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Correspondence re: M. Follen et al., A Randomized Clinical Trial of 4-Hydroxyphenylretinamide for High-Grade Squamous Intraepithelial Lesions of the Cervix. Clin. Cancer Res., 7: 3356–3365, 2001¹

Department of Experimental Oncology, Istituto Nazionale Tumori, Via Venezian 1, 20133 Milan, Italy

Clinical trials of 4-HPR² in several organ sites are ongoing, and the paper by Follen et al. (1) reports the results of a trial in patients with high-grade squamous intraepithelial lesions of the cervix. 4-HPR, administered for 6 months at 200 mg/day with a 3-day/month drug holiday was not active compared with placebo. I appreciated the decision of the authors to monitor the drug plasma levels, and I read with interest their hypothesis that the lack of activity was attributable to low drug serum levels. As pointed out in the discussion section, the 4-HPR concentrations effective in suppressing the in vitro growth of tumor cells range from 1 to 10 µM, which correspond to 400–4000 ng/ml, whereas the mean serum levels of 4-HPR in the participants in the trial were 34.8 ng/ml. We found, in patients participating in a breast prevention trial and treated with 4-HPR at the same dose and with the same schedule, 4-HPR plasma levels of 350 ng/ml (2 ,3) , which are concentrations 10 times higher.

To understand the reasons for such differences and to provide information for 4-HPR monitoring in future trials, we reviewed the published data on similar analyses. Table 1 reports the levels of 4-HPR and of its metabolite 4-MPR found in plasma or serum of subjects participating in six different clinical trials in which the drug was administered at 200 mg/day with a 3-day/month drug holiday and in which blood samples for drug measurement were collected at a single point. Table 1 also reports the results of a study by Doose et al. (4) on 4-HPR bioavailability that clearly showed the influence of meals and meal composition on 4-HPR plasma levels. In the study, at variance with the clinical trials, the dose of 4-HPR was 300 mg, and drug levels were measured at different intervals after a single drug administration. Doose et al. showed that administration of 4-HPR after a high-fat breakfast increased 4-HPR peak levels three times (from 198 to 596 ng/ml) compared with administration of the same dose in the fasting state. They also showed that a high-fat meal caused the highest increase in 4-HPR absorption compared with high-protein and high-carbohydrate meals.

In conclusion, from the analysis of the results on 4-HPR levels measured in different clinical trials, we suggest that the observed differences might be attributable to differences in meal composition and in the interval between drug intake and blood sampling. Therefore, we draw attention to the importance of the modalities of drug administration and of meal composition in 4-HPR bioavailability, and of the interval from drug intake in monitoring drug levels. From this analysis we also conclude that the highest 4-HPR plasma concentrations achieved with the 200-mg daily dose are 1 µM, i.e., the least effective in suppressing tumor cell growth in vitro. For this reason we agree with the conclusion of the authors that higher doses should be tested in future clinical trials. The suggestion seems reasonable taking into account that 4-HPR was not toxic at 200 mg/day and is supported by the fact that high-dose 4-HPR was more effective than low dose in preventing mammary tumors in rats (9) .

ACKNOWLEDGMENTS

We thank Dr. Carmen Pollini for useful discussion about the letter and Elena Cavadini for excellent technical help in all my studies on 4-HPR plasma levels.

FOOTNOTES

¹ Supported in part by a grant from the Associazione Italiana Ricerca sul Cancro, Milan, Italy.

² The abbreviations used are: 4-HPR, N-(4-hydroxyphenyl)retinamide; 4-MPR, N-(4-methoxyphenyl)retinamide.

Received 12/19/01; accepted 2/ 1/02.

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