Polymers with the ability to kill or inhibit the growth of microorganisms such as bacteria, fungi, or viruses are classified as antimicrobial agents. [1] [2] This class of polymers consists of natural polymers with inherent antimicrobial activity and polymers modified to exhibit antimicrobial activity. [1] Polymers are generally nonvolatile, chemically stable, and can be chemically and physically modified to display desired characteristics and antimicrobial activity. [2] Antimicrobial polymers are a prime candidate for use in the food industry to prevent bacterial contamination and in water sanitation to inhibit the growth of microorganisms in drinking water. [2]
Antimicrobial polymers inhibit cell growth and initiate cell death through two primary mechanisms. [3] The first mechanism is utilized by contact-active polymers. [3] Contact-active polymers utilize electrostatic interactions, the hydrophobic effect, and the chelate effect. Electrostatic attraction is a common initial interaction of an antimicrobial polymer with a microbe. [1] The chelating and hydrophobic effects are common secondary interactions of antimicrobial polymers with microbes. [1]
Cationically charged antimicrobial polymers are attracted to the anionically charged bacterial cell walls. [4] The outer wall of bacterial cells possesses a net negative charge. [5] The cytoplasmic membrane of bacterial cells has a negative charge and contains essential proteins. [5] The secondary interaction, the chelating effect, involves the bonding of the antimicrobial polymer to the microbial cell. These interactions lead to membrane disruption and ultimately inhibited cell growth or death. [5]
The cytoplasmic membrane of a cell is a semi-permeable membrane, which controls the transport of solutes into the cell. [5] The phospholipid bilayer is an important component of the cell membrane, which is composed of hydrophilic heads and a hydrophobic tail. [6] The hydrophilic heads form the inner and outer linings of the cell membrane, while the hydrophobic tails compose the interior of the membrane. [6] The secondary interaction, the hydrophobic effect, involves the accumulation of nonpolar compounds away from water. [7] Nonpolar components of antimicrobial polymers insert themselves into the nonpolar interior of the cell membrane.
High molecular weight polymers commonly induce cell death or inhibition through contact-active interactions with the surface of cells. [1] Cell death and inhibition result from impairment of normal cellular function. Positive residues on the polymer electrostatically interact with negative charges on the cell and induce secondary cellular effects. [1] Cellular membrane penetration is common in low molecular weight polymers. [1] The initial electrostatic and hydrophobic interaction of an antimicrobial polymer and biomimetic polymer causes membrane disruption and cell death. [8] The hydrophobic tail of the polymer penetrates the phospholipid bilayer into the hydrophobic region, resulting in membrane disruption and denaturing of proteins and enzymes, as well as other secondary effects. [1] [4] Secondary effects include disruption of solute and electron transport as well as disturbances to energy production pathways, which leads to cell death. [1] [9]
The second mechanism is characterized by the release of low molecular weight antimicrobial agents from polymers. [3] [1] Antimicrobial agents that are released from polymers induce cell death through binding to or penetrating the cell wall. When antimicrobial agents bind to proteins, structural changes occur to the cell membrane resulting in cellular death. [1] The penetration of nanoparticle antimicrobial agents into the cell wall enables the antimicrobial agents to interact with cell DNA. Microbe death results from the effects to DNA transcription and mRNA synthesis when polymer nanoparticles combine with DNA. [1]
There are different primary characteristics of antimicrobial polymers, dependent upon the mechanism of action. The two primary characteristics of contact-active antimicrobial polymers are cationic charge and hydrophobicity. Cationic residues are necessary to induce the interaction with the microbial cell wall. Polycations such as quaternary ammonium, quaternary phosphonium, and guanidinium are frequently found in antimicrobial polymers. [9] Hydrophobic residues improve binding to the lipid bilayer and are utilized for insertion into the microbial cell wall. [11] Non-contact-active antimicrobial polymers require the addition of antimicrobial agents to induce activity. Common agents added include N-halamine compounds, nitric oxide, and copper and silver nanoparticles. [3] [1]
