Synthesis of 9-cis-retinoic acid and C-20-[3H3C]-9-cis-retinoic acid with high specific activity

## Abstract A selective total synthesis of [11,12‐^3^H]‐9‐__cis__‐retinoic acid 1 at a specific activity of 46 Ci/mmole is described. The alkyne 4, efficiently prepared in two steps from readily available starting materials, was partially reduced to 9,11‐di‐__cis__‐retinoic acid 3 with both deuteri

## Abstract 1‐[^13^CD~3~]‐9‐__cis__‐Retinoic acid was prepared in 8 steps from 2,6‐dimethylcyclohexanone. Alkylation of 2,6‐dimethylcyclohexanone under LiHMDS/MnBr~2~/^13^CD~3~I gave the corresponding labeled 2‐[^13^CD~3~]‐2,2,6‐trimethylcyclohexanone 4 in good yield. Further functionalization of 4

## Abstract All‐__trans__‐Retinoic acid [11,12‐^3^H(N)] was photochemically isomerized using a fluorescent source to afford a mixture of isomeric retinoic acids, from which 9‐__cis__‐retinoic acid[11,12‐^3^H(N)] was isolated by reversed‐phase HPLC. The identity of 9‐__cis__‐retinoic acid [11, 12‐^3

A method is described by which tritium-labeled alltrans retinoic acid of high specific activity (up to \(\sim 51\) \(\mathrm{Ci} / \mathrm{mmol}\) corresponding to \(85 \%\) of theoretical) is converted photolytically within a fraction of a second to a mixture of retinoic acid stereoisomers. One of

BACKGROUND. 1,25 dihydroxyvitamin D 3 (1,25D) and retinoids may play an important role in preventing progression of prostate cancer. METHODS. We examined the ability of four novel 20-epi-vitamin D 3 analogs (CB1093, KH1060, KH1266, and CB1267), either alone or in combination with 9-cis retinoic acid