1997 Teva Founders Prize To Weizmann Institute's Prof. David Wallach

English
REHOVOT, Israel - March 22, 1998 - Prof. David Wallach of the Weizmann Institute of Science's Biological Chemistry Department has been awarded the 1997 Teva Founders Prize.
 
Prof. David Wallach
 
Wallach was honored for his pioneering research on the transmission of signals in cells. His studies for the first time provided a clear picture of the way such signaling controls mechanisms leading to cell death rather than to processes related to the life of the cell. Excessive cell death is a distinguishing feature of autoimmune diseases such as multiple sclerosis and juvenile diabetes, while insufficient cell death leads to uncontrolled tissue growth and can result in cancer.
 
Prof. Wallach has spent some 14 years studying the tumor necrosis factor, or TNF, a molecule that plays a key role in the regulation of cell death. TNF is an effective killer of diseased cells but it is sometimes produced in excess, leading to pathologies in various parts of the body.
 
Wallach was one of the first researchers to isolate this molecule. He also discovered the TNF receptors, including their soluble forms that block TNF action - a finding that has opened the way to developing treatments for TNF-associated diseases.
 
More recently, he won widespread acclaim in the scientific community for clarifying the mechanisms by which TNF transmits death-inducing signals to cells. In 1996, the journal Science named his research on this topic the runner-up for the "Breakthrough of the Year."
 
The Teva Prize was awarded to Prof. Wallach at a festive ceremony in Jerusalem's Binyanei Ha'uma convention center on February 23.
 
At the same ceremony, Weizmann Institute Vice President Prof. Yoram Groner of the Molecular Genetics Department received the Teva Founders Prize for 1996. Groner was cited for his pioneering studies into the genetic and molecular basis of Down syndrome and for playing a leading role in this field worldwide. He shared the 1996 award with Prof. Yossi Shilo of Tel Aviv University.

The Weizmann Institute of Science is a major center of scientific research and graduate study located in Rehovot, Israel.
Prof. David Wallach
English

Belgian Queen to Present the Award

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Weizmann Institute's Prof. Michael Sela First Israeli Winner of Interbrew-Baillet Latour Health Prize


REHOVOT, Israel - April 13, 1997 - Prof. Michael Sela of the Weizmann Institute of Science has been awarded the 1997 Interbrew-Baillet Latour Health Prize of Belgium.
 
 
Prof. Michael Sela

The prize, which is given every two years for scientific research with practical applications, will be presented to Sela by Belgium's Queen Paola at a ceremony in Brussels on June 17. It is the first time an Israeli scientist has been named a recipient of the award, which involves prize money of 6 million Belgian francs (about US$175,000).

Sela, Deputy Chairman of the Institute's Board of Governors and a former President of the Institute, is being awarded the prize for his pioneering work on synthetic peptides, or protein fragments, which has contributed to greater understanding and control of the immune system.

He is known in the scientific world for his seminal work in immunology, particularly for his research on synthetic antigens, molecules that trigger the immune system to attack. These efforts have led to the discovery of the genetic control of the immune response, as well as to the design of vaccines based on synthetic molecules.

One of Sela's major research efforts culminated recently in the approval by the US Food and Drug Administration of copolymer-1 (Copaxone), a new drug for relapsing-remitting multiple sclerosis. Copolymer-1 was originally synthesized and developed by Sela with the Institute's Prof. Ruth Arnon and Dr. Dvora Teitelbaum.

Sela, who has worked at the Weizmann Institute since 1950, has won numerous prizes and awards for his research, among them the Israel Prize in Natural Sciences (1959); the Rothschild Prize (1968); Germany's Emil von Behring Prize (1973); Canada's Gairdner Foundation International Award (1980); France's Institut de la Vie Prize (1984); Germany's Commander's Cross of the Order of Merit Award (1986); France's Officier de l'Ordre de la Legion d'Honneur (1987); and UNESCO's Albert Einstein Golden Medal (1995).