Antimicrobial polymers are generally classified into two categories based on how antimicrobial activity is conferred. [1] The first are polymers with inherent antimicrobial which do not require any modifications to incite antimicrobial behavior. The other class requires modification to enable antimicrobial activity and can be differentiated by the type of modification. Polymers may be chemically modified to induce antimicrobial behavior or they may be used as a backbone for the addition of organic or inorganic compounds. [1]
Polymers with inherent antimicrobial activity include chitosan, poly-ε-lysine, quaternary ammonium compounds, polyethylenimine, and polyguanidines. [1] Chitosan is a nontoxic polymer that has displayed broad-spectrum antimicrobial activity. [12] [1] The mechanism of action for chitosan includes electrostatic interaction, the chelate effect, and the hydrophobic effect. Electrostatic interaction is the primary initial interaction when the pH is lower, while the chelating and hydrophobic effects are the primary initial interactions when the pH is higher. Growth inhibition and death of fungi, bacteria, and yeasts have been seen from chitosan. The antimicrobial effect of chitosan is greater on fungi than yeasts and more effective on gram-negative bacteria than gram-positive bacteria. [1]
Poly-ε-lysine is a biodegradable, nontoxic, edible antimicrobial polymer. [1] This polymer utilizes electrostatic interactions to attach to the cell wall, therefore disrupting the integrity of the cell wall. [13] Poly-ε-lysine penetrates the cell wall, causing physiological damage to the cell and death. [13] In comparison to a similar synthetic polymer, poly-ε-lysine is more effective against gram-positive than gram-negative bacteria. [1] Poly-ε-lysine is also effective against Bacillus coagulans, Bacillus stearothermophilus, and Bacillus subtilis. [1]
Benzalkonium chloride, stearalkonium chloride, and cetrimonium are all quaternary ammonium compounds containing nitrogen. [1] The antibacterial activity of these compounds is affected by the number of carbon atoms and the length of the nitrogen-containing chain. [1] Optimal antimicrobial activity is generally seen in quaternary ammonium compounds with a long chain length, containing 8-18 carbon atoms. [14] Increased activity is seen against gram-positive bacteria in polymers with a chain length of 12-14 carbon atoms, while improved activity against gram-negative bacteria is seen in polymers with a chain length of 14-16 carbon atoms. [14] Polymer quaternary ammonium compounds containing nitrogen induce cell death through electrostatic interactions and the hydrophobic effect. [1] This group of polymers displays limited hemolytic activity, making them advantageous for use in cosmetics and healthcare.
Polyethylenimine is a synthetic, nonbiodegradable polymer containing nitrogen. [1] This polymer induces cell death through cell membrane rupture. When attached to immobilized surfaces including glass and plastic, N-alkyl-polyethylenimine caused cell inactivation in almost 100% of airborne and waterborne bacteria and fungi. [15] A benefit of this polymer is that it is nontoxic to mammalian cells. [1] Polyethylenimine has been applied in the medical industry for use in prostheses. Bacteria growth was reduced by 92% when polyethylenimine was tested as a coating surface for medical devices. [1] The activity of polyethylenimine is affected by the molecular weight of the polymer; low molecular weight polyethylenimine displays negligible activity, while displaying great antimicrobial activity in its high molecular weight form. [16]
Polyguanidines are another class of antimicrobial polymers containing nitrogen. [1] This class of antimicrobial polymers is nontoxic and exhibits high water solubility. Polyguanidines display broad-spectrum antimicrobial activity and initially interact with microbes using electrostatic forces. Greater activity against gram-positive bacteria has been seen with polyguanidines than against gram-negative bacteria. The reason for the difference in activity is likened to the different structures of gram-positive and gram-negative bacteria. [1] Gram-negative bacteria have a thinner peptidoglycan layer than gram-positive bacteria. [17] In addition, gram-negative bacteria have an outer lipid membrane, which gram-positive bacteria do not. [17] High molecular weight polymers are able to penetrate gram-positive bacteria. [1]
This class of polymers does not have any inherent antimicrobial activity. [1] To induce antimicrobial activity, polymers re chemically modified to include active agents. Active side groups are attached to the polymer backbone to generate antimicrobial activity. Pendent groups, antibiotic drugs, or inorganic particles can be adjoined to the polymer. [1]
