Lactam derivatives 3-lactams

If a bromomethyl- or vinyl-substituted cyclopropane carbon atom bears a hydroxy group, the homoallyiic rearrangement leads preferentially to cyclobutanone derivatives (J. Sa-laun, 1974). Addition of amines to cydopropanone (N. J. Turro, 1966) yields S-lactams after successive treatment with tert-butyl hypochlorite and silver(I) salts (H.H. Wasserman, 1975). For intramolecular cyclopropane formation see section 1.16. 

The conversion of carboxylic acid derivatives (halides, esters and lactones, tertiary amides and lactams, nitriles) into aldehydes can be achieved with bulky aluminum hydrides (e.g. DIBAL = diisobutylaluminum hydride, lithium trialkoxyalanates). Simple addition of three equivalents of an alcohol to LiAlH, in THF solution produces those deactivated and selective reagents, e.g. lithium triisopropoxyalanate, LiAlH(OPr )j (J. Malek, 1972). 

In synthetic target molecules esters, lactones, amides, and lactams are the most common carboxylic acid derivatives. In order to synthesize them from carboxylic acids one has generally to produce an activated acid derivative, and an enormous variety of activating reagents is known, mostly developed for peptide syntheses (M. Bodanszky, 1976). In actual syntheses of complex esters and amides, however, only a small selection of these remedies is used, and we shall mention only generally applicable methods. The classic means of activating carboxyl groups arc the acyl azide method of Curtius and the acyl chloride method of Emil Fischer. 

A very mild and efficient synthesis of N-substituted -lactams uses the Mitsunobu reaction (see section 2.6.2) for the ring closure of seryl dipeptides protected at the terminal N as 4,5-diphenyloxazol-2(3f/)-one ( Ox ) derivatives (see section 2,6.3)... 

The cyclic carbonate of benzoin (4,5-diphenyl-l,3-dioxol-2-one, prepared from benzoin and phosgene) blocks both hydrogen atoms of primary amines after dehydration acid stable, easily crystallizable Sheehan oxazolinones are formed, which are also called Ox derivatives. The amine is quantitatively deblocked by catalytic hydrogenation in the presence of 1 equiv. of aqueous acid (J.C Sheehan, 1972, 1973 M.J. Miller, 1983). An intelligent application to syntheses of acid labile -lactams is given in the previous section (p. 161). 

First the protected oligopeptide is coupled with polymer-bound nitrophenol by DCC. N"-Deblocking leads then to simultaneous cycliiation and detachment of the product from the polymer (M. Fridkin, 1965). Recent work indicates that high dilution in liquid-phase cycli-zation is only necessary, if the cyclization reaction is sterically hindered. Working at low temperatures and moderate dilution with moderately activated acid derivatives is the method of choice for the formation of macrocyclic lactams (R.F. Nutt, 1980). 

The coupling of the enol triflate 703 with the vinylstannane 704[397] has been applied to the synthesis of glycinoeclepin[576]. The introduction of a (Z)-propenyl group in the / -lactam derivative 705 proceeds by use of tri-2-furylphosphine[577]. However, later a smooth reaction to give the propenyl-iactam in 82% yield was achieved simply by treating with Pd(OAc)2 in NMP or CH2CI2 for 3-5 min without addition of LiCI and the phosphine ligand[578]. 

In addition to alcohols, some other nucleophiles such as amines and carbon nucleophiles can be used to trap the acylpalladium intermediates. The o-viny-lidene-/j-lactam 30 is prepared by the carbonylation of the 4-benzylamino-2-alkynyl methyl carbonate derivative 29[16]. The reaction proceeds using TMPP, a cyclic phosphite, as a ligand. When the amino group is protected as the p-toluenesulfonamide, the reaction proceeds in the presence of potassium carbonate, and the f>-alkynyl-/J-lactam 31 is obtained by the isomerization of the allenyl (vinylidene) group to the less strained alkyne. 

ANTTBIOTTCS - BETA-LACTAMS - PENICILLINS AND OTTiERS] (Vol 3) -pivaloyloxymethyl ester derivative [CARBOXYLIC ACIDS - TRIALKYLACETIC ACIDS] (Vol 5)... 

Synthetic utility of stereoselective alkylations in natural product chemistry is exemplified by the preparation of optically active 2-arylglycine esters (38). Chirally specific a-amino acids with methoxyaryl groups attached to the a-carbon were prepared by reaction of the dimethyl ether of a chiral bis-lactam derivative with methoxy arenes. Using SnCl as the Lewis acid, enantioselectivities ranging from 65 to 95% were obtained. 

Table 15 gives a sampling of other pharmaceuticals derived from hydraziae. Cefazolin, a thiadiazole tetrazole derivative, is one of the most widely used antibacterial dmgs in U.S. hospitals (see Antibiotics, P-LACTAMs). Procarbazine, an antineoplastic, is a monomethyUiydrazine derivative (220). Fluconazole has shown some promise in the treatment of AIDS-related fungal infections. Carbidopa is employed in the treatment of Parkinson s disease. FurazoHdone is a veterinarian antibacterial. 

