3-Oxidopyridinium Ions Are Versatile Bioorthogonal Dipoles for Use in Cycloadditions with Cyclooctynes.

3-oxidopyridinium ions are water stable and soluble heteroaromatic betaines that behave as latent dipoles and undergo a wide variety of cycloadditions. Research into the cycloaddition reactions of 3-oxidopyridiniums was spearheaded by Alan R. Katritzky and collaborators from the early 1970s until the late 1980s, but they have yet to be used for bioorthogonal applications. Herein we report that 3-oxidopyridiniums can readily react with 4-dibenzocyclooctynol (DIBO), a common bioorthogonal handle, in a [3+2] cycloaddition. The mechanism was investigated by altering the electronics of the reaction by changing the substituent on the 5 position of the pyridinium. Electron-donating 5-substituents have been shown to significantly increase the rate of the reaction, with bimolecular rate constants ranging from 3.3×10-4 s-1 with 5-trifluoromethyl-N-methyl-3-oxidopyridinium to 1.07 M-1 s-1 with 5-amino-N-methyl-3-oxidopyridinium. 3-oxidopyridiniums' appreciable cycloaddition rates and compatibility with bioorthogonally relevant environments give them the potential to be used in a variety of bioconjugation applications.

Bioorthogonal Reactions Utilizing Nitrones as Versatile Dipoles in Cycloaddition Reactions.

Bioorthogonal chemical reactions have emerged as convenient and rapid methods for incorporating unnatural functionality into living systems. Different prototype reactions have been optimized for use in biological settings. Optimization of 3 + 2 dipolar cycloadditions involving nitrones has resulted in highly efficient reaction conditions for bioorthogonal chemistry. Through substitution at the nitrone carbon or nitrogen atom, stereoelectronic tuning of the reactivity of the dipole has assisted in optimizing reactivity. Nitrones have been shown to react rapidly with cyclooctynes with bimolecular rate constants approaching k2 = 102 M-1 s-1, which are among the fastest bioorthogonal reactions reported (McKay et al. Org. Biomol. Chem. 2012, 10, 3066-3070). Nitrones have also been shown to react with trans-cyclooctenes (TCO) in strain-promoted TCO-nitrone cycloadditions reactions. Copper catalyzed reactions involving alkynes and nitrones have also been optimized for applications in biology. This review provides a comprehensive accounting of the different bioorthogonal reactions that have been developed using nitrones as versatile reactants, and provides some recent examples of applications for probing biological systems.

Characterization of Nitrogen-Containing Polycyclic Aromatic Heterocycles in Crude Oils and Refined Petroleum Products.

A large amount of polycyclic aromatic hydrocarbons (PAHs) and their heterocyclic analogues (N, S, O) are released to the marine environment from natural oil seeps, oil spills, bilge discharges and input of land-based sources. Many of these compounds are toxic and have a deleterious effect on marine biota. Nitrogen-containing compounds in crude oils are typically present as cyclic compounds such as polycyclic aromatic nitrogen heterocycles (PANHs) and are generally classified into the two categories of nonbasic (N-PANHs) and basic compounds (B-PANHs). Chromatographic analyses of PANHs are easily to be interfered by other oil components without proper sample preparation prior to instrumental analysis. In this work, dual solid phase extraction columns of 3-(isocyanato)propyl-functionalized silica gel (Si-NCO) and silica gel were employed to efficiently separate both N-PANHs and B-PANHs from saturated and aromatic petroleum hydrocarbons, which enable simultaneous accurate analyses of these groups with single sample preparation. Crude oils studied contain various concentrations of N-PANHs including carbazole, benzocarbazole and B-PANHs including quinolone, acridine and benzoacridine as well as their alkylated homologues. These compounds in light fuel and lubricating oil are generally not detected or are only in trace concentration, but have considerable abundance in heavy fuel oils. Crude oils from different sources and various petroleum products have their unique absolute concentrations and relative distribution patterns of PANHs. Chemical fingerprints of PANHs can provide valuable information for forensic oil spill identification and improve the understanding of the fate, behaviour and chemical degradation of spilled crude oil.