In February last year, Sela became the first non-German to be given the Max Planck Society's highest award, the Harnack Medal, which was first awarded in 1925 and has since been presented to 25 eminent German scientists and officials.

Sela is a member of scientific bodies in Israel and abroad, including the U.S.'s National Academy of Sciences, the American Academy of Arts and Sciences, the Pontifical Academy of Sciences, the French Academy of Sciences, the Russian Academy of Sciences, Germany's Leopoldina Academy of Natural Sciences, the Italian Academy of Sciences and the Romanian Academy of Sciences.

He also holds honorary doctorates from academic institutions around the world and is an honorary member of many major scientific bodies. He is an Institute Professor in the Weizmann Institute's Immunology Department and holds the W. Garfield Weston Chair of Immunology.

Interbrew Baillet-Latour, which produces Stella Artois lager, is one of the world's leading brewery groups, as well as one of the oldest. The brewery was founded in the 14th century in Leuven, Belgium, under the name Den Horen, and was acquired by Sebastien Artois in the late 17th or early 18th century. In 1988, Artois Breweries merged with another major Belgian brewery, Piedboeuf, to create the Interbrew group.

The Interbrew-Baillet Latour Foundation (originally named the Artois-Baillet Latour Foundation) was set up in 1974 with a significant donation of company shares by long-time brewery director Count Alfred de Baillet Latour (1901-1980). In its biennial awards, presented for the first time in 1979, the Foundation aims to honor applications of fundamental scientific research.

The first winner was Britain's Sir James Black, honored for his contribution to medications for high blood pressure, peptic ulcers and other disorders. The 1995 winner was the U.S.'s Prof. Roger Tsien, honored for his work in clarifying the events inside cells critical to the actions of hormones and other molecules.

The Weizmann Institute of Science is a major center of scientific research and graduate study located in Rehovot, Israel.
Prof. Michael Sela
English

A Cancer Pioneer

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 Prof. Leo Sachs
 
When Prof. Leo Sachs was young, he dreamed of founding a kibbutz in Israel and even spent two years as a farm laborer to prepare for pioneering on the land. Today, however, Sachs, a professor at the Weizmann Institute of Science in Israel, is renowned for pioneering of a very different nature. One of the world's leading scientists in the areas of cell biology and cancer research, Sachs has made fundamental contributions to his field and paved the way for successful clinical treatments.
 
One recent recognition of his achievements comes from Harvard Medical School, which will present him with its Warren Alpert Foundation Prize in Boston on April 17. Shortly afterwards, Sachs will travel to Sweden, where on May 30 he will receive an honorary doctorate of medicine from Lund University.
 
These are only the latest in a long list of prizes that have punctuated the illustrious career of the 6'8" researcher, who is quippingly said to be "head and shoulders" above many of his colleagues. His previous honors include the Wolf Prize in Medicine, the Israel Prize in Natural Sciences, the Rothschild Prize in Biological Sciences, the General Motors Cancer Research Foundation Prize, the Bristol-Myers Award for Distinguished Achievement in Cancer Research, the Royal Society Wellcome Prize, and Foreign Associate of the USA National Academy of Sciences.

Prenatal diagnosis
 
At the very beginning of his scientific career in Israel, Sachs had an idea that ultimately made it possible to diagnose human diseases in the womb.
 
The year was 1952, and the German-born Sachs, who had been educated in England, had just moved to the new Jewish state. By then, he had abandoned his early dreams of working the land in favor of contributing to the fledgling nation in the way he knew best - through science. He was recruited by the Weizmann Institute and asked to initiate a research program in genetics and development.
 
Sachs started working on a theory that human amniotic fluid, which bathes the baby in the womb, contains fetal cells that can provide information about the fetus. His studies proved him right. He showed that cells in the fluid can be reliably used to tell the sex of the baby before birth and also reveal other important properties of the fetus. This groundbreaking research formed the basis for human prenatal diagnosis by amniocentesis, a diagnostic procedure used today in millions of expectant mothers.
 
