Racemic form

Borneol and isoboineol are respectively the endo and exo forms of the alcohol. Borneol can be prepared by reduction of camphor inactive borneol is also obtained by the acid hydration of pinene or camphene. Borneol has a smell like camphor. The m.p. of the optically active forms is 208-5 C but the racemic form has m.p. 210-5 C. Oxidized to camphor, dehydrated to camphene. 

The other tetritols were formerly called d-and /-erythritol, but have been renamed L-and D-threitol respectively. A racemic form can also be prepared,... 

A dicyclic monoterpene, the ( + )-form of which is found in oil of savin and many other essentia oils. The (—)- and racemic forms occur occasionally in nature. 

Atropiae (41), isolated from the deadly nightshade Airopa belladonna L.) is the racemic form, as isolated, of (—)-hyoscyamine [which is not isolated, of course, from the same plant but is typically found ia solanaceous plants such as henbane (HyosQiamus mgerl. )]. Atropiae is used to dilate the pupil of the eye ia ocular inflammations and is available both as a parasympatholytic agent for relaxation of the intestinal tract and to suppress secretions of the saUvary, gastric, and respiratory tracts. In conjunction with other agents it is used as part of an antidote mixture for organophosphorus poisons (see Chemicals in war). 

In perfumery bisabolol functions as a fixative. The racemic form is manufactured by the acid-catalyzed cyclization of nerohdol (193). 

The racemic form of the unsubstituted nucleus (1, X = CH2) was synthesized by several groups (32—34) prior to the disclosure of the natural material. One reaction path involved an azetidinone (21) where R = CH2OH or CH=CH2 converted to the corresponding phosphorane (22) where R = o-NO.-C,H, when R = CH.OH and R = COCH, when R=CH=CH.. 

The presence of asymmetric C atoms in a molecule may, of course, be indicated by diastereotopic shifts and absolute configurations may, as already shown, be determined empirically by comparison of diastereotopic shifts However, enantiomers are not differentiated in the NMR spectrum. The spectrum gives no indication as to whether a chiral compound exists in a racemic form or as a pure enantiomer. 

The subject was then fully investigated by Pyman, who found that the products obtained depended partly on the material started with and partly on the conditions of the experiment. Thus under his conditions, Z-canadine methohydroxide when dried in vacuo gave rise to three anhydro-bases, a and b optically inactive, and c optically active whilst the methohydroxide of the dZ-base formed only two, a and Z , but the proportion of b formed in this instance was equal to the amount of b and c together in the case of the Z-base (canadine). For this and other reasons b was regarded as the racemic form of c and, like it, is represented by F (R = Me),... 

Two pieces of chemical evidence support the three-membered ring formulation. The bifunctional oxazirane prepared from glyoxal, tert-butylamine, and peracetic acid (6) can be obtained in two crystalline isomeric forms. According to the three-membered ring formula there should be two asymmetric carbon atoms which should allow the existence of meso and racemic forms. A partial optical resolution was carried out with 2-7i-propyl-3-methyl-3-isobutyloxazirane. Brucine was oxidized to the N-oxide with excess of the oxazirane. It was found that the unused oxazirane was optically active. 

R = H, R =Br, R" =Et) was prepared by cyclization of aroylacetate 314 (R = H, R =Br, r2 = H, X = F) (OOMIPIO). 9,10-Difluoro-3(5)-methyl-7-oxo-7//-pyrido[l,2,3- /e]-l,4-benzoxazine-6-carboxylic acid and its racemic form were prepared in the reaction of ethyl 2-(2,3,4,5-tetrafluorobenzoyl)-2-ethoxymethyleneacetate and (R)- or (i ,5)-2-aminopropanol and subsequent hydrolysis of the ring closed tricyclic esters (98MI45). Cyclization of ethyl 2-(2,3-difluoro-5-iodobenzoyl)-2-[A-(2-hydroxyethyl)aminomethylene]acetate 315 in the presence of K2CO3 in DMF at 95 °C for 3.5 h yielded 9-iodo-7-oxo-2,3-dihydro-7//-pyrido[l,2,3- /e]-l,4-benzoxazine-6-carboxylate (01MIP2). 

