Iota carrageenan linked barium ion nanoparticle synthesis for the selective targeted imaging and inhibition of cancer cells
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Aman Shukla
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Shashank Kailkhura
Abstract
The development of stable carrageenan nanoparticles connected to the sulfate functional group of carrageenan and barium ion for the use of selectively targeting cancer cell and imaging contrast to help with diagnosis (tracing/imaging) is the concern of the present research. This study provides an overview of ion substitution chemistry, highlighting the role of ions and how they affect the applicability of carrageenan. The characteristic of barium sulfate, which is widely used as radiopaque to provide contrast for diagnostic radiographic examinations in the gastrointestinal mucosa, is provided by its linkage with the barium ion despite K+’s natural binding with carrageenan. The additional role of the Ba ion linked carrageenan was found highly selective for cancer cell through the in vitro cell line assay; however, the nonattachability to the normal cell makes useful to trace and treat the cancer cell. The tracing is possible because of the barium sulfate functional group and its nanosize molecule, which shows precision medicine, fluorescence, and X-ray/CT imaging character, to be utilized as the diagnostic purpose, especially to tumor cell. The apoptosis from the Ba2+ ion by the inhibition of outflux of K+ to disturb the osmosis of cell and selectivity of the molecules because of high pKa (Logarithms of acid dissociation constant) value, which makes the drug more active anionic (nonpolar) form in the cancer cell and ionic form (polar) in the normal cell, which avoids the interaction with normal cell and facilitate the interaction with cancer cell. In conclusion, the cancer cell selectivity with fluorescence and radiopaque properties of Ba ion linked carrageenan makes the molecule useful for tracing, imaging, and treating cancer cell with high selectivity.
Acknowledgments
All authors thank the Deanship of Higher Education and Scientific Research at Taif University for supporting the in-vitro cell line assay. For Figure 8: credit pic of bulb from “image: Freepik.com”.
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Research ethics: Not applicable.
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Author contributions: Aman Shukla and Sachin Kumar: performed replacement of ion based reaction and product characterzation; Akanksha Bhatt and Shashank Kailkhura: nanoparticle formation and characterization; Priyank Purohit: finalization of draft; Magda H. Abdellattif: performed cancer and healthy in vitro cell line assay. The authors have accepted responsibility for the entire content of this manuscript and approved its submission.
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Competing interests: The authors states no conflict of interest.
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Research funding: All authors express their gratitude to Graphic Era Hill University for providing the initial funding to start the project work.
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Data availability: Not applicable.
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© 2024 Walter de Gruyter GmbH, Berlin/Boston
Artikel in diesem Heft
- Frontmatter
- Material Properties
- Biodegradability and mechanical behavior of novel hybrid green composites fabricated with cashew shell particle, sisal fiber and corn starch resin
- Preparation and Assembly
- Preparation and properties of vancomycin-loaded PLA-PEG-PLA microspheres by electrostatic spray technology
- Iota carrageenan linked barium ion nanoparticle synthesis for the selective targeted imaging and inhibition of cancer cells
- Self-healing superoleophobic and superhydrophilic fabrics for efficient oil/water separation
- Engineering and Processing
- Enhanced Pb2+ adsorption using recyclable magnetic sodium alginate in a network structure for high renewable capacity
Artikel in diesem Heft
- Frontmatter
- Material Properties
- Biodegradability and mechanical behavior of novel hybrid green composites fabricated with cashew shell particle, sisal fiber and corn starch resin
- Preparation and Assembly
- Preparation and properties of vancomycin-loaded PLA-PEG-PLA microspheres by electrostatic spray technology
- Iota carrageenan linked barium ion nanoparticle synthesis for the selective targeted imaging and inhibition of cancer cells
- Self-healing superoleophobic and superhydrophilic fabrics for efficient oil/water separation
- Engineering and Processing
- Enhanced Pb2+ adsorption using recyclable magnetic sodium alginate in a network structure for high renewable capacity