"I could have made this my life's work. But since I'd already proved the point, I wanted to look at some other aspect of development," Sachs explains. "I wanted to get a broad picture and try and discover general principles of normal and abnormal development."

Improving clinical treatments
 
Shortly afterwards, Sachs moved to the Institute's newly-created Experimental Biology Department and asked himself two questions that would form the basis of his research over the following years. First, what controls the normal development of different types of blood cells and second, what happens when normal development goes wrong through disease? "I thought that by understanding the normal processes and what happens in disease, I might be able to find a way to control the disease," says Sachs.
 
In trying to answer these questions, Sachs made discoveries that would serve as a cornerstone for current blood cell research and lead to major clinical applications. He developed the first-ever procedure to grow, clone and induce the development of different types of normal blood cells in a petri dish. Using this process he discovered and identified a family of proteins, among them colony-stimulating factors and some interleukins, that control blood cell production in its various stages.
 
One of the proteins that Sachs identified, the granulocyte colony stimulating factor, is now used clinically to boost the production of disease-fighting white blood cells in cancer patients undergoing chemotherapy or irradiation. The problem with both of these therapies is that they kill not only cancerous cells but also healthy ones. In many cases patients become dangerously susceptible to infection because their white blood cells have been destroyed. Regenerating certain white blood cells therefore gives these patients a better chance to fight infections. After clinical trials in several countries, this treatment is now widely used around the world.
 
The same protein was also found to help improve the success of bone marrow and blood cell transplants, as well as a number of other clinical procedures.

Reversing malignancy
 
Sachs also asked the question: what changes in normal development result in leukemia, and can this process be reversed? Subsequently he demonstrated that the proteins he had initially discovered, and some other compounds, can induce certain leukemic cells to behave again like normal ones both in a petri dish and in the body. Until then, most scientists had believed that malignancy was irreversible. These findings led to a form of treatment, called differentiation therapy, that does not kill cancer cells but instead gently induces them to behave like normal cells again.
 
Based on these results, researchers in France and China then developed an experimental treatment for patients suffering from acute promyelocytic leukemia. This procedure is now also being tested in other types of cancer.

What keeps cancer cells alive?
 
A few years ago Sachs returned to a question that had troubled him back in the early days of his scientific work. "When I first put normal blood cells into a petri dish, I found that without the necessary chemicals the cells would die. I decided to see if the materials needed to keep normal cells alive were the same for leukemic cells," says Sachs.
 
In normal circumstances, a cell is created, lives and then dies, and there is a balance between the creation of new cells and the death of old ones. But in cancer cells this balance is profoundly distorted. Sachs' present research includes studies on the genetic changes which take place in leukemic cells enabling them to live longer, and on finding ways to "switch off" these life-maintaining genes in the cancer cells, so that they die like normal cells that the body no longer needs. This research could provide another new approach to cancer treatment.
 
Contemplating 45 years of work, Sachs, who holds the Otto Meyerhof Chair of Molecular Biology at the Weizmann Institute, acknowledges that it has not always been easy. "I enjoyed most of it, but not all," he admits. "There have been ups and downs. But overall I'm optimistic and believe that all problems have solutions. One has to be permanently curious and keep on trying."

The Weizmann Institute of Science is a major center of scientific research and graduate study located in Rehovot, Israel.
 Prof. Leo Sachs
English

Weizmann Institute Professor Leo Sachs Wins Harvard Medical School's Warren Alpert Foundation Prize

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Prof. Leo Sachs
 
 
REHOVOT, Israel -- March 18, 1997 -- Prof. Leo Sachs of the Weizmann Institute of Science has been awarded Harvard Medical School's Warren Alpert Foundation Prize. Given "in recognition of scientific discoveries leading to improved understanding and treatment of disease," the prize will be presented to Prof. Sachs at a ceremony at the Harvard Medical School on April 17.

