Preclinical assessment of JNJ-26854165 (Serdemetan), a novel tryptamine compound with radiosensitizing activity in vitro and in tumor xenografts.

Serdemetan (JNJ-26854165) is a novel tryptamine compound with antiproliferative activity in various p53 wild-type (WT) tumor cell lines. We investigated its potential as radiosensitizer using four human cancer cell lines: H460, A549, p53-WT-HCT116, and p53-null-HCT116. Serdemetan inhibited clonogenic survival in all cell lines, but in a lower extent in p53-null-HCT116. In the combination studies, Serdemetan treatment at 0.25µM in H460 and at 5µM in A549 cells resulted in a sensitivity-enhancement ratio of 1.18 and 1.36, respectively. At 2Gy, surviving fractions were 0.72 and 0.97 for p53-WT HCT116 and p53-null cells exposed to 0.5µM of Serdemetan, respectively (p<0.05). Radiosensitization of H460 and A549 cells was associated with G2/M cell cycle arrest and with an increased expression of p53 and p21. In vivo, Serdemetan caused a greater than additive increase in tumor growth delay. The dose enhancement factor was 1.9 and 1.6 for H460 and A549 tumors, respectively. Serdemetan inhibited proliferation, capillary tube formation and migration of HMEC-1 cells. These effects were more marked concurrently with irradiation. These results in tumor and endothelial cells suggest that Serdemetan has potential as a radiosensitizer. Further investigations are warranted with regard to the molecular mechanisms underlying its actions and its dependency regarding p53 status.

Microwave assisted medicinal chemistry.

Microwave irradiation has been used to enhance organic reactions since the mid 80's, its use within the field of medicinal chemistry is not so widely evident in the literature. The present review highlights the use of microwave chemistry as an important tool for the fast development of structure activity relationship in several programs related to various therapeutic areas.

Applications of the combination of microwave and parallel synthesis in medicinal chemistry.

The blending of microwave heating and parallel chemistry is a logical consequence of the significant rate enhancement and higher product yield afforded by microwave technology and the increase in productivity afforded by combinatorial chemistry. For this reason, this combination has become increasingly popular in the organic chemistry community. The current review highlights the application of this approach as a way to increase the rate of analogue synthesis in medicinal chemistry.