Palladium complexes of a variety of β- and γ-iminophosphines have been prepared and
characterized by X-ray diffraction studies. Their properties as catalyst for three different
Stille coupling reactions have been investigated and compared to catalytic performances of
a phosphorus-containing dendrimer incorporating analogous γ-iminophosphine palladium
complexes on the surface.
This comprehensive review describes methods for the preparation of 1-indanones published in original and patent literature from 1926 to 2017. More than 100 synthetic methods utilizing carboxylic acids, esters, diesters, acid chlorides, ketones, alkynes, alcohols etc. as starting materials, have been performed. This review also covers the most important studies on the biological activity of 1-indanones and their derivatives which are potent antiviral, anti-inflammatory, analgesic, antimalarial, antibacterial and anticancer compounds. Moreover, they can be used in the treatment of neurodegenerative diseases and as effective insecticides, fungicides and herbicides.
TauBr, despite very low concentration of Br(-) in body fluids, may support TauCl and HOCl in the regulation of inflammatory response and in killing of bacteria by neutrophils. However, TauBr activity in vivo will depend on the presence of H(2)O(2) and possible other mediators of inflammation which can compete with target molecules for TauBr.
Amygdalin (d-Mandelonitrile 6-O-β-d-glucosido-β-d-glucoside) is a natural cyanogenic glycoside occurring in the seeds of some edible plants, such as bitter almonds and peaches. It is a medically interesting but controversial compound as it has anticancer activity on one hand and can be toxic via enzymatic degradation and production of hydrogen cyanide on the other hand. Despite numerous contributions on cancer cell lines, the clinical evidence for the anticancer activity of amygdalin is not fully confirmed. Moreover, high dose exposures to amygdalin can produce cyanide toxicity. The aim of this review is to present the current state of knowledge on the sources, toxicity and anticancer properties of amygdalin, and analytical methods for its determination in plant seeds.
The first solvent-
and catalyst-free procedure for the Michaelis–Arbuzov
reaction under flow conditions was developed. A variety of alkylphosphonic
esters could be obtained using this protocol starting from the corresponding
trialkyl phosphites and even catalytic amounts of alkyl halides with
very short reaction times (8.33–50 min) and excellent conversions.
In general, this protocol works effectively when the alkyl halide
is used in catalytic amounts as low as 5–10% only if it concerns
the synthesis of homo alkylphosphonates. One equivalent and an excess
of alkyl halides should be used in the reaction with alkyl phosphite
if the alkyl group of the selected substrates differ. Thus, it provides
a sustainable, fast alternative to the existing methods for the preparation
of alkylphosphonates. The isolation of the reaction products is straightforward
due to the lack of solvents and a high purity of the obtained products
(conv ≥ 99%), and notably, in the catalytic procedures there
are only traces of alkyl halides formed after the reaction is complete.
The reactions conducted using a glass microreactor chip with an internal
volume of 250 μL allow the production of 1.6–1.95 g of
organophosphorus esters per hour.
The highly substituted mono‐aryl/alkylthio‐(hetero)acenes prepared in this study have been found to be thermally more stable (Tdecomp.=331–354 °C) than the known di‐aryl/alkylthio‐substituted acenes by an average of 25 °C. They are also much more photostable at 254 and 365 nm (in both argon and air) than the parent anthracene and other reported anthracenes. The most photostable aryl/alkylthio‐anthracenes at 254 nm were found to be 60–70 (in air) and 130 (in argon) times more stable in solution than the unsubstituted anthracene, and much more stable than known EDG/EWG‐substituted anthracenes (EDG=electron‐donating group, EWG=electron‐withdrawing group) with an extended aromatic core. Furthermore, the acenes showed significantly higher photostability at 365 nm in both air and argon. The anthracenes were obtained by the novel thio‐Friedel–Crafts/Bradsher cyclization reaction of hitherto unknown [o‐(1,3‐dithian‐2‐yl)aryl](aryl)methyl thioethers. The developed approach provides a general access to mono‐aryl/alkylthio‐substituted (hetero)acene frameworks containing at least three fused (hetero)aromatic rings. The characteristic feature of this approach, which leads to highly substituted acenes, is that the substituents, unlike in other methods, may be introduced at an early stage of the synthesis. DFT and TD‐DFT calculations confirmed the stabilizing role of the aryl/alkylthio substituent in the mono‐aryl/alkylthio‐substituted anthracenes, which are the most stable anthracenes prepared to date. Their high photostability is mainly due to the quenching of singlet oxygen by the acene and the quenching of the acene S1 state by molecular oxygen.
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