Morpholine 4-amino

A novel type of ring closure is the reaction of 6-amino-5-dichloroacetylaminopyrimidines (285) with sulfur and morpholine under the conditions of a Kindler reaction (B-64MI21605). 7-Morpholinopteridin-6-ones (287) are formed, either via thiooxamide derivatives (286) or via corresponding 7,8-dihydropteridines (284 equation 102). Chloral hydrate also reacts with 2-substituted 5,6-diaminopyrimidin-4-ones to form pteridin-6-ones (56JCS3311, 64JCS565) by a so far unknown mechanism. 

Additional evidence that a dynamic equilibrium exists between an enamine, N-hemiacetal, and aminal has been presented by Marchese (41). It should be noted that no acid catalysts were used in the reactions of aldehydes and amines discussed thus far. The piperidino enamine of 2-ethylhexanal (0.125 mole), morpholine (0.375 mole), and p-toluene-sulfonic acid (1.25 x 10 mole) diluted with benzene to 500 ml were refluxed for 5 hr. At the end of this time the enamine mixture was analyzed by vapor-phase chromatography, which revealed that exchange of the amino residue had occurred in a ratio of eight morpholine to one piperidine. Marchese proposed a scheme [Eqs. (4), (5) and (6)] to account for these... 

Morpholine has been used for 5 -phosphate protection in oligonucleotide synthesis and can be cleaved with 0.01 N HCl without significant depurination of bases having free exocyclic amino functions. 

The mixture is then cooled and sodium bisulfite added to decolorize. Recrystallization of the product from methanol gives about 8 g, MP 147° to 150°C. The /3-(3-amino-2,4,6-triiodophenyl)-0 -ethylpropionic acid may be purified further by precipitation of the morpholine salt from ether solution and regeneration of the free amino acid by treatment of a methanol solution of the morpholine salt with sulfur dioxide. The pure amino acid has the MP 155° to 156.5°C. 

A solution of 1-benzyl-4-piperidone, ethyl cyanoacetate, powdery sulfur and morpholine in ethanol is heated moderately under reflux for about 20 minutes to dissolve the powdery sulfur. The mixture is heated under reflux for one further hour to complete the reaction. On standing at room temperature, the mixture yields a precipitate. The precipitate is collected by filtration, washed well with methanol and recrystallized from methanol to give 2-amino-6-benzyl-3-ethoxycarbonyl-4,5,6,7-tetrahydrothieno(2,3-c)-pyridine as almost colorless needles melting at 112° to 113°C. 

A solution of 5.0 g of a-ethyl-(3-(aminophenyl)propionic acid in 100 ml of water containing 5 ml of concentrated hydrochloric acid was added over a period of h hour to a stirred solution of 3.2 ml of Iodine monochioride in 25 ml of water and 25 ml of concentrated hydrochloric acid heated to 60°C. After addition was complete, the heating was continued for h hour longer at 60° to 70°C. A black oil separated which gradually solidified. The mixture was then cooled and sodium bisulfite was added to decolorize. Recrystallization of the product from methanol gave about 8 g of a-ethyl-(3-(2,4,6-triiodo-3-aminophenyl-pro-pionic acid, MP 147° to 150°C. The product could be further purified by precipitation of its morpholine salt from ether solution and regeneration of the free amino acid by treatment of a methanol solution of the morpholine salt with sulfur dioxide. The pure amino acid had the MP 155° to 156.5°C (corr). 

Environmentally the most important variables are pH, oxygen content and temperature of the water (Figure 1.96). In single phase conditions both high pH and additions of low levels of oxygen have been used to prevent erosion corrosion . However, because of partitioning effects between water and steam this is more difficult to achieve in two-phase flow. Although additions of morpholine or AMP (2-amino-2-methyl-propan-l-ol) have been successfully used to control pH. 

Various amines find application for pH control. The most commonly used are ammonia, morpholine, cyclohexylamine, and, more recently AMP (2-amino-2-methyl-l-propanol). The amount of each needed to produce a given pH depends upon the basicity constant, and values of this are given in Table 17.4. The volatility also influences their utility and their selection for any particular application. Like other substances, amines tend towards equilibrium concentrations in each phase of the steam/water mixture, the equilibrium being temperature dependent. Values of the distribution coefficient, Kp, are also given in Table 17.4. These factors need to be taken into account when estimating the pH attainable at any given point in a circuit so as to provide appropriate protection for each location. 

Amino,2-methyl,1-propanol (AMP), also known as Isobutanolamine (IBA), (CH3)2CNH2CH2OH, MW = 89. Available as a 95% solution (AMP-95 ) from Angus Chemical Company. Sp. gr. = 0.942. Flash point = 87 °C/188 °F (PMCC). Boiling point = 329 °F. Suitable for short to medium steam-condensate pipe runs provided the operating pressure is at least 75 psig. A safe replacement for morpholine. Reasonable thermal stability. 

