The Weizmann Institute of Science team that developed the computer has published the results in Nature. Headed by Professor Ehud Shapiro of the Departments of Computer Sciences and Applied Mathematics, and Biological Chemistry, the team included research students Yaakov Benenson, Binyamin Gil, Uri Ben-Dor and Dr. Rivka Adar. Ehud Shapiro presented the team's findings at the Brussels symposium "Life, a Nobel Story" in which Nobel Laureates and others addressed the future of the life sciences.
As in previous biological computers produced in Professor Shapiro's lab, input, output and "software" are all composed of DNA, the material of genes, while DNA-manipulating enzymes are used as "hardware". The newest version's input apparatus is designed to assess concentrations of specific RNA molecules, which may be overproduced or underproduced, depending on the type of cancer. Using pre-programmed medical knowledge, the computer then makes its diagnosis based on the detected RNA levels. In response to a cancer diagnosis, the output unit of the computer can initiate the controlled release of a single-stranded DNA molecule that is known to interfere with the cancer cell's activities, causing it to self-destruct.
In one series of test-tube experiments, the team programmed the computer to identify RNA molecules that indicate the presence of prostate cancer and, following a correct diagnosis, to release the short DNA strands designed to kill cancer cells. Similarly, they were able to identify, in the test tube, the signs of one form of lung cancer. One day in the future, they hope to create a "doctor in a cell", which will be able to operate inside a living body, spot disease and apply the necessary treatment before external symptoms even appear.
The original version of the biomolecular computer, also created in a test tube, capable of performing simple mathematical calculations, was introduced by Ehud Shapiro and colleagues in 2001. An improved system, which uses its input DNA molecule as its sole source of energy, was reported in 2003 and was listed in the 2004 Guinness Book of World Records as the smallest biological computing device.
Ehud Shapiro stated: "It is clear that the road to realizing our vision is a long one; it may take decades before such a system operating inside the human body becomes reality. Nevertheless, only two years ago we predicted that it would take another 10 years to reach the point we have reached today." Professor Ehud Shapiro's research is supported by the M.D. Moross Institute for Cancer Research, the Samuel R. Dweck Foundation, the Dolfi and Lola Ebner Center for Biomedical Research, the Benjamin and Seema Pulier Charitable Foundation, and the Robert Rees Fund for Applied Research.
The Weizmann Institute of Science in Israel, is one of the world's top-ranking multi-disciplinary research institutions. Noted for its wide-ranging exploration of the natural and exact sciences, the Institute is home to 2500 scientists, students, technicians and supporting staff. Institute research efforts include the search for new ways of fighting disease and hunger, examining leading questions in mathematics and computer science, probing the physics of matter and the universe, creating novel materials and developing new strategies for protecting the environment.