Browsing by Author "Rekha, CR"

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    Bifunctional cysteine gold nanocluster for β-amyloid fibril inhibition and fluorescence imaging: A distinctive approach to manage Alzheimer's disease
    (Journal of Materials Chemistry B, 2023-04) Resmi, AN; Rekha, CR; Dhushyandhun, ME; Sarathkumar, E; Shenoy, SJ; Gulia, KK; Jayasree, RS
    Alzheimer's disease (AD) is a progressive complex neurodegenerative disorder affecting millions of individuals worldwide. Currently, there is no effective treatment for AD. AD is characterized by the deposition of amyloid plaques/fibrils. One major strategy for managing this disease is by slowing the progression of AD using different drugs which could potentially limit free-radical formation, oxidative stress and lipid peroxidation and promote the survival of neurons exposed to β-amyloid. Inhibition of amyloid fibrillization and clearance of amyloid plaques/fibrils are essential for the prevention and treatment of AD. The thiophilic interaction between the side chain of an aromatic residue in a polypeptide and a sulphur atom of the compound can effectively inhibit amyloid fibril formation. In this work, we have synthesized cysteine-capped gold nanoclusters (Cy-AuNCs) which exhibit inherent red emission and can disintegrate amyloid fibrils through the aforementioned thiophilic interactions. Herein, we also used molecular docking to study the thiophilic interactions between the sulphur atom of Cy-AuNCs and the aromatic rings of the protein. Finally, the gold cluster was functionalized with a brain targeting molecule, Levodopa (AuCs-LD), to specifically target the brain and to facilitate passage through the blood brain barrier (BBB). Both Cy-AuNCs and AuCs-LD showed good biocompatibility and the inherent fluorescence properties of nanoclusters enabled real time imaging. The efficacy of the nanoclusters to disintegrate amyloid fibrils and their ability to cross the BBB were demonstrated both in vitro and in vivo in the BBB model and the AD animal model respectively. Our results imply that nanoparticle-based artificial molecular chaperones may offer a promising therapeutic approach for AD.
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    Luminescent Gold Nanorod to enhance the NIR emission of Photosensitizer for Targeted Cancer Imaging and Dual therapy: Experimental and Theoretical Approach.
    (Chemistry:A European Journal., 2019-11) Nair, RV; Nair, LV; Govindachar, DM; Santhakumar, H; Nazeer, SS; Rekha, CR; Shenoy, SJ; Periyasamy, G; Jayasree, RS
    The strong plasmon absorption in the near‐infrared (NIR) region render gold nano rods (GNR) amenable for biomedical applications, particularly for photo‐thermal therapy. However, these nanostructures have not been explored for their imaging potential because of their weak emission profile. In this study, the weak fluorescence emission of GNR is tuned to match with the absorption of a photosensitizer molecule (PS), and the energy transfer from GNR to PS enhances emission profile of GNR‐PS combination. GNR complexes generally quench the fluorescence emission of nearby chromophores. However, in the present study, through a competition of energy transfer, the complex retains or rather enhances the fluorescence. The excitation dependent energy transfer has been explained experimentally and theoretically using DFT calculations and CIE chromaticity diagram and power spectrum. The final GNR‐PS complex modified for tumor specificity serves as an excellent organ specific theranostic probe for bioimaging and dual modal therapy, both in vitro and in vivo. Principal component analysis designates photodynamic therapy as a better candidate than the photothermal therapy for long term efficacy, in vivo.