Institute of Micro-Biology. Though last year he formally handed over the reins to Professor R. Cruikshank, he continued his own research work there and only the day before yesterday was at the institute discussing plans for the lecture tour in the Middle East he had been asked to undertake by the British Council.
Fleming’s first notable discovery, that of lysozyme, was made in 1922. He had for some time been interested in antiseptics and in naturally occurring antibacterial substances. In culturing nasal secretion from a patient with an acute cold he found a remarkable element that had the power of dissolving bacteria. This bacteriolyte element, which he also found in tears and other body fluids, he isolated and named lysozyme.
A Lucky Accident
Penicillin was discovered in 1928 when Fleming was engaged in bacteriological researches on staphylococci. For examination purposes he had to remove the covers of his culture plates and a mould spore drifted on to a plate. After a time it revealed itself by developing into a colony about half an inch across. It was no new thing for a bacteriologist to find that a mould had grown on a culture plate which had lain on the bench for a week, but the strange thing in this particular case was that the bacterial colonies in the neighbourhood of the mould appeared to be fading away. What had a week before been vigorous staphylococcus colonies were now faint shadows of their former selves. Fleming might have merely discarded the contaminated culture plate but fortunately his previous research work on antiseptics and on naturally occurring antibacterial substances caused him to take special note of the apparent anti-bacterial action of the mould.
He made sub-cultures of the mould and investigated the properties of the antibacterial substance. He found that while the crude culture fluid in which the mould had grown was strongly antibacterial it was non-toxic to animals and human beings. The crude penicillin was, however, very unstable and was too weak and too crude for injection. Early attempts at concentration were not very successful, and after a few tentative trials its clinical use was not pursued, although it continued to be used in Fleming’s laboratory for differential culture. The position in 1929 was that Fleming had discovered and named penicillin, had investigated its antibacterial power, and had suggested that it might be useful as an antiseptic applied to infected lesions. Attempts to produce a concentrated extract capable of clinical application were not successful and had been abandoned. In the light of later knowledge Fleming’s original paper of 1929 was remarkable. It covered nearly the whole field, realized most of the problems and made considerable progress in solving them. The resuscitation of penicillin as a chemotherapeutic agent was due to the brilliant work of Sir Howard Florey and his colleagues at Oxford, notably Dr E. B. Chain.
Overwhelmed with Honours
After the establishment of penicillin as a life-saving drug Fleming was overwhelmed with honours. He was knighted in 1944 and in the following year he shared the Nobel Prize for Medicine with Sir Howard Florey and Dr E. B. Chain. He was William Julius Mickle Fellow of London University in 1942, and received an award of merit from the American Pharmaceutical Manufacturers Association in 1943. He was elected frs in 1943 and frcp in 1944, under the special by-law. His other honours included the Moxon medal of the Royal College of Physicians (1945), the Charles Mickle Fellowship of Toronto University (1944), the John Scott medal of the City Guild of Philadelphia (1944), the Cameron prize of Edinburgh University (1945), the Albert Gold Medal of the Royal Society of Arts (1946), the honorary Gold Medal of the Royal College of Surgeons (1946), the Actonian Prize of the Royal Institution, and the honorary Freedom of the Boroughs of Paddington, Darvel, and Chelsea. He had innumerable honorary degrees from British and foreign universities, and in 1951 was elected Rector of Edinburgh University. Only last weekend thieves stole property from his flat in Chelsea worth about £1,000 and later an appeal was made to them to return a gold seal of great sentimental value.
Fleming was president of the London Ayrshire Society and of the Pathological and Comparative Medicine Sections of the Royal Society of Medicine. Apart from the papers describing his great discoveries, he contributed to the Medical Research Council System of Bacteriology, to the official Medical History of the 1914–18 War, and to many other publications. He was a keen amateur painter, and he had many friends among artists. He was also very fond of motoring and of gardening. He remained quite unspoiled by the publicity and acclaim that came to him and no one was more aware than he of the indispensable part played by other investigators in the development of penicillin. Animated by the spirit of the true scientist, he looked ever forward.
He was twice married, first to Sarah Marion, daughter of Mr John McElroy. She died in 1949, leaving a son. In 1953 he married Dr Amalia Coutsouris, of Athens, who had been a member of his staff at the Wright-Fleming Institute.
Albert Einstein
Father of nuclear physics
18 April 1955
Professor Albert Einstein, the greatest scientist of modern times, died in hospital at Princeton, New Jersey, on April 18 at the age of 76. He had lived a secluded life for some years, though he had been a member of the staff of the Institute for Advanced Study in Princeton University.
Albert Einstein was born at Ulm, in Württemberg, on March 14, 1879. A year later his family moved to Munich, where they remained until he was 15. His parentage was Jewish, but few Jewish usages were observed in his home. He was slow in learning to talk and at the Catholic elementary school which he first attended was known as Biedermeier (‘Honest John’) from his ponderously accurate way of speaking. Both here and at the Luitpold Gymnasium, where the educational system was rigid, he saw little difference between school and barrack. His father, Hermann, had a small electro-chemical factory, but he had a greater genius for living than he had for success. Failing in Munich he moved to Milan and later to Pavia. The son, left unhappily at the gymnasium, was well on the way to manoeuvring his departure from it when he was unexpectedly asked to leave as being ‘disruptive’ of his class. Italy gave him as great an interest in art and music as he already had in Schiller, and the affairs of his father enforced him to seek a career. He had speculated at the age of five on the movement of a compass needle, and he knew that his mathematics, if not his other subjects, were well beyond the usual examination requirements. Combining interest and ability, he arrived at theoretical physics as the field that would most attract him but partly because of his father’s work and partly from his own lack of formal attainment, he thought that technological training would be his best approach. He therefore proposed to study at the Swiss Federal Polytechnic School in Zürich, but was at first rejected. He had to qualify for the diploma in modern languages and biology at a cantonal school at Aarau. There he lost his dislike of schooling, and from the age of 17 until the age of 21 he conscientiously followed the course prescribed at Zürich for a teacher of physics and mathematics. In 1901 he became a Swiss citizen – a reflection of his dislike of authority.
Annus Mirabilis, 1905
Partly on account of his ancestry, he had difficulty in finding a teaching post, but by the influence of a fellow student he was appointed as a technical assistant in the Swiss Patent Office at Berne in 1902. This was the ‘cobbler’s job’, which he maintained later was the way that scientists should earn their living. In the next year he married Mileva Maritsch, a fellow student at the Polytechnic. Two sons were born in quick succession, but there were differences of temperament and interest, and the marriage was dissolved after some years.
Einstein’s first contribution to theoretical physics was made in the same year that he obtained his Patent Office job. Three years later was his annus mirabilis, 1905. Then he burst without warning into an extraordinary range of discovery and new ideas, of which the ‘Special Theory of Relativity’ was one part, not at the time the most comprehensible by his colleagues. In his earliest work he had simplified Boltzmann’s theory of the random motions of the molecules of a gas, and in 1905 he applied this method to the ‘Brownian movement’ – the impetuous, irregular motion of microscopic particles, suspended in a fluid, that is produced by molecular bombardment. Einstein showed how the number of molecules per unit of volume could be inferred from measurements made of the distances travelled by the visible particles which they hit. Such measurements, made later by Perrin, verified Einstein’s theory so well that the Brownian movement has