Polyampholytes
Polyampholytes are polymers that contain both positively charged (cationic) and negatively charged (anionic) functional groups within the same molecule. Their unique structure allows them to exhibit amphoteric behavior, meaning they can interact with a range of substances depending on the surrounding pH, making them useful in applications like drug delivery, water treatment, and biomaterials.[1]
Polyampholytes can exist as either linear water-soluble polyelectrolytes or as cross-linked structures. Weakly cross-linked polyampholytes swell in water, forming hydrogels. The swelling properties of these hydrogels are highly dependent on the solution pH and its relation to the polyampholyte’s isoelectric point.
The isoelectric point of polyampholytes is the pH at which the polymer exhibits no net charge, balancing its positive and negative charges. This point is important because it dictates the net charge of polyampholyte macromolecules at different pH levels. At a pH less than the isoelectric point, the macromolecules carry a positive charge, while at a pH greater than the isoelectric point, they acquire a negative charge. At pH equal to the isoelectric point, polyampholytes are neutral. Under these conditions, they may show minimal viscosity in solutions or lose solubility and precipitate.[2]
Proteins are a class of natural polyampholytes, as they contain both positively and negatively charged amino acid residues within their structure. These charges are influenced by the pH of the surrounding environment, which determines the overall charge of the protein. The presence of both acidic (anionic) and basic (cationic) residues allows proteins to interact with various charged species, making them versatile in biological processes.
Gelatin is a well-known example of a protein-derived polyampholyte. It is derived from collagen, a structural protein found in connective tissues, and contains both acidic (anionic) and basic (cationic) amino acid residues, making it capable of exhibiting amphoteric behavior. The unique combination of these charges allows gelatin to interact with a variety of substances, depending on the pH of the surrounding environment.
Applications
[edit]Synthetic polyampholytes have a wide range of applications due to their unique ability to interact with both cationic and anionic species.[3] In drug delivery, they are used to design advanced systems that can adhere to mucosal surfaces, enhance drug retention, and improve bioavailability by adjusting their charge at specific pH levels.[4] Polyampholytes are also employed in water treatment, where they act as flocculants binding to contaminants and aiding in their removal.[5] In biomaterials, they are utilized in tissue engineering, wound dressings, and as scaffolds for cell growth, taking advantage of their biocompatibility and adjustable charge properties. Furthermore, synthetic polyampholytes serve as cryoprotectants in cryopreservation, stabilizing biological samples like cells and tissues during freezing by preventing ice crystal formation and reducing cellular damage.[6] Additionally, polyampholytes are explored as stealth coatings, creating anti-fouling surfaces that resist biofilm formation and minimize unwanted interactions with biological or environmental surfaces.[7] These applications make polyampholytes highly versatile, with potential in various fields such as sensors, lubricants, and coatings, where their pH-responsive behavior is harnessed for adaptive functionalities.
References
[edit]- ^ "Polyampholytes in Advanced Polymer Science and Emerging Technologies". Routledge & CRC Press. Retrieved 2024-12-14.
- ^ Kudaibergenov, Sarkyt E. (2021). "Synthetic and natural polyampholytes: Structural and behavioral similarity". Polymers for Advanced Technologies. 32 (3): 906–918. doi:10.1002/pat.5145. ISSN 1099-1581.
- ^ Kudaibergenov, Sarkyt E. (2022-01-01). "Application of polyampholytes in emerging technologies". Materials Today: Proceedings. The 1st International Symposium on Emerging Materials and Devices. 71: 31–37. doi:10.1016/j.matpr.2022.07.187. ISSN 2214-7853.
- ^ Fu, Manfei; Filippov, Sergey K.; Williams, Adrian C.; Khutoryanskiy, Vitaliy V. (2024-04-01). "On the mucoadhesive properties of synthetic and natural polyampholytes". Journal of Colloid and Interface Science. 659: 849–858. Bibcode:2024JCIS..659..849F. doi:10.1016/j.jcis.2023.12.176. ISSN 0021-9797. PMID 38218088.
- ^ Morrissey, Kathryn L.; Keirn, Max I.; Inaba, Yuta; Denham, Annika J.; Henry, Graham J.; Vogler, Brian W.; Posewitz, Matthew C.; Stoykovich, Mark P. (2015-09-01). "Recyclable polyampholyte flocculants for the cost-effective dewatering of microalgae and cyanobacteria". Algal Research. 11: 304–312. Bibcode:2015AlgRe..11..304M. doi:10.1016/j.algal.2015.07.009. ISSN 2211-9264.
- ^ Stubbs, Christopher; Bailey, Trisha L.; Murray, Kathryn; Gibson, Matthew I. (2020-01-13). "Polyampholytes as Emerging Macromolecular Cryoprotectants". Biomacromolecules. 21 (1): 7–17. doi:10.1021/acs.biomac.9b01053. ISSN 1525-7797. PMC 6960013. PMID 31418266.
- ^ Zhang, Wei; Yang, Zhe; Kaufman, Yair; Bernstein, Roy (2018-05-01). "Surface and anti-fouling properties of a polyampholyte hydrogel grafted onto a polyethersulfone membrane". Journal of Colloid and Interface Science. 517: 155–165. Bibcode:2018JCIS..517..155Z. doi:10.1016/j.jcis.2018.01.106. ISSN 0021-9797. PMID 29421675.