Cooperative capture synthesis: yet another playground for copper-free click chemistry

Abstract: Click chemistry describes a family of modular, efficient, versatile and reliable reactions which have acquired a pivotal role as one of the most useful synthetic tools with a potentially broad range of applications. While copper(i)-catalysed alkyne-azide cycloaddition is the most widely adopted click reaction in the family, the fact that it is cytotoxic restricts its practice in certain situations, e.g., bioconjugation. Consequently, researchers have been exploring the development of copper-free click reaction… Show more

“…20)isthe rate-determining step followed by rapid first-order RC ring opening (20 ! More than [2+ +2]CA-RC reactions,S PA AC reactions are highly important within the realm of click chemistry in awide range of chemical disciplines,including materials science [21][22][23] and chemical biology. Fort he ratedetermining step (DG°2 98 K = 22.1 AE 0.6 kcal mol À1 )t he entropic contribution (DS°= À37.5 AE 1.0 cal K À1 mol, at 298 K: DS°2 98 K = À11.2 AE 0.3 kcal mol À1 )s lightly exceeds that of the enthalpy (DH°= 10.9 AE 0.3 kcal mol À1 ;Supporting Information, Figure S44, Table S1).…”

“…The development of archetypal angle-strained alkynes that have laid the foundationsf or aryne and bioorthogonalchemistry; starting from 1,2-didehydrobenzene [8] and cyclooctyne in the 1950s. Moreover,w ea lso demonstrate that these structures can undergo facile and high-yielding SPAAC reactions,t herefore opening the door to ar ange of applications in materials science [21][22][23] and chemical biology. Moreover,w ea lso demonstrate that these structures can undergo facile and high-yielding SPAAC reactions,t herefore opening the door to ar ange of applications in materials science [21][22][23] and chemical biology.…”

Strain‐Promoted Reactivity of Alkyne‐Containing Cycloparaphenylenes

“…20)isthe rate-determining step followed by rapid first-order RC ring opening (20 ! More than [2+ +2]CA-RC reactions,S PA AC reactions are highly important within the realm of click chemistry in awide range of chemical disciplines,including materials science [21][22][23] and chemical biology. Fort he ratedetermining step (DG°2 98 K = 22.1 AE 0.6 kcal mol À1 )t he entropic contribution (DS°= À37.5 AE 1.0 cal K À1 mol, at 298 K: DS°2 98 K = À11.2 AE 0.3 kcal mol À1 )s lightly exceeds that of the enthalpy (DH°= 10.9 AE 0.3 kcal mol À1 ;Supporting Information, Figure S44, Table S1).…”

“…The development of archetypal angle-strained alkynes that have laid the foundationsf or aryne and bioorthogonalchemistry; starting from 1,2-didehydrobenzene [8] and cyclooctyne in the 1950s. Moreover,w ea lso demonstrate that these structures can undergo facile and high-yielding SPAAC reactions,t herefore opening the door to ar ange of applications in materials science [21][22][23] and chemical biology. Moreover,w ea lso demonstrate that these structures can undergo facile and high-yielding SPAAC reactions,t herefore opening the door to ar ange of applications in materials science [21][22][23] and chemical biology.…”

Strain‐Promoted Reactivity of Alkyne‐Containing Cycloparaphenylenes

“…Cucurbit[n]urils (Q[n]s) [1][2][3][4][5][6] are generally characterized by a nearly neutral electro-potential cavity and two negative electro-potential carbonyl-fringed portals, in addition to a positive electro-potential outer surface: the cavities of Q[n]s can accommodate various guest molecules through hydrophobic interactions, resulting in characteristic cucurbit[n]uril chemistry known as Q[n]-based host-guest chemistry; [7][8][9][10][11][12][13][14][15][16][17] Additionally, carbonyl groups on the rims of the portals of Q[n]s can interact with metal ions through direct coordination, resulting in distinct Q[n]-based coordination chemistry; [18][19][20][21] Furthermore, the positive electro-potential outer surface of Q[n]s can induce the formation of various novel supramolecular assemblies thorough the outer surface interaction of cucurbit[n]urils, which is another emerging research field in cucurbit[n]uril chemistry. [22] To date, Q[n]-based host-guest chemistry and Q[n]based coordination chemistry have received most attention in Q[n] research, including molecular machines or switches, [23] materials science, supramolecular materials and polymers, [15,24] life science, [25] catalysis, [13,14] sensors and other applications.…”

“…

Based on the study of a known host-guest inclusion complex comprising cucurbit [6]uril (Q[6]) and a hemicyanine dye, trans-4- [4-(dimethylamino)styryl]-1-pyridinium iodide (t-DSMI), a water-soluble symmetric tetramethylcucurbit[6]uril (TMeQ[6]), was selected to construct a t-DSMI-based probe to test the response to various metal cations in neutral water. [22] To date, Q[n]-based host-guest chemistry and Q[n]based coordination chemistry have received most attention in Q[n] research, including molecular machines or switches, [23] materials science, supramolecular materials and polymers, [15,24] life science, [25] catalysis, [13,14] sensors and other applications.Cucurbit[n]urils (Q[n]s) can interact with both guests (G) and metal cations (M n+ ), respectively. ">Introduction

Cucurbit[n]urils (Q[n]s) [1][2][3][4][5][6] are generally characterized by a nearly neutral electro-potential cavity and two negative electro-potential carbonyl-fringed portals, in addition to a positive electro-potential outer surface: the cavities of Q[n]s can accommodate various guest molecules through hydrophobic interactions, resulting in characteristic cucurbit[n]uril chemistry known as Q[n]-based host-guest chemistry; [7][8][9][10][11][12][13][14][15][16][17] Additionally, carbonyl groups on the rims of the portals of Q[n]s can interact with metal ions through direct coordination, resulting in distinct Q[n]-based coordination chemistry; [18][19][20][21] Furthermore, the positive electro-potential outer surface of Q[n]s can induce the formation of various novel supramolecular assemblies thorough the outer surface interaction of cucurbit[n]urils, which is another emerging research field in cucurbit[n]uril chemistry.

…”

Recognition of Different Metal Cations by a trans‐4‐[4‐(Dimethylamino)styryl]‐1‐methylpyridinium Iodide@Tetramethylcucurbit[6]uril Probe

“…4 Nolte, Rowan, and co-workers took advantage of this unique biological rotaxane formation and succeeded in the construction of an artificial rotaxane system composed of a catalyticallyactive porphyrin-based macrocycle that threaded onto a reactive polymer chain during oxidation along the polymer, 5 and further proposed a unique threading mechanism of porphyrin-based macrocycles onto a viologen-appended polymer chain bearing a bulky stopper at one end as a model system, 6 through which the macrocycles thread from the polymer chain in one direction to form a 1:1 inclusion complex with the terminal viologen residue of the polymer. Although a large number of supramolecular rotaxane and pseudorotaxane formations have been reported, 1,2,7 biomimetic pseudorotaxane complex formation between macrocycles and polymers focusing on such a polymer threading process before complexation remains limited. …”

Alkali Metal Ion-enhanced Threading of a Perylenediimide-bound Polymer Chain through a Double-stranded Spiroborate Helicate with a Bisporphyrin Unit