Moreover, Kim and coworkers have shown that a-amino-butyrolactones can be synthesized by a related process employing the amino acid homoserine with an unprotected hydroxy functionality [31]. In a more recent publication by the same research group, morpholin-2-one derivatives of type 9-37 have been prepared (Scheme 9.6) [32]. Herein, glycolaldehyde dimer 9-32 acts as a bifunctional compound, which first reacts with the a-amino acids 9-33 to give the iminium ions 9-34,... 

Flash vacuum pyrolysis (FVP) of the 3-(iV-(pyrimidin-2-yl)imino-l-morpholino)propanoate 179 led to pyrimido-pytimidines 182 and 184, as a result of competition between thermal loss of ethanol or morpholine. The ketenimine 181, being unable to undergo cyclization, underwent [l,3]-ethoxy migration to form 183, leading to 184 (Scheme 28). The ratio of the products was studied on variation of the temperature (400, 530, and 600 °C) and the nature of the amino substiuent (NR1R2 = morpholino, pyrrolidino, N(Me)Ph ) <2004AJC577>. 

Functionalized sugars and amino acids have been used to create unique morpholine scaffolds which were further elaborated to create a second generation of morpholino derivatives following the precepts of the build/couple/pair approach [73]. 

Initially PDPs were synthesized by stepwise polycondensation of linear activated depsipeptide [93]. In 1985, Helder, Feijen and coworkers reported the synthesis of PDPs by ROP of a morpholine-2,5-dione derivative (cyclic dimer of ot-hydroxy- and a-amino acid cyclodepsipeptide, cDP) [94, 95]. The ROP method gives an alternative type of PDP by homopolymerization and also allows the copolymerization with other monomers (lactones and cyclic diesters) including LA, GA, and CL to give a wide variety of functional biodegradable materials. The synthesis of PDPs as functional biomaterials has been recently reviewed [17]. 

A solvent-free synthesis of substituted spiroindolinonaphth[2,l-fo][l,4]oxazines through condensation of 2-methylene-l,3,3-trimethylindoline derivatives with 1-nitroso-2-naphthol under microwave irradiation has been described by Fedorova and colleagues (Scheme 6.263) [453], In a typical reaction, an equimolar mixture of the two starting materials was irradiated at 65-110 °C for 15 min to produce the desired spiroindolinonaphth[2,l-fo][l,4]oxazines, which are useful as photochromic compounds. In a related procedure, addition of morpholine to the reaction mixture led to the formation of the corresponding 6 -amino-functionalized spiroindolino-naphth[2,l-fo][l,4]oxazines, which exhibit a strong hypsochromic color shift (not shown) [453]. 

Methylthiopyrido[2,3-e][ 1,2,4]triazine 41 was prepared (76KGSI140) by cyclization of 2-amino-3-hydrazinopyridine 40 with carbon disulfide followed by methylation. Oxidation of 41 with chlorine afforded the 3-methylsulfonopyridotriazine 42. Heating 41 with morpholine or pyrrolidine gave 43, whereas the reaction at 20°C gave 44. 

Compound 642, obtained by condensation of glyoxal with benzotriazole and morpholine undergoes interesting [2+3] cyclocondensation with 2-aminopyridine to give imidazo[l,2- ]pyridine 643 (Equation 15) <2003JOC4935>. Similar derivatives of piperidine and pyrrolidine are also described. 2-Amino- and 6-aminopyrimidines react similarly to give imidazo[l,2- ]- and imidazoll - pyrimidines, respectively. 

Deoxoartemisinin and carboxypropyldeoxoartimisinin have also been shown to have anti-tumour activity and, NMR studies on solution conformations have been reported <00BBR359>. One of the problems with artemisinin use is its poor water solubility characteristics. An attempt to rectify this, and to overcome stability problems associated with sodium artesunate in solution, has involved the introduction of amino group functionality as in 127 (eg. R = 0(CH2)3NR r2 where NR r2 = morpholine). The maleate salt of this compound has reasonable water solubility and aqueous solutions are stable at room temperature for an extended time. However activity against Plasmodium knowlesi in rhesus monkeys after oral administration was poorer compared with artesunic acid <00JMC1635>. 

Its chemical structure does not allow elimination of HNO, thus supporting the oxidative pathway of activation to NO, a mechanism still possible in this blocked SIN-1A derivative. The final product of the NO-release was found to be l-amino-2-cyanomorpholine (110) [106]. Its formation can be rationalized assuming that, after the oxidative NO-release, deprotonation occurs at the a-position of the morpholine, followed by migration of the cyano group and hydrolytic cleavage of the hydrazone moiety. 

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