Dendrimers as efficient nanocarriers for the protection and delivery of bioactive phytochemicals

• Published in: Advances in colloid and interface science Vol. 278; p. 102125
• Main Authors: Yousefi, Mohammad, Narmani, Asghar, Jafari, Seid Mahdi
• Format: Journal Article
• Language: English
• Published: Netherlands Elsevier B.V 01.04.2020
• Subjects: Bioactive delivery systems; Dendrimers; Dendrimers - chemical synthesis; Dendrimers - chemistry; Dendrimers - metabolism; Drug Carriers - chemistry; Drug Delivery Systems; Encapsulation; Nanocarrier; Nanoparticles - chemistry; Phytochemicals; Phytochemicals - chemistry; Encapsulation; Dendrimers; Phytochemicals; Nanocarrier; Bioactive delivery systems
• ISSN: 0001-8686; 1873-3727; 1873-3727
• DOI: 10.1016/j.cis.2020.102125

The genesis of dendrimers can be considered as a revolution in nano-scaled bioactive delivery systems. These structures possess a unique potential in encapsulating/entrapping bioactive ingredients due to their tree-like nature. Therefore, they could swiftly obtain a valuable statue in nutraceutical, pharmaceutical and medical sciences. Phytochemicals, as a large proportion of bioactives, have been studied and used by scholars in several fields of pharmacology, medical, food, and cosmetic for many years. But, the solubility, stability, and bioavailability issues have always been recognized as limiting factors in their application. Therefore, the main aim of this study is representing the use of dendrimers as novel nanocarriers for phytochemical bioactive compounds to deal with these problems. Hence, after a brief review of phytochemical ingredients, the text is commenced with a detailed explanation of dendrimers, including definitions, types, generations, synthesizing methods, and safety issues; then is continued with demonstration of their applications in encapsulation of phytochemical bioactive compounds and their active/passive delivery by dendrimers. Dendrimers provide a vast and appropriate surface to entrap the targeted phytochemical bioactive ingredients. Several parameters can affect the yield of nanoencapsulation by dendrimers, including their generation, type of end groups, surface charge, core structure, pH, and ambient factors. Another important issue of dendrimers is related to their toxicity. Cationic dendrimers, particularly PAMAM can be toxic to body cells through attaching to the cell membranes and disturbing their functions. However, a number of solutions have been suggested to decrease their toxicity. [Display omitted] •Dendrimers can be considered as a revolution in nano-scaled bioactive delivery systems.•Dendrimers as novel nanocarriers can improve the efficiency of phytochemical bioactive compounds.•Several parameters can affect the yield of nanoencapsulation by dendrimers.•Cationic dendrimers, particularly PAMAM can be toxic to body cells