A potenti illy useful approach to the marine ilkaloid papiiairune based on INOC strategy is proposed as shown m Scheme 8.21. In fact, a Rruir-hydrindane intermediate has been synthe-SLzed in racemic form using a model sequence ofreacdons involving an itnle oxide cycloaddidon as a key step fEq. 8.69. ... 

The derivatives of fenchene are not in most cases crystalline, but the optically active a-fenchenes form a dibromide, C (,H,jBr.2, which crystallises well, and melts at 87° to 88°. The racemic form melts at 62°. 

The following are the characters of various derivatives of the active and the racemic forms —... 

Dipentene is the racemic form of the optically active d-limonene and 1-limonene, terpenes which are found to a very large extent in essential oils. Since an equal mixture of d-iimonene and f-limonene is dipentene, it is obvious that whenever optically active limonene is found with a rotation below the maximum, it must contain dipentene. Mixtures of equal quantities of a compound of the optically active limonenes are identical with the corresponding compound prepared from dipentene. It is therefore obvious that the nomenclature is unfortunate and dipentene should be termed i-limonene. 

The weight of chemical evidence is strongly in favour of dipentene, being actually i-limonene, that is, merely the racemic form of the active limonenes. Semmler has suggested, however, that a slight difference may exist between the constitutions of these terpenes. ... 

The hydrochloride addition salt of the above reaction product was prepared in customary fashion, that is, by reaction with hydrochloric acid, followed by fractional crystallization from a mixture of alcohol and ether. The two possible racemic forms were obtained thereby. The difficultly soluble racemate had a melting point of 169° to 170°C and the more readily soluble racemate had a boiling point of 145° to 148°C. 

Plouvier then prepared the previously unknown racemic form of proto-quercitol by mixing equal weights of the two enantiomers. The melting point (237°C.) of the mixture was not depressed, and its (presumably solid state) infrared spectrum reportedly (36) was identical with that of either active form. It thus appears that DL-proto-quercitol exists as a solid solution, not a racemic compound or conglomerate. 

The pure, crystalline (— )-proto-quercitol (13) which was isolated had an infrared spectrum identical with that of authentic ( + )-proto-quercitol, and its optical rotation was equal and opposite. Further characterization and preparation of the racemic form, by mixing the enantiomers, is described elsewhere (30). 

Amino acids can be synthesized in racemic form by several methods, including ammonolysis of an a-bromo acid, alkylation of diethyl acetamido-malonate, and reductive amination of an cv-keto acid. Alternatively, an enantio-selective synthesis of amino acids can be carried out using a chiral hydrogenation catalyst. 

A key transformation in Corey s prostaglandin synthesis is a Diels-Alder reaction between a 5-(alkoxymethyl)-l,3-cyclopenta-diene and a ketene equivalent such as 2-chloroacrylonitrile (16). As we have already witnessed in Scheme 3, it is possible to bring about a smooth [4+2] cycloaddition reaction between 5-substituted cyclopentadiene 15 and 2-chloroacrylonitrile (16) to give racemic 14 as a mixture of epimeric chloronitriles. Under these conditions, the diastereomeric chloronitriles are both produced in racemic form because one enantiotopic face of dienophile 16 will participate in a Diels-Alder reaction with the same facility as the other enantiotopic face. In subsequent work, Corey s group demonstrated that racemic hydroxy acid 11, derived in three steps from racemic 14 (see Scheme 3), could be resolved in a classical fashion with (+)-ephe-... 

Johnson s classic synthesis of progesterone (1) commences with the reaction of 2-methacrolein (22) with the Grignard reagent derived from l-bromo-3-pentyne to give ally lie alcohol 20 (see Scheme 3a). It is inconsequential that 20 is produced in racemic form because treatment of 20 with triethyl orthoacetate and a catalytic amount of propionic acid at 138 °C furnishes 18 in an overall yield of 55 % through a process that sacrifices the stereogenic center created in the carbonyl addition reaction. In the presence of propionic acid, allylic alcohol 20 and triethyl orthoacetate combine to give... 

Scheme 8 presents the sequence of reactions that led to the synthesis of the B-ring of vitamin B12 by the Eschenmoser group. An important virtue of the Diels-Alder reaction is that it is a stereospecific process wherein relative stereochemical relationships present in the diene and/or the dienophile are preserved throughout the course of the reaction.8 Thus, when the doubly activated dienophile 12 (Scheme 8) is exposed to butadiene 11 in the presence of stannic chloride, a stereospecific reaction takes place to give compound 27 in racemic form. As expected, the trans relationship between... 