Sachs is being honored for "work on the molecular regulation of bone marrow cell growth and differentiation and the use of granulocyte colony stimulating factor to treat bone marrow suppression." He shares the prize with Dr. Donald Metcalf of the Walter and Eliza Hall Institute of Medical Research, Melbourne, Australia.

Prof. Sachs' pioneering research, begun more than 35 years ago, has revolutionized molecular, cellular and clinical hematology. He developed the first procedure to grow and clone different types of normal blood cells in laboratory cultures.

Using this procedure, he discovered a family of proteins that control blood cell production, among them the compounds now called colony stimulating factors and some interleukins.

One of these proteins, the granulocyte colony stimulating factor, is today being used clinically to boost the production of disease-fighting white blood cells in cancer patients undergoing chemotherapy or irradiation, to improve the success of blood cell transplants and in other procedures.

Sachs also demonstrated that the proteins he discovered and certain other compounds can induce the maturation of particular types of leukemic cells, causing them to revert to normal. This finding has led to the development of a new experimental cancer treatment called differentiation therapy.

Sachs, who holds the Otto Meyerhof Chair of Molecular Biology and is a member of the Weizmann Institute's Molecular Genetics Department, has received numerous awards, including the Wolf Prize in medicine, the Israel Prize in natural sciences, the Rothschild Prize in biological sciences, the Harvey Lectureship, the Alfred P. Sloan Prize of the General Motors Cancer Research Foundation, the Bristol-Myers Award for distinguished achievement in cancer research, and the Royal Society Wellcome Foundation Prize. He is a member of the Israel Academy of Sciences and Humanities, and a Foreign Associate of the USA National Academy of Sciences.

On May 30, Prof. Sachs will also receive a Doctor of Medicine Honoris Causa from Lund University, Sweden, for his pioneering studies in experimental and clinical hematology.

The Weizmann Institute of Science is a major center of scientific research and graduate study located in Rehovot, Israel. Its 2,400 scientists, students and support staff are engaged in more than 850 research projects across the spectrum of contemporary science.
Prof. Leo Sachs
English

Weizmann Institute President Appointed Special Advisor to Madame Edith Cresson

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Prof. Haim Harari

 

REHOVOT, Israel -- March 6, 1997 -- Mme Edith Cresson, former Prime Minister of France and currently a member of the European Commission with responsibility for science, research and technological development, has just announced the appointment of Weizmann Institute of Science President Prof. Haim Harari as her special advisor. The appointment covers the fields of science education and international scientific cooperation.


Prof. Harari, a world authority in theoretical particle physics, is a long-time leader in science education. He has served as head of the Weizmann Institute's Science Teaching Department and Dean of its Feinberg Graduate School.

He was a founder of Perach, a nationwide tutoring program for underprivileged children, and presently chairs the Perach Council, which oversees the program. Prof. Harari has served as Chairman of the Planning and Grants Committee of Israel's Council for Higher Education and Chairman of the Israel Government's Superior Committee on Science, Mathematics and Technology Education charged with developing an educational program that will prepare Israel's youth for the challenges of the next century.

"The number one issue today in our society vis-a-vis science and technology is education," Prof. Harari says. "Everybody has to be able to speak the language of science, and the most important issue for the future is to give a certain level of science and technology education to the general public and to every child, no matter what profession a person might pursue."

In the area of international scientific cooperation, Prof. Harari has been instrumental in further expanding the Weizmann Institute's strong ties with preeminent research institutions throughout the world. The Institute's relations with European institutions have recently been bolstered by the signing of an agreement that fully associates Israel with the European Union's research and development activities.

The Weizmann Institute of Science is a major center of scientific research and graduate study located in Rehovot, Israel. Its 2,400 scientists, students and support staff are engaged in more than
850 research projects across the spectrum of contemporary science.
Prof. Haim Harari
English

'Women of Distinction' Award to Two Weizmann Institute Scientists

English
REHOVOT, Israel -- January 28, 1997 -- This week, two scientists from Israel's Weizmann Institute were honored for an achievement that bears on the lives of many people throughout the world.

