Kasturi A. Rokade scite author profile

An array of microneedles (MNs) of chitosan‐graphene assembled in porous carbon (CS‐GAPC) nanocomposites has been synthesized and evaluated. The safety of the formulated system has been ensured using detailed in vivo toxicological studies and efficacy has been ensured by evaluating the stimuli (pH and electric field) initiated drug delivery properties. Drug cephalexin has been incorporated in these MNs. In vivo toxicological studies of CS‐GAPC nanocomposite were performed on Sprague rats, using acute dermal and subacute dermal (ADT& SADT) test, histopathological studies, biochemical studies, and AMES tests. ADT and SADT studies showed that median lethal dose (LD50) was found greater than 2000 mg/kg body weight; with no abnormal weight gain and food consumption, during the study period of 28 days. This study showed that administration of CS‐GAPC did not cause any substantial alterations in hematological and biochemical parameters of the animals. Histopathological studies showed no significant changes in the control and CS‐GAPC administered groups. AMES tests reveal that CS‐GAPC nanocomposite is nonmutagenic against the Salmonella thyphimurium strains. No abnormalities were observed in the animal's chromosomal aberrations and clastogenic values when the animals were treated with CS‐GAPC. At acidic pH of 4, the encapsulated drug was completely released, indicating that the drug release from the prepared nanocomposite is pH dependent. An electric field of 5 V showed optimum drug release, as a function of applied electric pulses. A biologically safe drug encapsulation model system is hence projected for smart drug delivery (pH dependent and electric field triggered) using the microneedle approach. © 2019 Wiley Periodicals, Inc. J Biomed Mater Res Part A: 107A: 1582–1596, 2019.

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PEEK/SiO2 composites with high thermal stability for electronic applications

Goyal¹,

Rokade²,

Kapadia³

et al. 2013

Electron. Mater. Lett.

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Review of Electrochemically Synthesized Resistive Switching Devices: Memory Storage, Neuromorphic Computing, and Sensing Applications

et al. 2023

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Resistive-switching-based memory devices meet most of the requirements for use in next-generation information and communication technology applications, including standalone memory devices, neuromorphic hardware, and embedded sensing devices with on-chip storage, due to their low cost, excellent memory retention, compatibility with 3D integration, in-memory computing capabilities, and ease of fabrication. Electrochemical synthesis is the most widespread technique for the fabrication of state-of-the-art memory devices. The present review article summarizes the electrochemical approaches that have been proposed for the fabrication of switching, memristor, and memristive devices for memory storage, neuromorphic computing, and sensing applications, highlighting their various advantages and performance metrics. We also present the challenges and future research directions for this field in the concluding section.

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Study on novel high performance polymer nanocomposites for electronics packaging paper

Goyal¹,

Rokade²,

Kapadia³

2011

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Kasturi A. Rokade

Silica-chitosan nanocomposite mediated pH-sensitive drug delivery

Recent progress in energy, environment, and electronic applications of MXene nanomaterials

Microneedles of chitosan‐porous carbon nanocomposites: Stimuli (pH and electric field)‐initiated drug delivery and toxicological studies

PEEK/SiO2 composites with high thermal stability for electronic applications

Review of Electrochemically Synthesized Resistive Switching Devices: Memory Storage, Neuromorphic Computing, and Sensing Applications

Study on novel high performance polymer nanocomposites for electronics packaging paper

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