Flow chemistry involves the use of channels or tubing to conduct a reaction in a continuous stream rather than in a flask. Flow equipment provides chemists with unique control over reaction parameters enhancing reactivity or in some cases enabling new reactions. This relatively young technology has received a remarkable amount of attention in the past decade with many reports on what can be done in flow. Until recently, however, the question, "Should we do this in flow?" has merely been an afterthought. This review introduces readers to the basic principles and fundamentals of flow chemistry and critically discusses recent flow chemistry accounts.
Herein, we report a regioselective alkenyl electrophile synthesis from unactivated olefins that is based on a direct and regioselective C−H thianthrenation reaction. The selectivity is proposed to arise from an unusual inverse‐electron‐demand hetero‐Diels–Alder reaction. The alkenyl sulfonium salts can serve as electrophiles in palladium‐ and ruthenium‐catalyzed cross‐coupling reactions to make alkenyl C−C, C−Cl, C−Br, and C−SCF3 bonds with stereoretention.
Recent publications suggest that high dietary fructose might play a significant role in cancer metabolism and can exacerbate a number of aspects of metabolic syndrome. Addressing the role that fructose plays in human health is a controversial question and requires a detailed understanding of many factors including the mechanism of fructose transport into healthy and diseased cells. Fructose transport into cells is thought to be largely mediated by the passive hexose transporters Glut2 and Glut5. To date, no probes that can be selectively transported by one of these enzymes but not by the other have been identified. The data presented here indicate that, in MCF-7 cells, a 1-amino-2,5-anhydro-D-mannitol-based fluorescent NBDM probe is transported twice as efficiently as fructose and that this takes place with the aid of Glut5. Its Glut5 specificity and differential uptake in cancer cells and in normal cells suggest this NBDM probe as a potentially useful tool for cross-cell-line correlation of Glut5 transport activity.
The SLC2 family of facilitative Glucose transporters (Gluts) contains 14 isoforms divided into three classes based on amino acid sequence. While the majority of these proteins transport glucose, a subset can transport fructose. Recently, fructose and the Gluts responsible for fructose uptake have received increased interest due to the correlation between high fructose consumption and early onset of metabolic syndrome. In addition, the up-regulation of Gluts in certain cancers has made possible the development of a number of fructose probes for imaging cancer. Although structure activity data has defined some aspects of fructose-specific uptake, a far more detailed clarification of the variables governing the onset and progression of fructose-correlated diseases is still needed. Here, we summarize what is known about molecular structure and fructose uptake as it relates to the correlation of fructose and disease.
The introduction
of thianthrene as a linchpin has proven to be
a versatile strategy for the C–H functionalization of aromatic
compounds, featuring a broad scope and fast diversification. The synthesis
of aryl thianthrenium salts has displayed an unusually high
para
regioselectivity, notably superior to those observed
in halogenation or borylation reactions for various substrates. We
report an experimental and computational study on the mechanism of
aromatic C–H thianthrenation reactions, with an emphasis on
the elucidation of the reactive species and the nature of the exquisite
site selectivity. Mechanisms involving a direct attack of arene to
the isolated
O
-trifluoracetylthianthrene
S
-oxide (
TT
+
-TFA
) or to the thianthrene
dication (
TT
2+
) via electron transfer under
acidic conditions are identified. A reversible interconversion of
the different Wheland-type intermediates before a subsequent, irreversible
deprotonation is proposed to be responsible for the exceptional
para
selectivity of the reaction.
Aerobic amine oxidation is an attractive and elegant process for the α functionalization of amines. However, there are still several mechanistic uncertainties, particularly the factors governing the regioselectivity of the oxidation of asymmetric secondary amines and the oxidation rates of mixed primary amines. Herein, it is reported that singlet-oxygen-mediated oxidation of 1° and 2° amines is sensitive to the strength of the α-C-H bond and steric factors. Estimation of the relative bond dissociation energy by natural bond order analysis or by means of one-bond C-H coupling constants allowed the regioselectivity of secondary amine oxidations to be explained and predicted. In addition, the findings were utilized to synthesize highly regioselective substrates and perform selective amine cross-couplings to produce imines.
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