Pendant groups that are attached to the polymer backbone include quaternary ammonium, hydroxyl groups with an organic acid, and others. [1] Antimicrobial polymers containing quaternary ammonium as a side group are commonly synthesized from methacrylic monomers. [1] The benefit of these monomers is that the hydrophobicity, molecular weight, and surface charge can all be manipulated. [18] Hydrophobicity of the polymer has a strong effect on antimicrobial activity. [18] Polysiloxanes, which have a quaternary ammonium pendant group, have demonstrated activity against several strains of bacteria including Enterococcus hirae, E. coli, and P. aeruginosa. [1] The flexibility and amphiphilic nature of this polymer enhances the antimicrobial activity. When benzaldehyde, a hydroxyl group containing organic acid, is used as a side group with Methyl methacrylate polymers, growth inhibition five times that of control surfaces has been shown. [1] Benzaldehyde has inherent antimicrobial activity and has been incorporated into polymers to improve activity. [19] Polymers with quaternary ammonium or hydroxyl groups with an organic acid as a pendant group have demonstrated activity against many types of bacteria, fungi, and algae. [1]
Antimicrobial activity can also be induced through the addition of inorganic particles such as silver, copper, and titanium dioxide nanoparticles to a polymer. [1] Metal nanoparticles are incorporated into the polymer to form polymeric nanocomposites. Silver is utilized in antimicrobial polymers because of its stability as well as broad-spectrum antimicrobial activity. [3] Positive silver ions are produced in environments beneficial for the growth of bacteria. [1] These positive silver ions physically interact with cell wall proteins resulting in membrane disruption and cell death. [1] Silver nanoparticles embedded into a cationic polymer have displayed activity against E.coli and S.aureus. [3] Copper and titanium dioxide nanoparticles are less commonly employed in antimicrobial polymers than silver nanoparticles. [1] Copper nanoparticles embedded into polypropylene nanocomposites have demonstrated the ability to kill 99.9% of bacteria. [1] Titanium dioxide is a nontoxic material with antimicrobial activity that is photo-activated. [3] Titanium dioxide has been embedded in polypropylene to create photoactive antimicrobial polymers. [1] The antimicrobial activity of the polymer composite is initiated by a light source. The light source causes the titanium dioxide to be oxidized, which results in the release of highly reactive hydroxyl species that disrupt bacteria. [20] [21] The effectiveness of the photoactive antimicrobial polymer has been demonstrated against the bacteria E.coli. [20]
Another class of antibacterial polymers includes those whose activity is introduced through the incorporation of antibiotics into the polymer matrix. [1] The chemical triclosan is commonly utilized for its antibacterial properties. Triclosan mixed with the copolymer styrene-acrylate exhibits antibacterial activity against E. faecalis. In addition, triclosan combined with the polymer polyvinyl alcohol has increased antibacterial activity compared to triclosan not incorporated in a polymer. The polymer polyethylenimine has also been modified to include antibiotics. [22] Polyethylenimine is used to make bacterial cell walls more permeable, therefore increasing the sensitivity of bacteria to antibiotics. [22] Polyethylenimine increases the effectiveness of the antibiotics including ampicillin, rifampin, cefotaxime, as well as others. [1]
Magainin and defensin are natural peptides, short polymers composed of amino acids, which display exceptional antimicrobial activity. [23] The antimicrobial activity is a product of the peptides’ structure, including its highly rigid backbone. [1] These peptides have organized pendant groups, making one side of the polymer hydrophobic and the other side cationic. [23] This group of polymers efficiently induce cell death through cell wall penetration. [1] Polymer mimics of these antimicrobial peptides have been developed. Protein-mimicking polymers emulate the structure of magainin and defensin. Examples of protein mimicking polymers include poly(phenylene ethynylene)-based and N-carboxyanhydride-based polymers. Poly(phenylene ethynylene) polymers with amino acid pendant groups were manufactured to have positively charged side groups and a stiff backbone. The synthetic polymer had low toxicity and strong antimicrobial activity. In addition, N-carboxyanhydride-based polymers with the hydrophilic amino acid lysine and different hydrophobic amino acids were developed. The polymers displayed antimicrobial activity against E. coli, C. Albicans, and others. [1]
