Special Issue: Advanced Materials in Drug Release and Drug Delivery Systems

The main aim of drug delivery systems is to regulate the rate of drug release as per the patient's physiological conditions as well as the progression of the illness or as per the circadian rhythms. To achieve such objectives, the new drug delivery systems have been developed to provide the drug release profile, which is based on each patient's needs. Different researches have been done to create drug delivery carriers, focusing on targeting and delivering hydrophobic drug molecules. This review focuses on Polymeric Micelles as the promising drug delivery carrier due to its high stability, protective property against the harsh gastrointestinal environment.

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ID: 1044 DNA origami nanobot for sensitive drug delivery chemotherapy

Biomedical Research and Therapy ◽

10.15419/bmrat.v4is.320 ◽

2017 ◽

Vol 4 (S) ◽

pp. 124

Author(s):

Minh Tri Luu ◽

Shelley Wickham ◽

Ali Abbas

Keyword(s):

Drug Delivery ◽

Gold Nanoparticles ◽

Drug Release ◽

Drug Delivery Systems ◽

Heating Time ◽

Delivery Systems ◽

Chemotherapeutic Agents ◽

Dna Origami ◽

Drug Molecules ◽

Dna Strands

The cutting-edge technology of constructing nanoscale objects using DNA origami has opened new directions for drug delivery in cancer chemotherapy research [1, 2]. This project aims to develop a novel DNA origami nanobot for drug delivery, with high selectivity and specificity for chemotherapy. It is important to be able to control the rate of drug release to maintain the concentration of chemotherapeutic agents at the desirable set-point [3]. This control can be achieved through various activation methods, similar to those used in liposome drug delivery systems, e.g. magnetism, radiation, ultrasound, heating etc. [4]. These stimuli can deliver specific types of energy (e.g. thermal), which can then activate a pre-designed nanobot- topology variation. For example, thermal energy can cause local DNA strands to melt and partially distort some local regions of the DNA topology, releasing drug molecules. One mechanism to activate the drug release is via radio frequency (RF) electromagnetic wave induced heating of gold nanoparticles [6]. A prototype nanobot will be developed and tested for heat-triggered nanobot switching between open and closed configurations. It is hypothesized that upon RF heating, the gold nanoparticles will concentrate the heat and cause the local DNA strands to melt, leading to the open configuration, without melting the rest of the nanobot structure. Heating time and power will be tuned to regulate the drug release rate. This work will develop an effective process control strategy for enhanced performance of nanoscale drug delivery systems.

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Formulation, Development and Characterization of Floating Beads of Diltiazem Hydrochloride

International Journal of Drug Delivery Technology ◽

10.25258/ijddt.v6i1.8883 ◽

2016 ◽

Vol 6 (1) ◽

Author(s):

Anamika Saxena Saxena ◽

Santosh Kitawat ◽

Kalpesh Gaur ◽

Virendra Singh

Keyword(s):

Drug Delivery ◽

Drug Release ◽

Drug Delivery Systems ◽

Entrapment Efficiency ◽

Repeated Administration ◽

Alginate Beads ◽

Delivery Systems ◽

Sem Analysis ◽

Formulation Development

The main goal of any drug delivery system is to achieve desired concentration of the drug in blood or tissue, which is therapeutically effective and nontoxic for a prolonged period. Various attempts have been made to develop gastroretentive delivery systems such as high density system, swelling, floating system. The recent developments of FDDS including the physiological and formulation variables affecting gastric retention, approaches to design single-unit and multiple-unit floating systems, and their classification and formulation aspects are covered in detail. Gastric emptying is a complex process and makes in vivo performance of the drug delivery systems uncertain. In order to avoid this variability, efforts have been made to increase the retention time of the drug-delivery systems for more than 12 hours. The floating or hydrodynamically controlled drug delivery systems are useful in such application. Background of the research: Diltiazem HCL (DTZ), has short biological half life of 3-4 h, requires rather high frequency of administration. Due to repeated administration there may be chances of patient incompliance and toxicity problems. Objective: The objective of study was to develop sustained release alginate beads of DTZ for reduction in dosing frequency, high bioavailability and better patient compliance. Methodology: Five formulations prepared by using different drug to polymer ratios, were evaluated for relevant parameters and compared. Alginate beads were prepared by ionotropic external gelation technique using CaCl2 as cross linking agent. Prepared beads were evaluated for % yield, entrapment efficiency, swelling index in 0.1N HCL, drug release study and SEM analysis. In order to improve %EE and drug release, LMP and sunflower oil were used as copolymers along with sodium alginate.

