Cyclopentanes, construction

Cyclopentane Construction by Rhodium(M)-Mediated Intramolecular C-H Insertion... 

I 76 Cyclopentane Construction by Rhodium(ll)-Mediated Intramolecular C—H Insertion... 

Our initial objective, in this investigation, had been to design a useful chiral auxihary. We were pleased to find that naphthylborneol 31, upon optimization of the catalyst and the reaction temperature, served effectively. Until useful chiral catalysts are developed, naphthylborneol 31 will be of significant practical value for directing the absolute course of cyclopentane construction by rhodium-mediated intramolecular C-H insertion. 

Cyclopentane construction by rhodium-mediated intramolecular C-H insertion has been established as a powerful tool for the construction of carbocycHc systems, but there is much yet to be learned about the factors governing selectivity in the C-H insertion process [33]. We look forward to exciting developments in this area in years to come. 

Taber DF, Silverberg LJ, Robinson ED. Cyclopentane construction with control of side-chain configuration enantioselective synthesis of (+) brefeldin A. J. Am. Chem. Soc. 1991 113 6639 645. 

PGF2a- The cyclopentane ring of the Corey lactone (9) is the host of four contiguous stereogenic centers. Retrosynthetic simplification of 9 provides 10, a construct which is more complex than 9 Nevertheless, intermediate 10 possesses structural features that satisfy the requirement for the iodolactonization transform. The iodolactone in 10 constitutes the retron for the iodolactonization transform.11 Cleavage of the indicated bonds in 10 sacrifices two of the five stereocenters and provides unsaturated carboxylic acid... 

Stork s elegant use of a protected cyanohydrin function in the synthesis of PGF2a (2) is also noteworthy. The electron-withdrawing cyano substituent in intermediate 21 (Scheme 7) confers nucleophilic potential to C-9 and permits the construction of the saturated cyclopentane nucleus of PGF2a (2) through intramolecular alkylation. In addition, the C-9 cyanohydrin function contained within 40 is stable under the acidic conditions used to accomplish the conversion of 39 to 40 (see Scheme 7), and it thus provides suitable protection for an otherwise labile /J-hydroxy ketone. 

Conjugated chains, 14, 46 Correlation diagrams, 44, 50 Cyclobutadiene, 171 Cyclobutane, 47, 222 orbital ordering, 26 through-space interactions, 26 Walsh orbitals, 27 Cyclobutene, 200 Cyclohexane, 278 Cyclohexene (half-boat), 274 Cyclopen tadiene, 225 Cvclopen tadienone, 269 Cyclopentadienyl anion, 237 Cyclopentane, 254 Cyclopen ten e, 241 Cyclopropane, 41, 47, 153 construction of orbitals, 19, 22 Walsh orbitals, 22, 36, 37 Cyclopropanone, 48, 197 bond lengths, 38 Cyclopropen e, 49, 132 reactivity, 40... 

The ring templates can be further used to construct larger, multicyclic systems as illustrated in Fig. 7.8. For norbornane, two fitting conformahons of cyclopentane in the envelope conformation can be joined in order to construct the complete 3D structure of norbornane. In this case, this is the only low-energy conformahon known for norbornane due to its rigidity. 

Construction of the cyclopentane ring was accomplished by utilization of Trosf s Pd-mediated diastereoselective [3+2] trimethylenemethane (TMM) cycloaddition [4] on the cinnamate 5 having an Evans type chiral auxiliary [4b], The resulting diastereomeric mixture (3 1 at best) of 7a and 7b was separated by careful silica gel column chromatography (7a is less polar than 7b under normal phase). Puri-... 

Compound 1 was the first cyclopentane-based NK-1 receptor antagonist development candidate at Merck. It contains five stereocenters a central core possessing three contiguous all-trans stereocenters, a pendent bis(trifluoromethyl)-benzyHc ether, and a nipecotic acid moiety (Figure 7.1). Key to the successful preparation of 1 was construction of the trans, trans-cyclopentyl core and installation of the unsymmetrical secondary-secondary (sec-sec) ether. The preparation of 1 is the focus of this chapter. 

The use of rhodium(II) acetate in carbenoid chemistry has also been extended to promoting intramolecular C/H insertion reactions of ketocarbenoids 277,280,280 ,). From the a-diazo-P-ketoester 305, highly functionalized cyclopentane 306 could thus be constructed in acceptable yields by regiospecific insertion into an unactivated... 

Group contribution method of Andersen, Beyer, and Watson [51,52] In this method, a given compound is constructed from abase group (methane, cyclopentane, benzene, naphthalene, methylamine, dimethylamine, trimethylamine, or formamide) with known enthalpies of formation, which is then modified by appropriate substitutions to yield the desired molecule. 

Cycloisomerization represents another approach for the construction of cyclic compounds from acyclic substrates, with iridium complexes functioning as efficient catalysts. The reaction of enynes has been widely studied for example, Chatani et al. reported the transformation of 1,6-enynes into 1-vinylcyclopentenes using [lrCl(CO)3]n (Scheme 11.26) [39]. In contrast, when 1,6-enynes were submitted in the presence of [lrCl(cod)]2 and AcOH, cyclopentanes with two exo-olefin moieties were obtained (Scheme 11.27) [39]. Interestingly, however, when the Ir-DPPF complex was used, the geometry of olefinic moiety in the product was opposite (Scheme 11.28) [17]. The Ir-catalyzed cycloisomerization was efficiently utilized in a tandem reaction along with a Cu(l)-catalyzed three-component coupling, Diels-Alder reaction, and dehydrogenation for the synthesis of polycyclic pyrroles [40]. 

Intermolecular PKR is not widely applied. Krafft and co-workers reported the synthesis of asteriscanolide. In their approach, regioslective intermolecular PKR with propene is used for the construction of the cyclopentane backbone of the target molecule (Equation (42)). ... 

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