versatile metabolic capacity of some Pseudomonas spp. enables them to synthesize MCL-PHAs that contain various functional substituents; these MCL-PHAs are of great interest because these functional groups can improve the physical properties of the polymers, allowing the creation of tailor-made products. Moreover, some functional substituents can be modified by chemical reactions to obtain more useful groups that can extend the potential applications of MCL-PHAs as environmentally friendly polymers and functional biomaterials for use in biomedical fields. Although MCL-PHAs are water-insoluble, hydrophobic polymers, they can be degraded by microorganisms that produce extracellular MCL-PHA depolymerase. MCL-PHA-degraders are relatively uncommon in natural environments and, to date, only a limited number of MCL-PHA depolymerases have been investigated at the molecular level. All known MCL-PHA depolymerases share a highly significant similarity in amino acid sequences, as well as several enzymatic characteristics. This paper reviews recent advances in our knowledge of MCL-PHAs, with particular emphasis on the findings by our research group.     

Bactericidal properties of flat surfaces and nanoparticles derivatized with alkylated polyethylenimines

We previously discovered that covalently coating glass and plastic slides with certain long poly(vinyl-N-alkylpyridinium) chains enables the resultant surfaces to kill a variety of airborne and waterborne bacteria on contact. In the present study, these findings have been extended to an unrelated polymer class, polyethylenimines (PEIs). Alkylated PEIs attached to flat macroscopic surfaces and to those of nanoparticles make these materials highly bactericidal toward both Gram-positive and Gram-negative pathogenic bacteria. Systematic chemical modifications of the immobilized PEI conducted herein shed light on the relationship between the structure of the polymer and the antibacterial efficiency of the resultant coating.     

Sulfated chitin and chitosan as novel biomaterials

Chitin and chitosan are known to be natural polymers and they are non-toxic, biodegradable and biocompatible. Chemical modification of chitin and chitosan with sulfate to generate new bifunctional materials is of interest because the modification would not change the fundamental skeleton of chitin and chitosan, would keep the original physicochemical and biochemical properties and finally would bring new or improved properties. The sulfated chitin and chitosan have a variety of applications, such as, adsorbing metal ions, drug delivery systems, blood compatibility, and antibacterial field. The purpose of this review is to take a closer look about the different synthetic methods and potential applications of sulfated chitin and chitosan. Based on current research and existing products, some new and futuristic approaches in this context area are discussed in detail. From the studies reviewed, we concluded that sulfated chitin and chitosan are promising materials for biomedical applications.     

The effect of the L-azetidine-2-carboxylic acid residue on protein conformation. II. Homopolymers and copolymers

The alteration of polymer conformational properties caused by the replacement of L-proline by L-azetidine-2-carboxylic acid (Aze) has been studied by means of conformational energy computations. In addition to poly(Aze), two sequential copolymers, poly(Pro-Aze) and poly(Aze3-Pro3), have been investigated. All polymers containing Aze are more flexible than poly(Pro). This is a consequence of an increased number of permitted conformational states for the Aze residue, as compared to Pro, when they are incorporated into a polypeptide, as well as of a lessened cooperativity of the trans-cis transition. The results of the computation can be used to interpret the observed physical properties of poly(Aze) and of its copolymers.     

Enzymatic synthesis of galactosyl lactic ethyl ester and its polymer for use as biomaterials

Lactate-based chemicals and polymers including poly(lactic acid) (PLA) are highly valuable materials for biomedical, food and general-purpose applications. Chemical synthesis, albeit the high reaction velocities achieved with it, often leaves chemical residues that are subject to health and safety concerns. Alternative biosynthesis is preferred in order to overcome these problems. Herein we report a novel enzymatic synthesis for the preparation of beta-d-galactosyl-l-lactic acid ethyl ester (GLAEE). Such a product, which may find applications in food and personal care products, is generally difficult to synthesize via traditional chemical routes because the reactions have to be highly selective due to the multiple hydroxyl groups of sugars. We further explore the enzymatic polymerization of GLAEE to form a unique biopolymer, poly(beta-d-galactoside-co-l-lactic acid) (PGLA). Novozyme 435 was found efficient in catalyzing the polymerization reaction in acetone with a conversion yield of 60% within 100 h. The molecular weight of the polymer product ranged from about 800-2000 as analyzed by using ESI-MS. It is expected that a variety of sugar-hydroxyl acids copolymers can be prepared through the same approach and a new class of biomaterials can thus be developed.     

Polymers in drug delivery

Advances in polymer science have led to the development of several novel drug-delivery systems. A proper consideration of surface and bulk properties can aid in the designing of polymers for various drug-delivery applications. Biodegradable polymers find widespread use in drug delivery as they can be degraded to non-toxic monomers inside the body. Novel supramolecular structures based on polyethylene oxide copolymers and dendrimers are being intensively researched for delivery of genes and macromolecules. Hydrogels that can respond to a variety of physical, chemical and biological stimuli hold enormous potential for design of closed-loop drug-delivery systems. Design and synthesis of novel combinations of polymers will expand the scope of new drug-delivery systems in the future.     