The molecular weight of the polymer is perhaps one of the most important properties to consider when determining antimicrobial properties because antimicrobial activity is markedly dependent on the molecular weight. It has been determined that optimal activity is achieved when polymers have a molecular weight in the range of 1.4x104 Da to 9.4x104 Da. Weights larger than this range show a decrease in activity. This dependence on weight can be attributed to the sequence of steps necessary for biocidal action. Extremely large molecular weight polymers will have trouble diffusing through the bacterial cell wall and cytoplasm. Thus much effort has been directed towards controlling the molecular weight of the polymer. [24]
Most bacterial cell walls are negatively charged, therefore most antimicrobial polymers must be positively charged to facilitate the adsorption process. The structure of the counter ion, or the ion associated with the polymer to balance charge, also affects the antimicrobial activity. Counter anions that form a strong ion-pair with the polymer impede the antimicrobial activity because the counter ion will prevent the polymer from interacting with the bacteria. However, ions that form a loose ion-pair or readily dissociate from the polymer, exhibit a positive influence on the activity because it allows the polymer to interact freely with the bacteria. [25] [26]
The spacer length or alkyl chain length refers to the length of the carbon chain that composes the polymer backbone. The length of this chain has been investigated to see if it affects the antimicrobial activity of the polymer. Results have generally shown that longer alkyl chains have resulted in higher activity. There are two primary explanations for this effect. Firstly, longer chains have more active sites available for adsorption with the bacteria cell wall and cytoplasmic membrane. Secondly, longer chains aggregate differently than shorter chains, which again may provide a better means for adsorption. However, shorter chain lengths diffuse more easily. [25] [26]
A major disadvantage of antimicrobial polymers is that macromolecules are very large and thus may not act as fast as small molecule agents. Biocidal polymers that require contact times on the order of hours to provide substantial reductions in pathogens, really have no practical value. Seconds, or minutes at most, should be the contact time goal for a real application. Furthermore, if the structural modification to the polymer caused by biocidal functionalization adversely affects the intended use, the polymer will be of no practical value. For example, if a fiber that must be exposed to aqueous bleach to render it antimicrobial (an N-halamine polymer) is weakened by that exposure, or its dye is bleached, it will have limited use. [2]
This synthetic method involves covalently linking antimicrobial agents that contain functional groups with high antimicrobial activity, such as hydroxyl, carboxyl, or amino groups to a variety of polymerizable derivatives, or monomers before polymerization. The antimicrobial activity of the active agent may be either reduced or enhanced by polymerization. This depends on how the agent kills bacteria, either by depleting the bacterial food supply or through bacterial membrane disruption and the kind of monomer used. Differences have been reported when homo-polymers are compared to copolymers. [2] Examples of antimicrobial polymers synthesized from antimicrobial monomers are included in Table 2:
Table 2: Polymers Synthesized from Antimicrobial Monomers and their Antimicrobial Properties
Monomer | Inhibited Microbial Species | Antimicrobial Mechanism | Comparison of Polymers with Monomer |
---|---|---|---|
Fungus : C. albicans; A. niger | Slow release of 4-amino-N-(5-methyl-3-isoxazoly)benzenesulfonamide | The homopolymer is more effective than the monomer at all concentrations. [27] | |
Bacteria :Gram-positive; Gram-negative | Tin moiety on the polymer surface interacts with the cell wall. | Copolymerization of antimicrobial monomer and styrene decreases the potency of the monomer. [28] | |
Bacteria:S. aureus; P. aeruginosa; E. coli; | The presence of benzimidazole derivatives inhibit cytochrome P-450 monooxygenase | The homopolymer is more effective than the monomer. [29] | |
Bacteria:Gram-positive; Gram-negative | Release of norfloxacin which inhibits bacterial DNA gyrase and cell growth. [30] | ---- | |
Bacteria:Pseudomonas aeruginosa;Staphylococcus | Active agent is 2,4,4’-trichloro-2’-hydroxydiphenyl-ether | The homopolymer and copolymers with methyl methacrylate, styrene are all less effective than the monomer. [31] | |
Bacteria:S. aureus; P. aeruginosa; | Active agent is phenol group. | Polymerization significantly decreases the antimicrobial activity of the monomers. [32] | |
