Oxa-dibenzocyclooctynes (ODIBO, 2a–c) are prepared by photochemical decarbonylation of corresponding cyclopropenones (photo-ODIBO, 1a–c). While photo-ODIBO does not react with azides, ODIBO is one of the most reactive cyclooctynes exhibiting rates of cycloaddition over 45 M−1s−1 in aqueous solutions. ODIBO is stable under ambient conditions and has low reactivity towards thiols. Photo-ODIBO survives heating up to 160°C and does not react with thiols.
Irradiation of cyclopropenone-masked dibenzocyclooctynes with near-infrared pulses from a femtosecond laser triggers photodecarbonylation via nonresonant two- or three-photon excitation. Multiphoton-generated cyclooctynes undergo a SPAAC reaction with organic azides, yielding the expected triazoles. Multiphoton-triggered SPAAC (MP-SPAAC) enables high resolution 3-D photoclick derivatization of hydrogels and tissues.
Herein we report a robust, highly selective, and efficient method to prepare dense poly(ethylene glycol) (PEG) polymer brushes on silicon substrates via solvent-free, catalyst-free, strain-promoted acetylene−azide cycloaddition (SPAAC) reaction. First, poly(glycidyl methacrylate) was grafted to the silicon substrate as an anchoring layer to immobilize cyclopropenone-caged dibenzocyclooctyne-amine (photo-DIBO-amine) via an epoxy ring-opening reaction providing protected, stable, and functionalized substrates. Next, three synthesized α-methoxy-ω-azido-PEGs of different molecular weights (5, 10, and 20 kg/mol) were successfully grafted to the photo-DIBO-modified silicon substrates from melt after the deprotection of DIBO with UV-irradiation. PEG molecular weight, reaction temperature, and reaction time were all used to control the grafting reaction for targeted brush thicknesses and grafting densities. The highest grafting density obtained was close to 1.2 chains/nm 2 and was achieved for 5 kg/mol PEG. The prepared PEG polymer brushes displayed efficient antifouling properties and stability in PBS buffer aqueous media for a period of at least two months.
Three photo-click ligation strategies described in this account provide
scientists with efficient and selective tools for derivatization of various
molecules, polymers, and surfaces. Fast photochemical reactions that are
utilized in these techniques permit spatiotemporal control of the process. The
absence of activating reagents and catalysts, as well as compatibility with
aqueous media, makes photo-click ligations suitable for biomedical applications.
The first of these approaches relies on the photochemical decarbonylation of
cyclopropenones to produce cyclooctynes. The latter undergo rapid catalyst-free
strain-promoted azide–alkyne cycloaddition (SPAAC) to azide-tagged substrates.
The second method is based on a very fast (>104 M–1
s–1) light-triggered hetero-Diels–Alder reaction and permits
efficient derivatization of substrates bearing vinyl ether moiety. An even
faster reaction between photochemically generated naphthoquinone methides
(oNQMs) and thiols (~2 × 105 M–1
s–1) serves as a basis for a third method. This thiol photo-click
chemistry allows for the selective derivatization of thiol-functionalized
substrates or labeling of free cysteine residues in proteins. The thioether
linkage produced by the reaction of oNQMs and a thiol is stable
under ambient conditions, but can be cleaved by UV irradiation, regenerating
free thiol. This feature permits the removal or replacement of immobilized
compounds, as well as traceless substrate release.
In this study, we report the design, synthesis, and characterization of small 3 nm water soluble gold nanoparticles (AuNPs) that feature cyclopropenone-masked strained alkyne moieties capable of undergoing interfacial strain-promoted cycloaddition (i-SPAAC) with azides after exposure to UV-A light. A strained alkyne precursor was incorporated onto AuNPs by direct ligand exchange of a thiol-modified cyclopropenone-masked dibenzocyclooctyne (photoDIBO) ligand. These photoDIBO-AuNPs were characterized by H NMR, IR, and UV/Vis spectroscopy, as well as transmission electron microscopy (TEM) and thermogravimetric analysis (TGA), and the extent of modification was quantified. Upon irradiation with UV-A light, photoDIBO-AuNPs underwent efficient and quantitative regeneration of the parent strained alkyne by photochemical decarbonylation to afford DIBO-derivatized AuNPs. DIBO-AuNPs were found to react cleanly and rapidly (k=5.3×10 m s ) by an interfacial strain-promoted alkyne-azide cycloadditon (i-SPAAC) with benzyl azide, which served as a simple model system. Furthermore, DIBO-AuNPs were reacted with various azides and a nitrone (interfacial strain-promoted alkyne-nitrone cycloaddition, i-SPANC) to showcase the generality of this approach for the facile modification of AuNP surfaces and their properties. The cyclopropenone-based photo-triggered click chemistry at the interface of water-soluble AuNPs offers exciting opportunities for the atom-by-atom control and assembly of functional materials for applications in materials and biomaterials science as well as in chemical biology.
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