Prof. Ruth Arnon and Dr. Dvora Teitelbaum received Women of Distinction Awards from Hadassah, the Women's Zionist Organization of America, for three decades of pioneering scientific research that led to a new drug for multiple sclerosis.

This honor was bestowed upon them along with four other outstanding Israeli women at a festive ceremony in the Knesset, Israel's Parliament, on January 26. The Awards were inaugurated this year by Hadassah to celebrate the organization's 85th anniversary.

Arnon and Teitelbaum won the honor for synthesizing and developing -- together with former President of the Weizmann Institute Prof. Michael Sela -- the MS drug called copolymer-1 (COPAXONE®). In December 1996, COPAXONE® received approval from the U.S. Food and Drug Administration, one of the first Israeli-produced medications to achieve such distinction. It is manufactured and marketed by Teva Pharmaceutical Industries Ltd., which further developed the drug with the participation of physicians and researchers from Israel and other countries.

Paradoxically, the long journey of scientific exploration that resulted in the development of copolymer-1 began with a major disappointment. In trying to produce an MS-like disease in laboratory animals, the scientists synthesized several protein-like molecules called copolymers that mimicked a natural substance believed to trigger MS. But despite repeated efforts, the new molecules failed to produce the disease.
 
The scientists persisted, and in studying the properties of their copolymers stumbled upon an amazing discovery. Rather than triggering MS-like symptoms, the molecules actually blocked them. The researchers immediately knew they had a potential drug on their hands.

Years of research and several clinical trials later, one of these molecules, copolymer-1, indeed proved effective in alleviating the symptoms of relapsing-remitting MS in human patients.

MS, which affects at least one million people worldwide, is an autoimmune disorder in which the immune system mistakenly attacks and destroys the protective coating of nerves, leading to symptoms ranging from numbness to paralysis.

"By talking to patients and their physicians, we knew long before the large clinical trials had been completed that we were on the right track," says Teitelbaum.
 
Over the years, the Weizmann Institute researchers became personal friends with some of the patients who had been helped by the drug. "It's hard to describe the wonderful feeling of satisfaction that comes from the realization that our work is bringing someone relief," says Arnon.

But she and her colleagues are not about to rest on their laurels, she says, adding that they hope to apply what they learned from their research on copolymer-1 to finding remedies for other autoimmune disorders.
 
"And meanwhile, as an Israeli," she says, "I am really proud that Copaxone, which will bring relief to MS sufferers all over the world, is a true 'Sabra,' a born-in-Israel product."

Prof. Arnon holds the Paul Ehrlich Chair of Immunology.

The Weizmann Institute of Science is a major center of scientific research and graduate study located in Rehovot, Israel. Its 2,400 scientists, students and support staff are engaged in more than 850 research projects across the spectrum of contemporary science.
Prof. Ruth Arnon
English

World's Most Prestigious Award in Computer Science to Weizmann Institute's Prof. Amir Pnueli

English
REHOVOT, Israel -- November 7, 1996 -- A Weizmann Institute of Science mathematician, Prof. Amir Pnueli, has been named the recipient of the 1996 Turing Award, the world's most prestigious prize, dubbed the "Nobel Prize in computer science."
 
Prof. Amir Pnueli
 
Pnueli develops sophisticated methods for verifying the correctness and reliability of computer systems, including software and hardware. These increasingly complex systems control crucial aspects of contemporary life, such as the operation of nuclear power stations, missile launching, aircraft navigation, functioning of medical equipment and communications. A fault in these vital computer systems can have grave and sometimes catastrophic consequences.

One way to prevent such disasters is to test the computer's response to a range of simulated situations. However, sophisticated as this method may be, there is always a risk that the check-up may overlook one scenario -- which may happen to be the one that can trigger a meltdown .