Oxidative cleavage of P-aminoacyl complexes can yield P-amino acid derivatives (320,321). The rhodium(I)-catalyzed carbonylation of substituted aziridines leads to P-lactams, presumably also via a P-aminoacyl—metal acycHc compound as intermediate. The substituent in the aziridine must have 7T or electrons for coordination with the rhodium (322,323). 

The number of naturally occurring antibiotics increased from about 30 known in 1945, to 150 in 1949, 450 in 1953, 1200 in 1960, and to 10,000 by 1990 (1,9). Table 1 Hsts the years of historical importance to the development of antibiotics used for treatment in humans. Most of the antibiotics introduced since the 1970s have been derived from synthetic modifications of the P-lactam antibiotics (qv). 

PMVEMA, supphed as a white, fluffy powder, is soluble in ketones, esters, pyridine, lactams, and aldehydes, and insoluble in aUphatic, aromatic, or halogenated hydrocarbons, as well as in ethyl ether and nitroparaffins. When the copolymer dissolves in water or alcohols, the anhydride group is cleaved, forming the polymers in free acid form or the half-esters of the corresponding alcohol, respectively. Table 7 illustrates the commercially available alternating copolymers and derivatives. 

In the period up to 1970 most P-lactam research was concerned with the penicillin and cephalosporin group of antibiotics (1). Since that time, however, a wide variety of new mono- and bicychc P-lactam stmctures have been described. The carbapenems, characterized by the presence of the bicychc ting systems (1, X = CH2) originated from natural sources the penem ring (1, X = S) and its derivatives are the products of the chemical synthetic approach to new antibiotics. The chemical names are 7-oxo-(R)-l-a2abicyclo[3.2.0]hept-2-ene-2-carboxyhc acid [78854-41-8] CyH NO, and 7-oxo-(R)-4-thia-l-a2abicyclo[3.2.0]hept-2-ene-2-carboxylic a.cid [69126-94-9], C H NO S, respectively. 

In the case of thienamycin (Fig. lb) the absolute stereochemistry at C-5 was unambiguously deterrnined from the ene-lactam (16). The resultant (R)-aspartic acid (17) demonstrated that the absolute stereochemistry at C-5 of thienamycin is (R), corresponding to that found in the C-5 position of both penicillins and cephalosporins. Confirmation of the stereochemical assignments in both thienamycin (2) and the olivanic acid MM 13902 (3, n = 0) has been confirmed by x-ray crystallography (19,21,22). The stmctural determination of the nonsulfated derivatives from S. olivaceus (23), PS-5 (5) (5), the carpetimycins (6), and the asparenomycins (7) followed a similar pattern. 

A second method makes use of the lactone (31) from acetone dicarboxylate (40) and for which a synthesis from (—)-carvone has been reported (41). Displacement of chlorine from the 6-aminopenici11anic acid (6-APA) derived P-lactam (32) by (33) illustrates yet another approach to the dia2oketone (28) (42). 

Other approaches to (36) make use of (37, R = CH ) and reaction with a tributylstannyl allene (60) or 3-siloxypentadiene (61). A chemicoen2ymatic synthesis for both thienamycia (2) and 1 -methyl analogues starts from the chiral monoester (38), derived by enzymatic hydrolysis of the dimethyl ester, and proceeding by way of the P-lactam (39, R = H or CH ) (62,63). (3)-Methyl-3-hydroxy-2-methylpropanoate [80657-57-4] (40), C H qO, has also been used as starting material for (36) (64), whereas 1,3-dipolar cycloaddition of a chiral nitrone with a crotonate ester affords the oxa2ohdine (41) which again can be converted to a suitable P-lactam precursor (65). 

Active site directed P-lactam-derived inhibitors have a competitive component of inhibition, but once in the active site they form an acyl en2yme species which follows one or more of the pathways outlined in Figure 1. Compounds that foUow Route C and form a transiendy inhibited en2yme species and are subsequendy hydroly2ed to products have been termed inhibitory substrates or competitive substrates. Inhibitors that give irreversibly inactivated P-lactamase (Route A) are called suicide inactivators or irreversible inhibitors. The term progressive inhibitor has also been used. An excellent review has appeared on inhibitor interactions with P-lactamases (28). 

Compounds of type (6), (7), (8) and (9), although not strictly derivatives of a saturated heterocyclic system, will be discussed in this chapter. Our discussion of (7) begins and ends here, since oxiranethiones or a-thiolactones are apparently unknown (80AG(E)276). Little is known of (8) and its derivatives, oxiranimines or a-iminolactams. They have been postulated as intermediates in the thermal decomposition of aziridinones (a-lactams) (Scheme 1) but there is no well-established case of the isolation of an oxiranimine (80AG(E)276). 

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