Bacteria:E-coli | Direct transfer of oxidative halogen from polymer to the cell wall of the organism. [33] | ---- | |
Bacteria:E. coli;S. aureus; S. typhimurium | Release of 8-hydroxyquinoline moieties | The homopolymer and the copolymers with acrylamide are both less effective than the monomer. [34] | |
Bacteria:Gram-positive bacteria | Active agent is Sulfonium salt | The homopolymer is more effective than the corresponding model compound (p-ethylbenzyl tetramethylene sulforium tetrafluoroborate). [35] | |
Bacteria: Oral streptococci | Direct cationic binding to cell wall, which leads to the disruption of the cell wall and cell death. [36] | ---- | |
Bacteria: S. aureus; E-coli | Cationic biocides targets the cytoplasmic membranes; Similarities of the polymer pendent groups and the lipid layer enhances diffusion into the cell wall | The monomers are not active, while homopolymers show moderate activities in concentration from 1 mg/mL to 3.9 mg/mL. [37] | |
Bacteria: S. aureus; E. coli | Membrane disruption [38] | ---- | |
Bacteria: Staphylococcus;E. coli | Immobilization of high concentrations of chlorine to enable rapid biocidal activities and the liberation of very low amounts of corrosive free chlorine into water [39] | ---- | |
This synthetic method involves first synthesizing the polymer, followed by modification with an active species. The following kinds of monomers are usually used to form the backbone of homopolymers or copolymers: vinylbenzyl chloride, methyl methacrylate, 2-chloroethyl vinyl ether, vinyl alcohol, maleic anhydride. The polymers are then activated by anchoring antimicrobial species, such as phosphonium salts, ammonium salts, or phenol groups via quaternization, substitution of chloride, or hydrolysis of anhydride. [2] Examples of polymers synthesized from this method are provided in Table 3:
Table 3: Antimicrobial Polymers Synthesized from Preformed Polymers and Antimicrobial Properties
Polymer | Inhibited Microbial Species | Antimicrobial Mechanism |
---|---|---|
Fungus: Candida albicans; Aspergillus flavus; Bacteria: S. aureus; E. coli; B. subtilis; Fusarium oxysporum | Active group: Phosphonium groups. [27] | |
Fungus: Aspergillus fumigatus; Penicillium pinophilum | The release of m- 2-benzimidazolecarbamoyl moiety. [40] | |
Bacteria: E. coli; S. aureus | Active groups: phenolic hydroxyl group. [41] | |
Bacteria: E. coli; S. aureus | Active group: Quaternary ammonium group. [42] | |
Fungus: Trichophyton rubrum; Bacteria: Gram-negative bacteria | Active groups: Phosphonium and quaternary ammonium groups. [43] | |
Chitin is the second-most abundant biopolymer in nature. The deacetylated product of chitin—chitosan has been found to have antimicrobial activity without toxicity to humans. This synthetic technique involves making chitosan derivatives to obtain better antimicrobial activity. Currently, work has involved the introduction of alkyl groups to the amine groups to make quaternized N-alkyl chitosan derivatives, introduction of extra quaternary ammonium grafts to the chitosan, and modification with phenolic hydroxyl moieties. [44]
This method involves using chemical reactions to incorporate antimicrobial agents into the polymeric backbones. Polymers with biologically active groups, such as polyamides, polyesters, and polyurethanes are desirable as they may be hydrolyzed to active drugs and small innocuous molecules. For example, a series of polyketones have been synthesized and studied, which show an inhibitory effect on the growth of B. subtilis and P. fluorescens as well as fungi, A. niger and T. viride. There are also studies which incorporate antibiotics into the backbone of the polymer. [45]
In order for an antimicrobial polymer to be a viable option for large-scale distribution and use there are several basic requirements that must be first fulfilled:
Polymeric disinfectants are ideal for applications in hand-held water filters, surface coatings, and fibrous disinfectants, because they can be fabricated by various techniques and can be made insoluble in water. The design of insoluble contact disinfectants that can inactivate, kill, or remove target microorganisms by mere contact without releasing any reactive agents to the bulk phase being disinfected is desired. Chlorine or water-soluble disinfectants have problems with the residual toxicity, even if minimal amounts of the substance used. [46] Toxic residues can become concentrated in food, water, and in the environment. In addition, because free chlorine ions and other related chemicals can react with organic substances in water to yield trihalomethane analogues that are suspected of being carcinogenic, their use should be avoided. These drawbacks can be solved by the removal of microorganisms from water with insoluble substances. [47] [48]
