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Technical and engineering considerations for designing therapeutics and delivery systems

Journal

JOURNAL OF CONTROLLED RELEASE
Volume 353, Issue -, Pages 411-422

Publisher

ELSEVIER
DOI: 10.1016/j.jconrel.2022.11.056

Keywords

Electron diffraction; Electromechanical devices; Mechatronics; Optomechatronics; Drug delivery

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The emerging pathological conditions and growing drug resistance call for the application of advanced technologies to discover therapeutic candidates and gain comprehensive understanding about their targets, action mechanisms, and interactions within the body. Physics- and chemistry-based techniques can be used for theranostic purposes, including preparing smart carriers, local drug or gene delivery, and enhancing pharmaceutical bioavailability. Crystal engineering and other techniques such as artificial intelligence and quantum-based methods can play a crucial role in manufacturing efficient pharmaceuticals and reducing adverse events.
The newly-emerged pathological conditions and increased rates of drug resistance necessitate application of the state-of-the-art technologies for accelerated discovery of the therapeutic candidates and obtaining comprehensive knowledge about their targets, action mechanisms, and interactions within the body including those between the receptors and drugs. Using the physics- and chemistry-based modern techniques for theranostic purposes, preparing smart carriers, local delivery of genes or drugs, and enhancing pharmaceutical bioavailability could be of great value against the hard-to-treat diseases and growing drug resistance. Besides the artificial intelligence- and quantum-based techniques, crystal engineering capable of designing new molecules with appropriate characteristics, improving the stability and bioavailability of poorly soluble drugs, and efficient carrier development could play a crucial role in manufacturing efficient pharmaceuticals and reducing the adverse events. In this context, identifying the structures and behaviors of crystals and predicting their characteristics are of great value. Electron diffraction by accelerated analysis of the chemicals and sensitivity to charge alterations, electromechanical tools for controlled delivery of therapeutics, mechatronics via fabrication of multi-functional smart products including the organ-on-chip devices for healthcare applications, and optomechatronics by overcoming the limitations of conventional biomedical techniques could address the unmet biomedical requirements and facilitate development of more effective theranostics with improved outcomes.

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