The
effects of the CF2H moiety on H-bond (HB) acidity
and lipophilicity of various compounds, when attached directly to
an aromatic ring or to other functions like alkyls, ethers/thioethers,
or electron-withdrawing groups, are discussed. It was found that the
CF2H group acts as a HB donor with a strong dependence
on the attached functional group (A = 0.035–0.165).
Regarding lipophilicity, the CF2H group may act as a more
lipophilic bioisostere of OH but as a similar or less lipophilic bioisostere
of SH and CH3, respectively, when attached to Ar or alkyl.
In addition, the lipophilicity of ethers, sulfoxides, and sulfones
is dramatically increased upon CH3/CF2H exchange
at the α position. Interestingly, this exchange significantly
affects not only the polarity and the volume of the solutes but also
their HB-accepting ability, the main factors influencing log P
oct. Accordingly, this study may be helpful
in the rational design of drugs containing this moiety.
Modulation
of the H-bond basicity (pK
HB) of various
functional groups (FGs) by attaching fluorine functions
and its impact on lipophilicity and bioisosterism considerations are
described. In general, H/F replacement at the α-position to
H-bond acceptors leads to a decrease of the pK
HB value, resulting, in many cases, in a dramatic increase
in the compounds’ lipophilicity (log P
o/w). In the case of α-CF2H, we found
that these properties may also be affected by intramolecular H-bonds
between CF2H and the FG. A computational study of ketone
and sulfone series revealed that α-fluorination can significantly
affect overall polarity, charge distribution, and conformational preference.
The unique case of α-di- and trifluoromethyl ketones, which
exist in octanol/water phases as ketone, hemiketal, and gem-diol forms,
in equilibrium, prevents direct log P
o/w determination by conventional methods, and therefore, the
specific log P
o/w values of these
species were determined directly, for the first time, using Linclau’s 19F NMR-based method.
Following our ongoing studies on the reactivity of the fluoride ion toward organophosphorus compounds, we established that the extremely toxic and environmentally persistent chemical warfare agent VX (O-ethyl S-2-(diisopropylamino)ethyl methylphosphonothioate) is exclusively and rapidly degraded to the nontoxic product EMPA (ethyl methylphosphonic acid) even in dilute aqueous solutions of fluoride. The unique role of the P-F bond formation in the reaction mechanism was explored using both experimental and computational mechanistic studies. In most cases, the "G-analogue" (O-ethyl methylphosphonofluoridate, Et-G) was observed as an intermediate. Noteworthy and of practical importance is the fact that the toxic side product desethyl-VX, which is formed in substantial quantities during the slow degradation of VX in unbuffered water, is completely avoided in the presence of fluoride. A computational study on a VX-model, O,S-diethyl methylphosphonothioate (1), clarifies the distinctive tendency of aqueous fluoride ions to react with such organophosphorus compounds. The facility of the degradation process even in dilute fluoride solutions is due to the increased reactivity of fluoride, which is caused by the significant low activation barrier for the P-F bond formation. In addition, the unique nucleophilicity of fluoride versus hydroxide toward VX, in contrast to their relative basicity, is discussed. Although the reaction outcomes were similar, much slower reaction rates were observed experimentally for the VX-model (1) in comparison to VX.
The synthesis and properties of a new class of anhydrous quaternary ammonium fluorides, based on the rigid skeleton azabicyclo[2.2.2]octane, is described. Compounds 2a-d were easily prepared by passing the corresponding ammonium iodides over fluoride-based resin followed by drying their hydrated form at 100 or 140 °C under reduced pressure. The stability (experimental and theoretical study), solubility, reactivity, and characterization by solution and solid-state MAS NMR are discussed.
Fluorine atoms play an important role in all branches of chemistry and accordingly, it is very important to study their unique and varied effects systematically, in particular, the structure-physicochemical properties relationship. The present study describes exceptional physicochemical effects resulting from a H/F exchange at the methylene bridge of gem-difunctional compounds. The Δlog P (CF2-CH2) values, that is, the change in lipophilicity, observed for the CH 2 /CF 2 replacement in various α,α-phenoxyand thiophenoxy-esters/amides, diketones, benzodioxoles and more, fall in the range of 0.6-1.4 units, which for most cases, is far above the values expected for such a replacement. Moreover, for compounds holding more than one such gem-difunctional moiety, the effect is nearly additive, so one can switch from a hydrophilic compound to a lipophilic one in a limited number of H/F exchanges. DFT studies of some of these systems revealed that polarity, conformational preference as well as charge distributions are strongly affected by such hydrogen to fluorine atom substitution. The pronounced effects described, are a result of the interplay between changes in polarity, H-bond basicity and molecular volume, which were obtained with a very low 'cost' in terms of molecular weight or steric effects and may have a great potential for implementation in various fields of chemical sciences.
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