Antimicrobial substances that are incorporated into packaging materials can control microbial contamination by reducing the growth rate and the maximum growth population. This is done by extending the lagphase of the target microorganism or by inactivating the microorganisms on contact. [49] One of these applications is to extend the shelf life of food and promote safety by reducing the rate of growth of microorganisms when the package is in contact with the surfaces of solid foods, for example, meat, cheese, etc. Second, antimicrobial packaging materials greatly reduce the potential for recontamination of processed products and simplify the treatment of materials to eliminate product contamination. For example, self-sterilizing packaging might eliminate the need for peroxide treatment in aseptic packaging. Antimicrobial polymers can also be used to cover surfaces of food processing equipment as self-sanitizer. Examples include filter gaskets, conveyors, gloves, garments, and other personal hygiene equipment.
Some polymers are inherently antimicrobial and have been used in films and coatings. Cationic polymers such as chitosan promote cell adhesion. [50] This is because charged amines interact with negative charges on the cell membrane, and can cause leakage of intracellular constituents. Chitosan has been used as a coating and appears to protect fresh vegetables and fruits from fungal degradation. Although the antimicrobial effect is attributed to antifungal properties of chitosan, it may be possible that the chitosan acts as a barrier between the nutrients contained in the produce and microorganisms. [51]
Antimicrobial polymers are powerful candidates for controlled delivery systems and implants in dental restorative materials because of their high activities. This can be ascribed to their characteristic nature of carrying a high local charge density of active groups in the vicinity of the polymer chains. For example, electrospun fibers containing tetracycline hydrochloride based on poly(ethylene-co-vinyl acetate), poly(lactic acid), and blending were prepared to use as an antimicrobial wound dressing. [52] [53] Cellulose derivatives are commonly used in cosmetics as skin and hair conditioners. Quaternary ammonium cellulose derivatives are of particular interest as conditioners in hair and skin products.
The field of antimicrobial polymers has progressed steadily, but slowly over the past years, and appears to be on the verge of rapid expansion. This is evidenced by a broad variety of new classes of compounds that have been prepared and studied in the past few years. [54]
Modification of polymers and fibrous surfaces, and changing the porosity, wettability, and other characteristics of the polymeric substrates, should produce implants and biomedical devices with greater resistance to microbial adhesion and biofilm formation. A number of polymers have been developed that can be incorporated into cellulose and other materials, which should provide significant advances in many fields such as food packaging, textiles, wound dressing, coating of catheter tubes, and necessarily sterile surfaces. The greater need for materials that fight infection will give incentive for discovery and use of antimicrobial polymers. [2]
A micelle or micella is an aggregate of surfactant amphipathic lipid molecules dispersed in a liquid, forming a colloidal suspension. A typical micelle in water forms an aggregate with the hydrophilic "head" regions in contact with surrounding solvent, sequestering the hydrophobic single-tail regions in the micelle centre.
Benzalkonium chloride, also known as alkyldimethylbenzylammonium chloride (ADBAC) and by the trade name Zephiran, is a type of cationic surfactant. It is an organic salt classified as a quaternary ammonium compound. ADBACs have three main categories of use: as a biocide, a cationic surfactant, and a phase transfer agent. ADBACs are a mixture of alkylbenzyldimethylammonium chlorides, in which the alkyl group has various even-numbered alkyl chain lengths.
In organic chemistry, quaternary ammonium cations, also known as quats, are positively-charged polyatomic ions of the structure [NR4]+, where R is an alkyl group, an aryl group or organyl group. Unlike the ammonium ion and the primary, secondary, or tertiary ammonium cations, the quaternary ammonium cations are permanently charged, independent of the pH of their solution. Quaternary ammonium salts or quaternary ammonium compounds are salts of quaternary ammonium cations. Polyquats are a variety of engineered polymer forms which provide multiple quat molecules within a larger molecule.
