Geetha B. Heggannavar scite author profile

Brain glioma is the most lethal type of cancer, with extremely poor prognosis and high relapse. Unfortunately, the treatment of brain glioma is often limited because of the low permeability of anticancer drugs across the blood–brain barrier (BBB). To circumvent this, magnetic mesoporous nanoparticles were synthesized and loaded with doxorubicin as an anticancer agent. These nanoparticles were fabricated with Pluronic F-127 and subsequently conjugated with transferrin (Tf) to achieve the sustained release of the drug at the targeted site. The physicochemical properties of the conjugated nanoparticles were analyzed using different techniques. The magnetic saturation of the nanoparticles determined by a vibration sample magnetometer was found to be 26.10 emu/g. The cytotoxicity study was performed using the MTT assay at 48 and 96 h against the U87 cell line. The Tf-conjugated nanoparticles (DOX-MNP-MSN-PF-127-Tf) exhibited a significant IC50 value (0.570 μg/mL) as compared to the blank nanoparticles (121.98 μg/mL). To understand the transport mechanism of drugs across the BBB, an in vitro BBB model using human brain microvascular endothelial cells was developed. Among the nanoparticles, the Tf-conjugated nanoparticles demonstrated an excellent permeability across the BBB. This effect was predominant in the presence of an external magnetic field, suggesting that magnetic particles present in the matrix facilitated the uptake of drugs in U87 cells. Finally, it is concluded that nanoparticles conjugated with Tf effectively crossed the BBB. Thus, the developed nanocarriers can be considered as potential candidates to treat brain tumor.

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Development of dual drug loaded PLGA based mesoporous silica nanoparticles and their conjugation with Angiopep-2 to treat glioma

Heggannavar

Vijeth

2019

Journal of Drug Delivery Science and Technology

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Protein Nanocarriers for Targeted Drug Delivery for Cancer Therapy

Heggannavar

Amado

Mitchell

2019

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Encapsulating Wall Materials for Micro-/Nanocapsules

Vijeth¹,

Heggannavar²

2019

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Wall materials play a vital role in the development of micro-/nanocapsules to protect the bioactive compounds against external factors. The encapsulation process and the type of polymers exert a direct impact on the development of bioactive micro-/nanocapsules, which greatly reflect in encapsulation efficiency, solubility, stability, surface permeability, and release profile of desired bioactive compounds. Among the polymers, biodegradable polymeric materials have been the focus for various applications in food, pharmaceutical, and cosmetic industries. Thus, this chapter focuses on different encapsulation techniques and the importance of biodegradable polymers employed as wall materials for developing stable and safe micro-/nanocapsules. Among the natural polymers, protein-and polysaccharide-based polymers are widely used. Similarly, the most commonly used synthetic polymers are polycaprolactone, poly(lactic-co-glycolic acid), and polyethylene glycol. Synthetic polymers have been classified based on their exogenous and endogenous responsive natures. At the end, we have also discussed on the applications of biodegradable polymers employed in the development of micro-/ nanocapsules. To compile this chapter and to provide adequate information to the readers, we have explored various sources, such as reviews, research articles, books, and book chapters including Google sites.

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