Dihydroquinoline compounds

Substituted phenylisocyanide (34) can be used to make a dihydroquinoline compound, (35), (Scheme 23) <95CL575>. 

The mild conditions under which DDQ effects dehydrogenation of dihydroquinoline compounds has proved useful for activating a resin bound safety-catch linker for cleavage by aminol-ysis (eq 24). The excess DDQ and DDQH are easily removed by filtration after the activation step, effectively purging the system of these potential impurities. Conversely, removal of DDQ and DDQH with polymer-bound scavenger resins has also proven valuable in solution phase applications. ... 

Unlike the intermolecular reaction, the intramolecular aminopalladation proceeds more easily[13,14,166], Methylindole (164) is obtained by the intramolecular exo amination of 2-allylaniline (163). If there is another olefinic bond in the same molecule, the aminopalladation product 165 undergoes intramolecular alkene insertion to give the tricyclic compound 166[178]. 2,2-Dimethyl-l,2-dihydroquinoline (168) is obtained by endo cyclization of 2-(3,3-dimethyiallyl)aniline (167). The oxidative amination proceeds smoothly... 

Treatment of quinoline with cyanogen bromide, the von Braun reaction (17), in methanol with sodium bicarbonate produces a high yield of l-cyano-2-methoxy-l,2-dihydroquinoline [880-95-5] (5) (18). Compound (5) is quantitatively converted to 3-bromoquinoline [5332-24-1], through the intermediate (6) [66438-70-8]. These conversions are accompHshed by sequential treatment with bromine in methanol, sodium carbonate, or concentrated hydrochloric acid in methanol. Similar conditions provide high yields of 3-bromomethylquinoHnes. 

Qu tern iy S Its. The ring nitrogen of quinoline reacts with a wide variety of alkylating and acylating agents to produce useful intermediates like A/-benzoylquinolinium chloride [4903-36-0] (8). The quinoline 1,2-adducts, eg, A/-benzyl-2-cyano-l,2-dihydroquinoline [13721 -17-0] (9), or Reissert compounds (28), formed with potassium cyanide can produce 2-carboxyquinoline [93-10-7] (10) or 2-cyanoquinoline [11436-43-7] (11). 

Excellent yields of the former product are also obtained with quinoline N-oxide. Improved yields of Reissert compounds are found under phase-transfer conditions (29). The regiochemistry of the method changes dramatically with /V-alkyl quin olinium salts, eg, /V-methy1quino1inium iodide [3947-76-0] (12), which form 4-cyanoquinoline [23395-72-4] (13) (30), through the intermediary in this example of A[-methyl-4-cyano-l,4-dihydroquinoline... 

Antioxidants. The 1,2-dihydroquinolines have been used in a variety of ways as antioxidants (qv). For example, l,2-dihydro-2,2,4-trimethylquinoline along with its 6-decyl [81045-48-9] and 6-ethoxy [91-53-2] derivatives have been used as antio2onants (qv) and stabilizers (68). A polymer [26780-96-1] of l,2-dihydro-2,2,4-trimethylquinoline is used in resins, copolymers, lubricant oils, and synthetic fibers (69). These same compounds react with aldehydes and the products are useful as food antioxidants (70). A cross-linked polyethylene prepared with peroxides and other monomers in the presence of l,2-dihydro-6-ethoxyquinoline produces polymers with a chemically bonded antioxidant (71). 

Interestingly the Skraup/Doebner-von Miller reaction has been used to prepare a number of spiro-compounds. Aniline was reacted with enone 42 in the presence of iodine to yield dihydroquinoline 43 in acceptable yields. 

The final product—quinoline 5—is formed by an oxidation of the dihydroquinoline 4. As oxidant the aromatic nitro compound 7, that corresponds to the aromatic... 

Plasticiser/oil in rubber is usually determined by solvent extraction (ISO 1407) and FTIR identification [57] TGA can usually provide good quantifications of plasticiser contents. Antidegradants in rubber compounds may be determined by HS-GC-MS for volatile species (e.g. BHT, IPPD), but usually solvent extraction is required, followed by GC-MS, HPLC, UV or DP-MS analysis. Since cross-linked rubbers are insoluble, more complex extraction procedures must be carried out. The determination of antioxidants in rubbers by means of HPLC and TLC has been reviewed [58], The TLC technique for antidegradants in rubbers is described in ASTM D 3156 and ISO 4645.2 (1984). Direct probe EIMS was also used to analyse antioxidants (hindered phenols and aromatic amines) in rubber extracts [59]. ISO 11089 (1997) deals with the determination of /V-phenyl-/9-naphthylamine and poly-2,2,4-trimethyl-1,2-dihydroquinoline (TMDQ) as well as other generic types of antiozonants such as IV-alkyl-AL-phenyl-p-phenylenediamines (e.g. IPPD and 6PPD) and A-aryl-AL-aryl-p-phenylenediamines (e.g. DPPD), by means of HPLC. 

