Application of cyclodextrin in food industry

“…Although the literature contains numerous reviews covering the diverse applications of CDs and CD-based assemblies, including metal complexation, 11,41,161,162 cyclodextrin metal–organic frameworks, 163 cyclodextrin covalent organic frameworks, 164–167 supramolecular catalysis and synthesis, 168–170 multistimuli-responsive materials, 15,171–173 polymer materials, 13,24,174–181 self-healing materials, 182 amphiphilic materials, 90,183 crystalline organic materials, 184 liquid crystal materials, 14 rotaxanes/polypseudorotaxanes/catenanes/polyrotaxanes, 185–190 drug/protein/gene delivery, 16,19,23,191–194 molecular recognition and imaging, 1,195–199 molecular machines, 200 thiolated cyclodextrins, 201 cyclodextrin–porphyrinoid systems, 202 foods and antioxidants, 203,204 electrochemical analysis, 5 and chiral analysis, 205 to the best of our knowledge, multicharged CDs as an important building block have not been comprehensively reviewed. Multilevel supramolecular assembly based on electrostatic interactions between opposite charges, including parent CDs modified with multiple charges or encapsulating charged guest molecules, has enabled the construction of a diverse variety of multifunctional materials, and these have been widely applied in drug delivery, 206–214 bioimaging, 215–218 molecular recognition, 219–231 nanochannels, 232,233 molecular switches, 26,234 adsorbents and enrichment, 235–237 surfactants, 238 electrospinning supramolecular systems, 239,240 supercapacitors, 241 CD–polyoxometalate complexes, 242–245 liquid crystal materials, 246 multistimuli-responsive materials, 247–252 pseudorotaxanes, 253 conductive polymers, 254 photodynamic/chemotherapy, 255 molecular shuttles, 256,257 etc.…”

Multicharged cyclodextrin supramolecular assemblies

“…Although the literature contains numerous reviews covering the diverse applications of CDs and CD-based assemblies, including metal complexation, 11,41,161,162 cyclodextrin metal–organic frameworks, 163 cyclodextrin covalent organic frameworks, 164–167 supramolecular catalysis and synthesis, 168–170 multistimuli-responsive materials, 15,171–173 polymer materials, 13,24,174–181 self-healing materials, 182 amphiphilic materials, 90,183 crystalline organic materials, 184 liquid crystal materials, 14 rotaxanes/polypseudorotaxanes/catenanes/polyrotaxanes, 185–190 drug/protein/gene delivery, 16,19,23,191–194 molecular recognition and imaging, 1,195–199 molecular machines, 200 thiolated cyclodextrins, 201 cyclodextrin–porphyrinoid systems, 202 foods and antioxidants, 203,204 electrochemical analysis, 5 and chiral analysis, 205 to the best of our knowledge, multicharged CDs as an important building block have not been comprehensively reviewed. Multilevel supramolecular assembly based on electrostatic interactions between opposite charges, including parent CDs modified with multiple charges or encapsulating charged guest molecules, has enabled the construction of a diverse variety of multifunctional materials, and these have been widely applied in drug delivery, 206–214 bioimaging, 215–218 molecular recognition, 219–231 nanochannels, 232,233 molecular switches, 26,234 adsorbents and enrichment, 235–237 surfactants, 238 electrospinning supramolecular systems, 239,240 supercapacitors, 241 CD–polyoxometalate complexes, 242–245 liquid crystal materials, 246 multistimuli-responsive materials, 247–252 pseudorotaxanes, 253 conductive polymers, 254 photodynamic/chemotherapy, 255 molecular shuttles, 256,257 etc.…”

Multicharged cyclodextrin supramolecular assemblies

“…Zhang et al modified β-CD with three cinnamic acid derivatives, and the resulted products showed much enhanced water solubility of more than 600 mg/mL. The increased aqueous solubility of CD derivatives could prevent the absorption of them through a biological membrane and therefore alleviate their toxicity and promote their application in health-related fields. , …”

“…The increased aqueous solubility of CD derivatives could prevent the absorption of them through a biological membrane and therefore alleviate their toxicity and promote their application in health-related fields. 29,31 3.6. Thermal Stability of SACD.…”

Simple Strategy Preparing Cyclodextrin Carboxylate as a Highly Effective Carrier for Bioactive Compounds

“…Cyclodextrins are a family of cyclic oligosaccharides consisting of a macrocyclic ring containing glucose subunits that are linked by alpha-4.1 glycoside bonds that are produced through starch by enzymatic conversion ( Liu, Chen, Gao, Fu, & Hu, 2020 ). The three main types of this group of compounds are α-cyclodextrin(6 glucose subunits), β-cyclodextrin(7 glucose subunits) and γ-cyclodextrin(8 glucose subunits).…”

Loading of fish oil into β-cyclodextrin nanocomplexes for the production of a functional yogurt