A far more reliable approach has been developed by Pnueli. He uses a mathematical language to describe the desired specifications of a program and -- before the system is even built -- applies mathematical proofs to confirm beyond a shadow of a doubt that the program complies with the most stringent safety standards. This prize-winning method is particularly suitable for programs that control physical facilities, such as those that govern the flight of an aircraft.

The A.M. Turing Award is named after Alan M. Turing (1912-1954), the Scottish mathematician considered to be among the fathers of modern computer science. He was on the British team that deciphered the German army s Enigma codes during World War II.

The Award is granted annually by the Association for Computing Machinery for major and lasting contributions to the computing community. It will be presented to Pnueli in March 1997 in San Jose, California, at the scientific meeting marking the 50th anniversary of the association, the largest international scientific and educational computer society.

About Prof. Pnueli's research
 
In his research, Pnueli, a member of the Weizmann Institute's Applied Mathematics and Computer Science Department, relies on temporal logic, a mathematical language that incorporates the element of time into mathematical reasoning. For example, it can distinguish between things that are true at all times and properties that may be true in one instant but false in another.

Pnueli's innovative approach, first published in 1977, introduced temporal logic into computer science as the appropriate language for specifying and verifying reactive programs. By now, this use of temporal logic has been widely accepted and has led to the emergence of the new and dynamic field of temporal specification and verification in computer science.

Verification techniques based on his work have in the past few years been used worldwide both as a research tool and in practical applications, particularly in large and complicated systems.

Pnueli is responsible for the introduction of a number of new concepts, computational models and verification methodologies that have been adopted by the entire scientific community dealing with system verification.

For example, he characterized the class of reactive systems as systems whose role is to maintain an ongoing interaction with their environment, rather than compute a final result. He argued that such systems are particularly difficult to program correctly, and showed that temporal logic is the right tool for their specification and verification. Today the notion of reactive systems has become a key concept in computer science and is the topic of numerous research papers and international conferences.

An important extension to the temporal methodology was Pnueli's development of real-time temporal logic, which makes possible the precise analysis of real-time systems whose reliability is dependent on their ability to react to external stimuli within particularly short time periods. This improvement stirred up a flurry of activity in the international scientific community.

Another concept recently developed by Pnueli is that of hybrid systems. For many years, it was common to distinguish between discrete components (such as a digital controller that decides on the opening and closing of valves) and continuous ones (such as the chemical and physical processes themselves).

A system that controls a production line in a large factory naturally includes both discrete and continuous components. Pnueli found a way to combine these components into the single mathematical model of hybrid systems which can be specified and verified by temporal technology.

Pnueli is personally involved in numerous research projects at various international institutions. He plays a key role in a major European Union project aimed at developing a foolproof design methodology for safety-critical systems. These are legally characterized as systems in which a single failure can cause the death of one or more persons.

Born in Nahalal, Israel, Pnueli received his Ph.D. at the Weizmann Institute and then conducted research at Stanford University in the U.S. He founded and headed the Department of Computer Science at Tel Aviv University before returning to the Weizmann Institute in 1980.

The Weizmann Institute of Science is a major center of scientific research and graduate study located in Rehovot, Israel.
Prof. Amir Pnueli
English

1996 Distinguished Clinical Chemist award

English
REHOVOT, Israel. The Weizmann Institute's Professor Meir Wilchek has been named the 1996 winner of the prestigious Distinguished Clinical Chemist Award, given every three years by the International Federation of Clinical Chemistry.
 
 
Professor Meir Wilchek
 
Prof. Wilchek, who revolutionized the purification of biochemicals, will be presented with the award on July 7 at the opening ceremony of the Federation s triennial international congress being held in London on July 7 - 12.