Biosynthesis and properties of poly(3-hydroxybutyrate-co-3-hydroxyhexanoate) polymers

In support of programs to identify polyhydroxyalkanoates with improved materials properties, we report on our efforts to characterize the mechanical and thermal properties of copolyesters of 3-hydroxybutyrate (3HB) and 3-hydroxyhexanoate (3HHx). The copolyesters, having molar fraction of 3HHx ranging from 2.5 to 35 mol % and average molecular weights ranging from 1.15 x 10(5) to 6.65 x 10(5), were produced by fermentation using Aeromonas hydrophila and a recombinant strain of Pseudomonas putida GPp104. The polymers were chloroform extracted and characterized by solution-state and solid-state nuclear magnetic resonance (NMR) spectroscopy and a variety of mechanical and thermal tests. Solution-state (1)H NMR data were used to determine polymer composition-of-matter, while solution-state (13)C NMR data provided polymer-sequence information. Solvent fractionation and NMR spectroscopic characterization of these polymers showed that polymers containing up to 9.5 mol % 3HHx had a Bernoullian compositional distribution. By contrast, polymers containing more than 9.5 mol % 3HHx had a bimodal polymer composition. Solvent fractionation of these 3HHx-rich polyesters produced two polymer fractions, each of which was again consistent with Bernoullian polymerization statistics. Solid-state NMR relaxation experiments provided insight into aging in poly(3HB-co-3HHx) copolymers, demonstrating increased polymer-chain motion with increasing 3HHx content. The elongation-to-break ratio in the polyesters increased with increasing molar fraction of 3HHx monomers. Aging properties of the poly(3HB-co-3HHx) copolymers were very similar to copolymers of 3HB and 3-hydroxyvalerate (3HV). However, poly(3HB-co-3HHx) exhibited increased activation energy to thermal degradation with increasing 3HHx content.     

Polymers of malic acid and 3-alkylmalic acid as synthetic PHAs in the design of biocompatible hydrolyzable devices.

Poly(beta-malic acid) and poly(beta-3-alkylmalic acid) derivatives, as synthetic polyhydroxyalkanoates (PHAs), present several advantages as macromolecular materials for temporary biomedical applications. Indeed, such polymers, which can be synthesized through different chemical and biological routes, have cleavable ester bonds in their backbone for hydrolytic degradation, stereogenic centres in the monomers units for controlling the macromolecular structure. bioassimilable or non-toxic repeating units and lateral chemical functions which can be adapted to specific requirements. The strategy for building such complex architectures, with one or several specific pendant groups, is based on the anionic ring-opening polymerization or copolymerization of the large family of malolactonic and 3-alkylmalolactonic acid esters. Because we are able to control the monomer synthesis and the polymerization step, we have been able to prepare different degradable materials for the biomedical field, such as: degradable associating networks made up by the association of random copolyesters containing a small percentage of hydrophobic moieties and beta-cyclodextrin copolymers; degradable macromolecular micelles constituted by degradable amphiphilic block copolymers of poly(beta-malic acid) as hydrophilic segments and poly(beta-alkylmalic acid alkyl esters) as hydrophobic blocks; and degradable nanoparticles made up by hydrophobic poly(beta-malic acid alkyl esters) derivatives. We have also prepared a terpolymer which exhibits growth factor-like properties in vivo. Finally, poly(beta-malic acid) has been used as an additive in the preparation of peritoneal dialysis bags.     

Synthesis and self-assembly of well-defined poly(amino acid) end-capped poly(ethylene glycol) and poly(2-methyl-2-oxazoline)

Poly(ethylene glycol) (PEG) and poly(2-methyl-2-oxazoline) (PMOx) are water-soluble, biocompatible polymers with stealth hemolytic activities. Poly(amino acid) (PAA) end-capped PEG and PMOx were prepared using amino-terminated derivatives of PEG and PMOx as macroinitiators for the ring-opening polymerization of γ-benzyl protected l-glutamate N-carboxyanhydride and S-benzyloxycarbonyl protected l-cysteine N-carboxyanhydride, respectively, in the presence of urea, at room temperature. The molecular weight of the PAA moiety was kept between M(n) = 2200 and 3000 g mol(-1). PMOx was polymerized by cationic ring-opening polymerization resulting in molecular weights of M(n) = 5000 and 10,000 g mol(-1), and PEG was a commercial product with M(n) = 5000 g mol(-1). Here, we investigate the self-assembly of the resulting amphiphilic block copolymers in water and the effect of the chemical structure of the block copolymers on the solution properties of self-assembled nanostructures. The PEG-block-poly(amino acid), PEG-b-PAA, and PMOx-block-poly(amino acid), PMOx-b-PAA, block copolymers have a narrow and monomodal molecular weight distribution (PDI < 1.3). Their self-assembly in water was studied by dynamic light scattering and fluorescence spectroscopy. In aqueous solution, the block copolymers associate into particles with hydrodynamic radii (R(H)) ranging in size from R(H) 70 to 130 nm, depending on the block copolymer architecture and the polymer molecular weight. Larger R(H) and critical association concentration values were obtained for copolymers containing poly(S-benzyloxycarbonyl-l-cysteine) compared to their poly(γ-benzyl-L-glutamate) analogue. FTIR investigations revealed that the poly(γ-benzyl-L-glutamate) block adopts a helical conformation, while the poly(S-benzyloxycarbonyl-L-cysteine) block exists as β-sheet.     

