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Microcapsules gain a new power: Scavenging reactive oxygen species

These novel, biocompatible, hollow capsules can serve biomedical and industrial uses

Date:
January 30, 2018
Source:
University of Alabama at Birmingham
Summary:
Stable, biocompatible microcapsules have gained a new power -- the ability to scavenge reactive oxygen species. This may aid microcapsule survival in the body as the tiny polymer capsules carry a drug or other biomolecules. The microcapsules may also find use in antioxidant therapy or in industrial applications where scavenging of free radicals is needed.
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Stable, biocompatible microcapsules from the lab of Eugenia Kharlampieva, Ph.D., have gained a new power -- the ability to scavenge reactive oxygen species.

This may aid microcapsule survival in the body as the tiny polymer capsules carry a drug or other biomolecules, says Kharlampieva, associate professor of chemistry in the University of Alabama at Birmingham College of Arts and Sciences. The microcapsules may also find use in antioxidant therapy or in industrial applications where scavenging of free radicals is needed.

Reactive oxygen species play a Janus-like role in the body -- they can be a weapon against pathogens when produced by the immune system; but excess production of reactive oxygen species during biological stress can damage human cells in diseases like diabetes, atherosclerosis, Alzheimer's disease, kidney disease and cancer.

Current natural and synthetic antioxidants lack biocompatibility and bioavailability, and they are chemically unstable. This means they have a limited capability to scavenge reactive oxygen species. The new microcapsules do not show these limitations, and they may provide a way to locally modulate oxidative stress.

Kharlampieva and colleagues describe the construction and properties of these new microcapsules in the paper "Manganoporphyrin-polyphenol multilayer capsules as radical and ROS scavengers," published in Chemistry of Materials, a publication of the American Chemical Society. Graduate student Aaron Alford and research associate Veronika Kozlovskaya, Ph.D., are co-first authors, and Hubert Tse, Ph.D., associate professor of microbiology in the UAB School of Medicine, is co-corresponding author with Kharlampieva.

The UAB researchers have previous experience making and testing biocompatible microcapsules with alternating layers of tannic acid and poly(N-vinylpyrrolidone), or TA/PVPON. The layers are formed around a sacrificial core, such as solid silica, that is dissolved after the layers are complete.

Tannic acid is a natural antioxidant, and the TA/PVPON microcapsules have some reactive oxygen species-scavenging ability. However, they lose that ability and begin to degrade with prolonged exposure to the oxygen radicals.

So, the Kharlampieva team explored adding a metalloporphyrin to the PVPON layer of the TA/PVPON microcapsules.

Specifically, they devised a synthesis to covalently attach a manganoporphyrin to the PVPON. The addition of this pendant catalyst created an MnP-PVPON/TA capsule with the following characteristics: 1) the microcapsules synergistically remove reactive oxygen species, including superoxide and hydrogen peroxide, at dramatically increased rates compared to unmodified TA/PVPON microcapsules; 2) the microcapsule does not degrade with long exposure to reactive oxygen species; and 3) the microcapsules are nontoxic to mouse splenocytes.

Furthermore, the manganoporphyrin was stably contained within the microcapsule without release, and researchers showed that both manganoporphyrin and tannic acid were required for the synergistic scavenging of reactive oxygen species.

The presence of the manganoporphyrin did not interfere with the alternate-layer construction of the microcapsules, and the MnP-PVPON/TA capsules had increased wettability compared to the PVPON/TA capsule, which may aid microcapsule maintenance in the blood. The microcapsules had five or five and a half bilayers placed around a 4-micrometer silica particle.

Biological experiments with the MnP-PVPON/TA capsules are underway.


Story Source:

Materials provided by University of Alabama at Birmingham. Note: Content may be edited for style and length.


Journal Reference:

  1. Aaron Alford, Veronika Kozlovskaya, Bing Xue, Nirzari Gupta, William Higgins, Dana Pham-Hua, Lilin He, Volker S. Urban, Hubert M. Tse, Eugenia Kharlampieva. Manganoporphyrin-Polyphenol Multilayer Capsules as Radical and Reactive Oxygen Species (ROS) Scavengers. Chemistry of Materials, 2018; 30 (2): 344 DOI: 10.1021/acs.chemmater.7b03502

Cite This Page:

University of Alabama at Birmingham. "Microcapsules gain a new power: Scavenging reactive oxygen species." ScienceDaily. ScienceDaily, 30 January 2018. <www.sciencedaily.com/releases/2018/01/180130123719.htm>.
University of Alabama at Birmingham. (2018, January 30). Microcapsules gain a new power: Scavenging reactive oxygen species. ScienceDaily. Retrieved March 19, 2024 from www.sciencedaily.com/releases/2018/01/180130123719.htm
University of Alabama at Birmingham. "Microcapsules gain a new power: Scavenging reactive oxygen species." ScienceDaily. www.sciencedaily.com/releases/2018/01/180130123719.htm (accessed March 19, 2024).

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