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Biosurfactants as a Novel Additive in Pharmaceutical Formulations: Current Trends and Future Implications

Current Drug Metabolism ◽

10.2174/1389200221666201008143238 ◽

2020 ◽

Vol 21 (11) ◽

pp. 885-901

Author(s):

Shubham Thakur ◽

Amrinder Singh ◽

Ritika Sharma ◽

Rohan Aurora ◽

Subheet Kumar Jain

Keyword(s):

Drug Delivery ◽

Drug Delivery Systems ◽

Toxicity Testing ◽

Pharmaceutical Formulations ◽

Delivery Systems ◽

Surface Active Agents ◽

Regulatory Status ◽

Different Temperatures ◽

High Production Cost ◽

New Generation

Background: Surfactants are an important category of additives that are used widely in most of the formulations as solubilizers, stabilizers, and emulsifiers. Current drug delivery systems comprise of numerous synthetic surfactants (such as Cremophor EL, polysorbate 80, Transcutol-P), which are associated with several side effects though used in many formulations. Therefore, to attenuate the problems associated with conventional surfactants, a new generation of surface-active agents is obtained from the metabolites of fungi, yeast, and bacteria, which are termed as biosurfactants. Objectives: In this article, we critically analyze the different types of biosurfactants, their origin along with their chemical and physical properties, advantages, drawbacks, regulatory status, and detailed pharmaceutical applications. Methods: 243 papers were reviewed and included in this review. Results: Briefly, Biosurfactants are classified as glycolipids, rhamnolipids, sophorolipids, trehalolipids, surfactin, lipopeptides & lipoproteins, lichenysin, fatty acids, phospholipids, and polymeric biosurfactants. These are amphiphilic biomolecules with lipophilic and hydrophilic ends and are used as drug delivery vehicles (foaming, solubilizer, detergent, and emulsifier) in the pharmaceutical industry. Despite additives, they have some biological activity as well (anti-cancer, anti-viral, anti-microbial, P-gp inhibition, etc.). These biomolecules possess better safety profiles and are biocompatible, biodegradable, and specific at different temperatures. Conclusion: Biosurfactants exhibit good biomedicine and additive properties that can be used in developing novel drug delivery systems. However, more research should be driven due to the lack of comprehensive toxicity testing and high production cost which limits their use.

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Improving the Efficacy of Anticancer Drugs via Encapsulation and Acoustic Release

Current Topics in Medicinal Chemistry ◽

10.2174/1568026618666180608125344 ◽

2018 ◽

Vol 18 (10) ◽

pp. 857-880 ◽

Cited By ~ 3

Author(s):

Salma E. Ahmed ◽

Nahid Awad ◽

Vinod Paul ◽

Hesham G. Moussa ◽

Ghaleb A. Husseini

Keyword(s):

Drug Delivery ◽

Drug Release ◽

Drug Delivery Systems ◽

Delivery Systems ◽

Special Focus ◽

Nano Drug Delivery ◽

Medical Researchers ◽

History Of ◽

Overall Performance ◽

Enhanced Stability

Conventional chemotherapeutics lack the specificity and controllability, thus may poison healthy cells while attempting to kill cancerous ones. Newly developed nano-drug delivery systems have shown promise in delivering anti-tumor agents with enhanced stability, durability and overall performance; especially when used along with targeting and triggering techniques. This work traces back the history of chemotherapy, addressing the main challenges that have encouraged the medical researchers to seek a sanctuary in nanotechnological-based drug delivery systems that are grafted with appropriate targeting techniques and drug release mechanisms. A special focus will be directed to acoustically triggered liposomes encapsulating doxorubicin.

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Nanostructured Ketorolac-Tromethamine/MCF: Synthesis, Characterization and Application in Drug Release System

Current Nanoscience ◽

10.2174/1573413714666180222134742 ◽

2018 ◽

Vol 14 (5) ◽

pp. 432-439 ◽

Cited By ~ 1

Author(s):

Juliana M. Juarez ◽

Jorgelina Cussa ◽

Marcos B. Gomez Costa ◽

Oscar A. Anunziata

Keyword(s):

Drug Delivery ◽

Drug Release ◽

Therapeutic Efficacy ◽

Drug Delivery Systems ◽

Controlled Drug Release ◽

Delivery Systems ◽

The Body ◽

Fickian Diffusion ◽

Ketorolac Tromethamine

Background: Controlled drug delivery systems can maintain the concentration of drugs in the exact sites of the body within the optimum range and below the toxicity threshold, improving therapeutic efficacy and reducing toxicity. Mesostructured Cellular Foam (MCF) material is a new promising host for drug delivery systems due to high biocompatibility, in vivo biodegradability and low toxicity. Methods: Ketorolac-Tromethamine/MCF composite was synthesized. The material synthesis and loading of ketorolac-tromethamine into MCF pores were successful as shown by XRD, FTIR, TGA, TEM and textural analyses. Results: We obtained promising results for controlled drug release using the novel MCF material. The application of these materials in KETO release is innovative, achieving an initial high release rate and then maintaining a constant rate at high times. This allows keeping drug concentration within the range of therapeutic efficacy, being highly applicable for the treatment of diseases that need a rapid response. The release of KETO/MCF was compared with other containers of KETO (KETO/SBA-15) and commercial tablets. Conclusion: The best model to fit experimental data was Ritger-Peppas equation. Other models used in this work could not properly explain the controlled drug release of this material. The predominant release of KETO from MCF was non-Fickian diffusion.

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