Working with Prof. Pedro Cuatrecasas of the U.S., Prof. Wilchek pioneered a technique known as affinity chromatography, which makes it possible to extract and purify even the most minute quantities of biochemicals from complex chemical mixtures. As well as being of great importance for biological research, the method has the potential to improve medical treatments, enabling anti-cancer drugs, for example, to reach specific sites in the body without affecting other organs.

Prof. Wilchek, of the Institute's Membrane Research and Biophysics Department, also played a major role in the development of the remarkable biomolecular "superglue" that has generated a multimillion-dollar market in areas from pollution control to disease diagnosis. The glue is based on the strongest biological interaction known in nature -- the attraction of the vitamin biotin to the protein avidin.

Holder of the Marc R. Gutwirth Chair of Molecular Biology at the Weizmann Institute, Prof. Wilchek has also received the Wolf Prize in Medicine, the Israel Prize in Life Sciences and Biotechnology, the Pierce Award in Affinity Chromatography, the Rothschild Prize in Chemistry and the Sarstedt Prize for the avidin-biotin system. He is a member of the Israel Academy of Sciences and Humanities and the only Israeli to be elected a Foreign Associate Member in the Institute of Medicine of the U.S. National Academy of Sciences.

The International Federation of Clinical Chemistry, which was founded in the 1950s with the aim of advancing clinical chemistry around the world, is made up of member societies from more than 60 countries, representing more than 27,000 clinical chemists. The Federation has bestowed its Distinguished Clinical Chemist Award triennially since 1969 to honor an individual who has made outstanding contributions to clinical chemistry or the application of the field to medical problems. The award is sponsored by the Bayer Corporation (formerly Miles Laboratories Inc.).

The Weizmann Institute of Science is a major center of scientific research and graduate study located in Rehovot, Israel.
 
Professor Meir Wilchek
English

Rothschild Prize to Weizmann Institute Professor Yoseph Imry

English
Prof. Yoseph Imry
 
 
REHOVOT, Israel -- May 26, 1996 -- Weizmann Institute Prof. Yoseph Imry, a leading expert in the theory of solid state physics and one of the founders of the new and growing field known as mesoscopic physics, will today receive the 1996 Rothschild Prize in Physics, to be presented at a ceremony taking place at the Knesset, Israel's Parliament, in Jerusalem.

Mesoscopic physics deals with topics ranging from the foundations of quantum theory to development of ultra-modern electronic devices. According to the Prize committee, Prof. Imry's "personal contacts with experimental and theoretical physicists have greatly advanced the development of this new field throughout the scientific world."

The committee also praised Prof. Imry for raising a new generation of outstanding Israeli scientists and lauded his ongoing efforts to promote the infrastructure for experimental physics in Israel.

Prof. Imry, who holds the Max Planck Chair of Quantum Physics at the Weizmann Institute and is a member of the Department of Condensed Matter Physics, has received numerous other honors including the 1996 Lorenz Professorial Chair from the University of Leiden, The Netherlands; the Humboldt Research Award, Germany; the IBM Award, U.S.A., as well as the Weizmann and Landau Prizes, Israel. Imry is also an active member of the European Academy of Sciences and Arts.

The Rothschild Prizes are awarded once in two years by the Rothschild Prize Foundation in Israel.

The Weizmann Institute of Science is a major center of scientific research and graduate study located in Rehovot, Israel.
 
Prof. Yoseph Imry
English

Prestigious German Award to Weizmann Institute Professor

English
REHOVOT, Israel -- February 5, 1996 -- On February 12, the Weizmann Institute will host a ceremony at which Institute Professor Michael Sela will become the first non-German to receive the Harnack Medal, the Max Planck Society's highest award.
 
Professor Michael Sela
 
The medal will be presented to him by Prof. Hans F. Zacher, President of the Max Planck Society. It was named for Adolf von Harnack, the first President of the Kaiser Wilhelm Society, the Max Planck Society's predecessor, and is bestowed for outstanding contributions to the advancement of science and the humanities.