An amphiphile, or amphipath, is a chemical compound possessing both hydrophilic and lipophilic (fat-loving) properties. Such a compound is called amphiphilic or amphipathic. Amphiphilic compounds include surfactants and detergents. The phospholipid amphiphiles are the major structural component of cell membranes.
Thiolated polymers – designated thiomers – are functional polymers used in biotechnology product development with the intention to prolong mucosal drug residence time and to enhance absorption of drugs. The name thiomer was coined by Andreas Bernkop-Schnürch in 2000. Thiomers have thiol bearing side chains. Sulfhydryl ligands of low molecular mass are covalently bound to a polymeric backbone consisting of mainly biodegradable polymers, such as chitosan, hyaluronic acid, cellulose derivatives, pullulan, starch, gelatin, polyacrylates, cyclodextrins, or silicones.
Class II bacteriocins are a class of small peptides that inhibit the growth of various bacteria.
A lipopeptide is a molecule consisting of a lipid connected to a peptide. They are able to self-assemble into different structures. Many bacteria produce these molecules as a part of their metabolism, especially those of the genus Bacillus, Pseudomonas and Streptomyces. Certain lipopeptides are used as antibiotics. Due to the structural and molecular properties such as the fatty acid chain, it poses the effect of weakening the cell function or destroying the cell. Other lipopeptides are toll-like receptor agonists. Certain lipopeptides can have strong antifungal and hemolytic activities. It has been demonstrated that their activity is generally linked to interactions with the plasma membrane, and sterol components of the plasma membrane could play a major role in this interaction. It is a general trend that adding a lipid group of a certain length to a lipopeptide will increase its bactericidal activity. Lipopeptides with a higher amount of carbon atoms, for example 14 or 16, in its lipid tail will typically have antibacterial activity as well as anti-fungal activity. Therefore, an increase in the alkyl chain can make lipopeptides soluble in water. As well, it opens the cell membrane of the bacteria, so antimicrobial activity can take place.
Poly(acrylic acid) (PAA; trade name Carbomer) is a polymer with the formula (CH2-CHCO2H)n. It is a derivative of acrylic acid (CH2=CHCO2H). In addition to the homopolymers, a variety of copolymers and crosslinked polymers, and partially deprotonated derivatives thereof are known and of commercial value. In a water solution at neutral pH, PAA is an anionic polymer, i.e., many of the side chains of PAA lose their protons and acquire a negative charge. Partially or wholly deprotonated PAAs are polyelectrolytes, with the ability to absorb and retain water and swell to many times their original volume. These properties – acid-base and water-attracting – are the bases of many applications.
Poly(N-isopropylacrylamide) (variously abbreviated PNIPA, PNIPAM, PNIPAAm, NIPA, PNIPAA or PNIPAm) is a temperature-responsive polymer that was first synthesized in the 1950s. It can be synthesized from N-isopropylacrylamide which is commercially available. It is synthesized via free-radical polymerization and is readily functionalized making it useful in a variety of applications.
Polylysine refers to several types of lysine homopolymers, which may differ from each other in terms of stereochemistry and link position (α/ε). Of these types, only ε-poly-L-lysine is produced naturally.
Polyethylenimine (PEI) or polyaziridine is a polymer with repeating units composed of the amine group and two carbon aliphatic CH2CH2 spacers. Linear polyethyleneimines contain all secondary amines, in contrast to branched PEIs which contain primary, secondary and tertiary amino groups. Totally branched, dendrimeric forms were also reported. PEI is produced on an industrial scale and finds many applications usually derived from its polycationic character.
A nanogel is a polymer-based, crosslinked hydrogel particle on the sub-micron scale. These complex networks of polymers present a unique opportunity in the field of drug delivery at the intersection of nanoparticles and hydrogel synthesis. Nanogels can be natural, synthetic, or a combination of the two and have a high degree of tunability in terms of their size, shape, surface functionalization, and degradation mechanisms. Given these inherent characteristics in addition to their biocompatibility and capacity to encapsulate small drugs and molecules, nanogels are a promising strategy to treat disease and dysfunction by serving as delivery vehicles capable of navigating across challenging physiological barriers within the body.
