Reinforcement of ‘imine-hydroxyl chelation pocket’ by encapsulating into the β-CD cavity for the sterically protective detection of Al3+

“…[19][20][21][22] In this scenario, hydrophobic groups penetrate the β-CD cavity, while polar groups interact with the hydroxyl groups at the cavity's edge through hydrogen bonds and other polar interactions, thereby altering the material's physical and chemical properties. 23,24 Decsov et al successfully prepared 2-hydroxypropyl-β-cyclodextrin (HP-β-CD) fibers from an aqueous solution through high-speed electrospinning, with β-CD as the primary material. These fibers were subsequently incorporated into PLA and ammonium polyphosphate (APP) to generate a flame-retardant composite.…”

“…In this scenario, hydrophobic groups enter the β‐CD cavity, while polar groups interact with the hydroxyl groups at the cavity's edge through hydrogen bonds and other polar interactions, thereby altering the material's physical and chemical properties 19–22 . In this scenario, hydrophobic groups penetrate the β‐CD cavity, while polar groups interact with the hydroxyl groups at the cavity's edge through hydrogen bonds and other polar interactions, thereby altering the material's physical and chemical properties 23,24 . Decsov et al successfully prepared 2‐hydroxypropyl‐β‐cyclodextrin (HP‐β‐CD) fibers from an aqueous solution through high‐speed electrospinning, with β‐CD as the primary material.…”

Synergistic flame retardancy of aluminum diethylphosphinate and piperazine pyrophosphate/β‐cyclodextrin in polylactic acid

“…[19][20][21][22] In this scenario, hydrophobic groups penetrate the β-CD cavity, while polar groups interact with the hydroxyl groups at the cavity's edge through hydrogen bonds and other polar interactions, thereby altering the material's physical and chemical properties. 23,24 Decsov et al successfully prepared 2-hydroxypropyl-β-cyclodextrin (HP-β-CD) fibers from an aqueous solution through high-speed electrospinning, with β-CD as the primary material. These fibers were subsequently incorporated into PLA and ammonium polyphosphate (APP) to generate a flame-retardant composite.…”

“…In this scenario, hydrophobic groups enter the β‐CD cavity, while polar groups interact with the hydroxyl groups at the cavity's edge through hydrogen bonds and other polar interactions, thereby altering the material's physical and chemical properties 19–22 . In this scenario, hydrophobic groups penetrate the β‐CD cavity, while polar groups interact with the hydroxyl groups at the cavity's edge through hydrogen bonds and other polar interactions, thereby altering the material's physical and chemical properties 23,24 . Decsov et al successfully prepared 2‐hydroxypropyl‐β‐cyclodextrin (HP‐β‐CD) fibers from an aqueous solution through high‐speed electrospinning, with β‐CD as the primary material.…”

Synergistic flame retardancy of aluminum diethylphosphinate and piperazine pyrophosphate/β‐cyclodextrin in polylactic acid

Review on β-cyclodextrin inclusion complex based chemosensors for heavy metals

Enhanced flame retardancy of modified β-cyclodextrin doped silica fume-based geopolymeric coating covered on plywood