Supramolecular Interactions in Chemomechanical Polymers

Abstract: ConspectusMolecular recognition is the basis for the operation of most biological functions; outside of nature, it has also been developed to a high degree of sophistication within the framework of supramolecular chemistry. More recently, selective noncovalent interactions-which constitute molecular recognition-are being used in intelligent new materials that transform chemical signals into actions, such as the release of drugs. The presence of supramolecular binding sites allows chemomechanical polymers to op… Show more

“…[87] The Schneider group delivered proof-of-principle for the utility of chemomechanical polymers as actuators (machines) or in drug delivery. [84] This application potential together with the demonstrated logic switching opens interesting perspectives for the further career of these "intelligent" materials.…”

“…Well defined three-dimensional size changes in the millimeter range were discussed in a series of reports about chemomechanical polymers developed by the Schneider group. [84] These polymers contain various functional recognition sites for effector molecules, which are attracted via ion-pairing, hydrogen bonding, cation- interactions, metal complexation, hydrophobic effects, etc. (see two example polymers in Scheme 18).…”

Information Processing with Molecules—Quo Vadis?

“…[87] The Schneider group delivered proof-of-principle for the utility of chemomechanical polymers as actuators (machines) or in drug delivery. [84] This application potential together with the demonstrated logic switching opens interesting perspectives for the further career of these "intelligent" materials.…”

“…Well defined three-dimensional size changes in the millimeter range were discussed in a series of reports about chemomechanical polymers developed by the Schneider group. [84] These polymers contain various functional recognition sites for effector molecules, which are attracted via ion-pairing, hydrogen bonding, cation- interactions, metal complexation, hydrophobic effects, etc. (see two example polymers in Scheme 18).…”

Information Processing with Molecules—Quo Vadis?

“…The focus of this review is the macroscopic materials designed, synthesized, and applied based on or inspired by DNA and the application of these materials specifically for biology and medicine. Changes in the nanoscale structures can trigger macroscopic changes in the materials (Schneider & Strongin 2009). For these macro-materials, incorporation of DNA into the structural design confers a number of possibilities that would otherwise not be feasible.…”

Development of DNA Based Active Macro–Materials for Biology and Medicine: A Review

“…[4,5] Herkömmliche Polymergele werden durch vernetzte kovalent gebundene Polymere gebildet, die aufquellen und ein Vielfaches ihres Eigengewichts an Lösungsmittel aufnehmen können. [6] Dagegen werden supramolekulare Gele im Allgemeinen aus niedermolekularen organischen Verbindungen aufgebaut, die sich über nichtkovalente Wechselwirkungen zu supramolekularen Netzwerken zusammenlagern, welche dann in der Lage sind, Lösungsmittelmoleküle aufzunehmen. Da solche Gele durch viele schwache, reversible Wechselwirkungen zusammengehalten werden, stellen die supramolekularen Gele eine besonders reaktionsfähige und regulierbare Form von weichem Material dar.…”

Bausteine mit Hohlräumen in supramolekularen Gelen