In 1980, a Merck group disclosed the results of a model study which amply demonstrated the efficiency with which the strained bicyclic ring system of thienamycin can be constructed by the carbene insertion cyclization strategy.12 Armed with this important precedent, Merck s process division developed and reported, in the same year, an alternative route to carbene precursor 4.13 Although this alternative approach suffers from the fact that it provides key intermediate 4, and ultimately thienamycin, in racemic form, it is very practical and is amenable to commercial scale production. The details of this interesting route are presented in Schemes 4-6. 

For additional syntheses of thienamycin in both optically active and racemic forms, see (a) Ponsford,... 

Schemes 28 and 29 illustrate Curran s synthesis of ( )-hirsutene [( )-1]. Luche reduction58 of 2-methylcyclopentenone (137), followed by acetylation of the resulting allylic alcohol, furnishes allylic acetate 138. Although only one allylic acetate stereoisomer is illustrated in Scheme 28, compound 138 is, of course, produced in racemic form. By way of the powerful Ireland ester enolate Clai-sen rearrangement,59 compound 138 can be transformed to y,S-unsaturated tm-butyldimethylsilyl ester 140 via the silyl ketene acetal intermediate 139. In 140, the silyl ester function and the methyl-substituted ring double bond occupy neighboring regions of space, a circumstance that favors a phenylselenolactonization reac-...

The synthesis of enantiomerically enriched vinyl carbamates is described in Section 1.3.3.3.8.2.2. by applying this procedure, these were also obtained efficiently in the racemic form. Some further examples of substituted carbamates are collected below ... 

In a chiral aldehyde or a chiral ketone, the carbonyl faces are diastereotopic. Thus, the addition of an enolate leads to the formation of at least one stereogenic center. An effective transfer of chirality from the stereogenic center to the diastereoface is highly desirable. In most cases of diastereoface selection of this type, the chiral aldehyde or ketone was used in the racemic form, especially in early investigations. However, from the point of view of an HPC synthesis, it is indispensable to use enantiomerically pure carbonyl compounds. Therefore, this section emphasizes those aldol reactions which are performed with enantiomerically pure aldehydes. 

Chrysanthemumic acid may exist in four stereoisomers, because of the two asymmetric carbon atoms in the cyclopropane ring. The natural acid has the D-trans configuration and this has been shown to be more insecticidally active than any of the other isomers or the racemic form. Harper et al, (4,18) have synthesized, separated, and optically resolved all of the isomers of this acid. 

Chrysanthemum dicarboxylic acid or pyrethric acid may exist in eight stereoisomers, owing to the trans or cis configuration on the side chain of the double bond as well as that of the cyclopropane. The natural acid has been shown to be the trans-trans acid. As in the case of the chrysanthemum monocarboxylic acid, the naturally occurring configuration is more insecticidally active than the racemic form or any of the three isomers synthesized. 

Zirconocene dichloride 121 derived from (l-phenylethyl)cyclopentadienyl ligand is formed as a mixture of diastereomers from which the racemic form can be isolated by fractional crystallization. This complex was studied by X-ray diffraction methods and revealed a virtually chiral C2-symmetrical conformation in which the chiral ring-substituents are arranged in a synclinal position relative to the five-membered ring. It was proposed that this conformation is preserved in solution. Using 121 as catalyst the influence of double stereodifferentiation during isospecific polymerization of propylene (Eq. 32) was demonstrated for the first time [142],... 

The search for the racemic form of 15, prepared by allylic cyclopropanation of farnesyl diazoacetate 14, prompted the use of Rh2(OAc)4 for this process. But, instead of 15, addition occurred to the terminal double bond exclusively and in high yield (Eq. 6) [65]. This example initiated studies that have demonstrated the generality of the process [66-68] and its suitability for asymmetric cyclopropanation [69]. Since carbon-hydrogen insertion is in competition with addition, only the most reactive carboxamidate-ligated catalysts effect macrocyclic cyclopropanation [70] (Eq. 7), and CuPF6/bis-oxazoline 28 generally produces the highest level of enantiocontrol. 

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