Antibacterial hydrogels of amino acid-based cationic amphiphiles

Development of biomaterials, which are inherently antibacterial having broad-spectrum activity against both Gram-positive and Gram-negative bacteria with considerable biocompatibility, is of tremendous importance in biomedicinal chemistry. Microbial infections are still of great concern, often originated from indwelling medical devices typically in hospitalized patients. To this end, hydrogelating soft materials particularly from low-molecular-weight (LMW) gelators have generated significant interest in preparing and modifying biomedicinal implants. Herein, we have developed L-tryptophan based cationic amphiphilic hydrogelators with varying degree of hydrophobicity that exhibited remarkable bactericidal activity against wide range of Gram-positive (MIC = 0.1-75 microg/mL) and Gram-negative bacteria (MIC = 0.5-5 microg/mL). Antimicrobial efficacy of the amphiphiles was greatly influenced by their alkyl chain length. This bactericidal effect of cationic hydrogelators is quite comparable or in some cases markedly better than that of clinically available antibiotics. Most excitingly, they selectively attack the bacterial pathogens while remain biocompatible to the mammalian cells. Thus, we have developed LMW biocompatible, inherently antibacterial hydrogels having potential applications in biomedicines.     

Molecular imprinting and solid phase extraction of flavonoid compounds

Molecularly imprinted polymers (MIPs) for quercetin have been successfully prepared by a thermal polymerization method using 4-vinylpyridine (4-VP) and ethylene glycol dimethacrylate (EDMA) as functional monomer and cross-linker, respectively. The obtained molecularly imprinted polymers were evaluated by HPLC using organic eluents, with respect to their selective recognition properties for quercetin and related compounds of the flavonoid class. Two equivalent control polymers, a blank polymer and a polymer imprinted with a structural analogous template, were synthesized, in order to confirm the obtained results. Furthermore, preliminary experiments confirm the applicability of the prepared MIPs for solid phase extraction (SPE), as rapid and facile clean-up of wine samples for HPLC analysis is an envisaged field of application. The successful preparation of molecularly imprinted polymers for flavones provides an innovative opportunity for the development of advanced separation materials, with applications in the field of wine and fermentation analysis.     

Graft copolymerization of glycerol 1,3-diglycerolate diacrylate onto poly(3-hydroxyoctanoate) to improve physical properties and biocompatibility

Glycerol 1,3-diglycerol diacrylate-grafted poly(3-hydroxyoctanoate) (GDD-g-PHO) copolymers were prepared by heating homogeneous solutions of PHO, GDD monomer and benzoylperoxide initiator. Experiments showed that GDD was successfully grafted onto the PHO chains and that the resulting copolymers had enhanced thermal properties and mechanical strengths. The surfaces and the bulk of GDD-g-PHO copolymers became more hydrophilic as the GDD grafting density in the copolymer increased. Measurements of the growth of Chinese hamster ovary cells and the adsorption of blood proteins and platelets in vitro showed that biocompatibility was also enhanced by grafting of GDD groups. These results indicate that the GDD-g-PHO copolymers are promising materials for biocompatible biomedical applications.     

Fabricating Superhydrophobic Polymeric Materials for Biomedical Applications

Superhydrophobic materials, with surfaces possessing permanent or metastable non-wetted states, are of interest for a number of biomedical and industrial applications. Here we describe how electrospinning or electrospraying a polymer mixture containing a biodegradable, biocompatible aliphatic polyester (e.g., polycaprolactone and poly(lactide-co-glycolide)), as the major component, doped with a hydrophobic copolymer composed of the polyester and a stearate-modified poly(glycerol carbonate) affords a superhydrophobic biomaterial. The fabrication techniques of electrospinning or electrospraying provide the enhanced surface roughness and porosity on and within the fibers or the particles, respectively. The use of a low surface energy copolymer dopant that blends with the polyester and can be stably electrospun or electrosprayed affords these superhydrophobic materials. Important parameters such as fiber size, copolymer dopant composition and/or concentration, and their effects on wettability are discussed. This combination of polymer chemistry and process engineering affords a versatile approach to develop application-specific materials using scalable techniques, which are likely generalizable to a wider class of polymers for a variety of applications.