First awarded in 1925 by the Kaiser Wilhelm Institute, the Harnack medal has since been presented to only 25 distinguished public personalities, including eminent scientists like Max Planck and notable officials such as three presidents of the Federal Republic of Germany (see list below).

Prof. Sela, Deputy Chairman of the Weizmann Institute's Board of Governors and a former President of the Institute, is best known in the scientific community for his work in immunology -- particularly for pioneering the study of synthetic antigens, an effort that led to a better understanding of the molecular basis of immunity as well as the design of synthetic vaccines. He is co-developer of copolymer-1, a new drug that is now being used in the treatment of multiple sclerosis.
 
Prof. Sela is a member of numerous scientific bodies, among them the Israel Academy of Sciences and Humanities, the U.S. National Academy of Sciences, the French Academy of Sciences and Deutsche Akademie der Naturforscher Leopoldina. He is the recipient of numerous honors, including the Israel Prize, Germany's Commander's Cross of the Order of Merit and the French Legion of Honor, as well as several honorary doctorates from academic institutions throughout the world.
 
Several of the previous Harnack Medal recipients have had close links with the Weizmann Institute. Among these was Otto Hahn, who headed a Max Planck Society delegation to the Institute in 1959. This visit marked the start of official scientific relations between the State of Israel and the Federal Republic of Germany, six years before the establishment of diplomatic relations between the two countries.
 
Other medal recipients linked to the Institute include Nobel laureate Fritz Haber, a personal friend of Dr. Chaim Weizmann, and Richard von Weizsacker, former President of Germany and a 1985 recipient of an honorary doctorate from the Weizmann Institute.
 
Over the past three and a half decades, collaboration between Weizmann Institute and German scientists has evolved and expanded, and today Germany is the Institute's most important international partner after the United States.
 
A special place in this partnership is occupied by the Max Planck Society's Minerva Foundation, which "through the funding of Germany's Federal Ministry for Education, Science, Research and Technology" supports six interdisciplinary research centers and numerous research projects at the Institute.
 
Prof. Sela is the incumbent of the W. Garfield Weston Chair of Immunology at the Weizmann Institute.
 
 
List of Harnack Medal Recipients

1.1925 Exzellenz Adolf v. Harnack

2.1926 Prof. Dr. Fritz Haber

3.1929 Exzellenz Friedrich Schmidt-Ott

4.1932 Bankier Franz v. Mendelssohn

5.1932 Prof. Dr. Carl Correns

6.1933 Prof. Dr. Max Planck

7.1933 Dr. Gustav Krupp v. Bohlen und Halbach

8.1934 Prof. Dr. Carl Duisberg

9.1936 Dr. Albert Vogler

10.1936 Prof. Dr. Ludwig Prandtl

11.1953 Dr.-Ing. E.h. Gustav Winkler

12.1954 Prof. Dr. Otto Hahn

13.1959 Prof. Dr. Otto Hahn (in Gold)

14.1959 Bundesprasident Prof. Dr. Theodor Heuss

15.1960 Prof. Dr. Erich Kaufmann

16.1962 Pralat Prof. D. Dr. Georg Schreiber

17.1963 Prof. Dr. Otto Warburg

18.1964 Bundesprasident Dr. Heinrich Lubke

19.1965 Prof. Dr. Alfred Kuhn

20.1970 Prof. Dr.-Ing. Carl Wurster

21.1973 Prof. Dr. Adolf Butenandt

22.1974 Prof. Dr. Walther Gerlach

23.1981 Dr. Kurt Birrenbach

24.1983 Prof. Dr. Adolf Butenandt (in Gold) 1984

25.Prof. Dr. h.c. Hans L. Merkle

26.1990 Bundesprasident Dr.Richard v.Weizsacke

27.1993 Prof. Dr. Reimar Lust

The Weizmann Institute of Science is a major center of scientific research and graduate study located in Rehovot, Israel.
 
Professor Michael Sela
English

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