In an acetone extract from a neoprene/SBR hose compound, Lattimer et al. [92] distinguished dioctylph-thalate (m/z 390), di(r-octyl)diphenylamine (m/z 393), 1,3,5-tris(3,5-di-f-butyl-4-hydroxybenzyl)-isocyanurate m/z 783), hydrocarbon oil and a paraffin wax (numerous molecular ions in the m/z range of 200-500) by means of FD-MS. Since cross-linked rubbers are insoluble, more complex extraction procedures must be carried out (Chapter 2). The method of Dinsmore and Smith [257], or a modification thereof, is normally used. Mass spectrometry (and other analytical techniques) is then used to characterise the various rubber fractions. The mass-spectral identification of numerous antioxidants (hindered phenols and aromatic amines, e.g. phenyl-/ -naphthyl-amine, 6-dodecyl-2,2,4-trimethyl-l,2-dihydroquinoline, butylated bisphenol-A, HPPD, poly-TMDQ, di-(t-octyl)diphenylamine) in rubber extracts by means of direct probe EI-MS with programmed heating, has been reported [252]. The main problem reported consisted of the numerous ions arising from hydrocarbon oil in the recipe. In older work, mass spectrometry has been used to qualitatively identify volatile AOs in sheet samples of SBR and rubber-type vulcanisates after extraction of the polymer with acetone [51,246]. 

Oxidative ageing of rubbers is limited by the rate of diffusion of oxygen into the rubber product and is usually confined to the outer 3 mm. Antioxidants are used to protect rubbers from the effects of thermal oxidation and the vast majority of compounds will contain one or more. Peroxide vulcanisates are usually protected with dihydroquinolines. Other antioxidants react adversely with the peroxide inhibiting the crosslinking reaction. 

N-Nitroso compounds occur in many operations in the rubber industry. Some nitrosamines (nitrosodiphenylamine, N-N-dinitrosopentamethylenetetramine, polymerized N-nitroso 2,2,4-trimethyl-l,2-dihydroquinoline and N-methyl-N-4-dinitroso aniline) are used as organic accelerators and antioxidants in the production of rubber and often the products are found to be contaminated with such compounds [19]. 

A series of novel 4-substituted-l,4-dihydroquinolines 140 were prepared and found to exhibit moderate to excellent mammalian topo II inhibitory activity. Among the compounds prepared, in general, the nitrogen analogues are the most active compounds and the sulfur analogue is the least active one. The most potent analogue 140 (X=NH-2-pyridinyl), had a topo II potency nearly equivalent to VP-16, a clinically useful topo II interactive antitumor agent, q. (55) [197]. 

A reinvestigation of the experiments on the UV irradiation of l-acetyl-l,2-dihydroquinoline-2-carbonitriles (Reissert compounds) 561 unequivocally demonstrated that the rearrangement via the diradical intermediate 562 gave 4//-3,l-benzoxazines 563 and 565 rather than the benzazete derivatives described earlier. The yields and the type of products were strongly influenced by the substituent R at position 4 while irradiation of the unsubstituted quinoline 561 (R=H) gave 3,1-benzoxazine 563 in nearly quantitative yield, the amount of the corresponding methyl-substituted analog 565 that could be isolated was considerable lower, due to its irreversible isomerization via 562 to the stable cycloprop[/ ]indole derivative 564 (Scheme 107) <199811(49)121 >. 

A related reaction has been observed with alkenyl substituted 1,2-dihydroquinolines. Heating these compounds results in oxidation of the heterocycle with corresponding reduction of the double bond. A radical mechanism was also postulated to be operating in this reaction (equation 14) (75JOC2288). 

HCA478). A similar route to quinolines via 1,2- dihydroquinolines starts fromN-propargyl-anilines and is copper catalyzed (62JOC4713). The allyl ether of cyclohexanone oxime (126) heated in benzene at 200 °C gives 5,6,7,8-tetrahydroquinoline (79S221) the proposed mechanism is reinforced by the isolation of a compound (128) formed from the ether (126) and a suggested intermediate (127). 

PhNO, oxidizes the dihydroquinoline to the aromatic compound quinoline. PhNO, is reduced to PhNH, which then reacts with more acrolein. This often violent reaction is moderated by added FeSO. ... 

Antioxidants. The 1,2-dihydroquinolines have been used in a variety of ways as antioxidants. These compounds react with aldehydes, and the products are useful as food antioxidants. 

In a reaction which is mechanistically related to the Skraup reaction an a,/ -unsaturated carbonyl compound, generated by way of an acid-catalysed aldol condensation, reacts with a primary aromatic amine in the presence of acid to yield a quinoline derivative (Doebner-Miller reaction). For example, when aniline is heated with paraldehyde (which depolymerises to acetaldehyde during the reaction) in the presence of hydrochloric acid the final product is 2-methyl-quinoline (101) (quinaldine, Expt 8.40). Retrosynthetic analysis for the 1,2-dihydroquinoline reveals crotonaldedhyde as the unsaturated carbonyl component which is in turn formed from acetaldehyde (see Section 5.18.2, p. 799). 

The indolenine 17 and the 3,4-dihydroquinoline derivative 18 have been prepared and comparative studies made. In the case of compound 18, there is hydrogen bonding between the hydroxyl and the carbonyl groups but this does not occur in compound 17 <1998J(P1)1193, 1998J(P 1)1203>. 

Tanaka, K., Kakinoki, O., and Toda, F. (1992) Control of the stereochemistry in the photocydisation of acrylanilides to 3,4-dihydroquinolin-2(lH)-ones. Delicate dependence on the host compound. Journal of the Chemical Society, Chemical Communications, 1053-1054. 

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