2-Acrylamido-2-methylpropane sulfonic acid (AMPS) was a Trademark name by The Lubrizol Corporation. It is a reactive, hydrophilic, sulfonic acid acrylic monomer used to alter the chemical properties of wide variety of anionic polymers. In the 1970s, the earliest patents using this monomer were filed for acrylic fiber manufacturing. Today, there are over several thousands patents and publications involving use of AMPS in many areas including water treatment, oil field, construction chemicals, hydrogels for medical applications, personal care products, emulsion coatings, adhesives, and rheology modifiers. Lubrizol discontinued the production of this monomer in 2017 due to copy-cat production from China and India destroying the profitability of this product.
An antimicrobial surface is coated by an antimicrobial agent that inhibits the ability of microorganisms to grow on the surface of a material. Such surfaces are becoming more widely investigated for possible use in various settings including clinics, industry, and even the home. The most common and most important use of antimicrobial coatings has been in the healthcare setting for sterilization of medical devices to prevent hospital associated infections, which have accounted for almost 100,000 deaths in the United States. In addition to medical devices, linens and clothing can provide a suitable environment for many bacteria, fungi, and viruses to grow when in contact with the human body which allows for the transmission of infectious disease.
In polymer chemistry, graft polymers are segmented copolymers with a linear backbone of one composite and randomly distributed branches of another composite. The picture labeled "graft polymer" shows how grafted chains of species B are covalently bonded to polymer species A. Although the side chains are structurally distinct from the main chain, the individual grafted chains may be homopolymers or copolymers. Graft polymers have been synthesized for many decades and are especially used as impact resistant materials, thermoplastic elastomers, compatibilizers, or emulsifiers for the preparation of stable blends or alloys. One of the better-known examples of a graft polymer is a component used in high impact polystyrene, consisting of a polystyrene backbone with polybutadiene grafted chains.
2-Ethyl-2-oxazoline (EtOx) is an oxazoline which is used particularly as a monomer for the cationic ring-opening polymerization to poly(2-alkyloxazoline)s. This type of polymers are under investigation as readily water-soluble and biocompatible materials for biomedical applications.
Hydrogels are three-dimensional networks consisting of chemically or physically cross-linked hydrophilic polymers. The insoluble hydrophilic structures absorb polar wound exudates and allow oxygen diffusion at the wound bed to accelerate healing. Hydrogel dressings can be designed to prevent bacterial infection, retain moisture, promote optimum adhesion to tissues, and satisfy the basic requirements of biocompatibility. Hydrogel dressings can also be designed to respond to changes in the microenvironment at the wound bed. Hydrogel dressings should promote an appropriate microenvironment for angiogenesis, recruitment of fibroblasts, and cellular proliferation.
1-Vinylimidazole is a water-soluble basic monomer that forms quaternizable homopolymers by free-radical polymerization with a variety of vinyl and acrylic monomers. The products are functional copolymers, which are used as oil field chemicals and as cosmetic auxiliaries. 1-Vinylimidazole acts as a reactive diluent in UV lacquers, inks, and adhesives.
Chelated platinum is an ionized form of platinum that forms two or more bonds with a counter ion. Some platinum chelates are claimed to have antimicrobial activity.
Chitosan-poly is a composite that has been increasingly used to create chitosan-poly(acrylic acid) nanoparticles. More recently, various composite forms have come out with poly(acrylic acid) being synthesized with chitosan which is often used in a variety of drug delivery processes. Chitosan which already features strong biodegradability and biocompatibility nature can be merged with polyacrylic acid to create hybrid nanoparticles that allow for greater adhesion qualities as well as promote the biocompatibility and homeostasis nature of chitosan poly(acrylic acid) complex. The synthesis of this material is essential in various applications and can allow for the creation of nanoparticles to facilitate a variety of dispersal and release behaviors and its ability to encapsulate a multitude of various drugs and particles.