[gdpawel]

Since the new millenium there has been the increasing acceptance of the concept that cancer is a very heterogenous disease and that it would be a good thing to try and individualize treatment. Oncologists are increasingly open to the concept of personalized therapy.

Driving this change has been the success of a few drugs which target specific molecular targets within cancer cells. For instance, Gleevec in a relatively rare disease called chronic myelogenous leukemia (CML). Herceptin, which targets a mutation present in some patients with breast cancer. Iressa and Tarceva, which help some patients with a mutation in lung cancer.

It has become routine to test breast cancer patients for the mutation conferring sensitivity to Herceptin. It is becoming routine to test lung cancer patients for the mutation conferring sensitivity to Iressa and Tarceva. When a tumor has certain KRAS mutations, the partially effective colon cancer drug Erbitux, is very unlikely to work.

So we've have Her2 testing for predicting Herceptin activity in breast cancer. EGFR mutation testing to predict for Iressa and Tarceva (two different flavors of the same, similar type of drug) in lung cancer. KRAS mutation to predict for Erbitux in colon cancer. Of course, this leaves out the three dozen other drugs and a myriad of drug combinations, which may often be even more effective in each of these diseases, and leaves out virtually all of the other forms of cancer.

Beyond this, there have been attempts to develop molecular-based tests to examine a broader range of chemotherapeutic drugs. New technologies for measuring the expression (biological activity) of literally hundreds to thousands of genes as part of a single test. There are two main technologies involved: RT-PCR (reverse transcription polymerase chain reaction) and DNA microarray.

Dr. Larry Weisenthal, one of the pioneers of functional profiling analysis, has described the use of RT-PCR and DNA microarrays in personalized oncology as analogous to the introduction of the personal computer. Dazzling hardware in search of a killer application. This was wonderful technology and the geekiest of people bought them and played with them, but they really didn't start to do anything for a mass market until the introduction of the first killer application, which was a spreadsheet program called Visicalc.

So what research scientists in universities and cancer centers have been doing for the past ten years is to try and figure out a way to use this dazzling technology to look for patterns of gene expression which correlate with and predict for the activity of anticancer drugs. Hundreds of millions of dollars have been spent on this effort. Objectively speaking, it's like the emperor's new clothes. So far, a qualified failure.

Academics are besides themselves over the promise of the new technology. It seems so cool that it simply must be good for something. How about in the area of identifying drugs which will work in individual patients? It has been a major bust by whatever standard you choose to apply. Objectively, if you compare and contrast the peer-reviewed medical literature supporting the use of functional profiling for personalizing drug selection versus the correspond literature supporting molecular profiling, the literature supporting functional profiling wins (big time!).

The scientist who reported the best results with molecular profiling (Dr. Anil Potti of Duke University) has recently been accused of fraud and his clinical trials have been suspended.