Biography
Beginnings
Work and Medical School
Discovery of Penicillin :
Some Personal Details and The End
Alexander Fleming discovered
Penicillin, whose use has saved untold millions of lives. Less well-known is
that before making this world-changing discovery, he had already made
significant contributions to medical science.
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| Alexander Fleming : Lived 1881 – 1955. |
Beginnings
Alexander Fleming
was born on August 6, 1881 at his parents’ farm located near the small town of
Darvel, in Scotland, UK.
His parents, Hugh
Fleming and Grace Stirling Morton, were both from farming families. His
father’s health was fragile; he died when Alexander was just seven years old.
Alexander’s earliest
schooling, between the ages of five and eight, was at a tiny moorland school
where 12 pupils of all ages were taught in a single classroom.
Darvel School was
Alexander’s next school, which involved an eight-mile round trip walk every
school-day. At the age of 11 his academic potential was recognized and he was
awarded a scholarship to Kilmarnock Academy, where he boarded for about two years
before leaving for the city of London.
Alexander arrived in
London early in 1895, aged 13. This was the year his fellow Scot, Arthur Conan
Doyle, published The
Memoirs of Sherlock Holmes, in which readers were horrified to
learn that their hero had died falling over the Reichenbach Falls.
Alexander lived in
the home of an older brother, Tom, who was a doctor of medicine. Most of the
Fleming family ended up living with Tom, leaving the eldest brother, Hugh,
running the farm.
Alexander attended
the Polytechnic School, where he studied business and commerce. He started in a
class appropriate to his age, but his teachers soon realized he needed more
challenging work. He was moved into a class with boys two years older than him
and finished school aged 16.
Work and Medical School
His business
training helped him get a job in a shipping office, but he did not enjoy
working there.
In 1901, at the age
of 20, he inherited some money from his uncle, John Fleming. He decided to use
the money to go to medical school; he wanted to become a doctor like his
successful brother Tom.
First, he needed
suitable qualifications to enable him to join a medical school. This did not
present any great difficulties; he passed his exams with the highest marks of
any student in the United Kingdom.
In 1903, aged 22,
Alexander enrolled at London’s St Mary’s Hospital Medical School, graduating
with distinction three years later as Bachelor of Medicine, Bachelor of
Surgery.
Rather than follow
in Tom’s footsteps, Alexander was persuaded by Almroth Wright, an authority in
immunology, to become a researcher in his bacteriology group at St Mary’s
Hospital Medical School. While carrying out this research Fleming graduated, in
1908, with a degree in bacteriology and the Gold Medal for top student. St
Mary’s Hospital Medical School then promoted him to the role of bacteriology
lecturer.
Almroth Wright was
interested in our bodies’ natural ability to fight infection. Fleming became
particularly fascinated by the fact that, although many people suffered
bacterial infections from time to time, the majority of people’s natural
defenses prevented infections from taking hold.
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Bulfighter Memorials for Research : Alexander Fleming
Fleming’s Most Significant
Contributions to Science :
Proving that Antiseptics
Kill Rather than Cure :
In 1914 World War 1
broke out and Fleming, aged 33, joined the army, becoming a captain in the
Royal Army Medical Corps, working in field hospitals in France.
There, in a series
of brilliant experiments, he established that antiseptic agents used to treat wounds
and prevent infection were actually killing more soldiers than the infections
were!
The antiseptics,
such as carbolic acid, boric acid and hydrogen peroxide, were failing to kill
bacteria deep in wounds; worse, they were in fact lowering the soldier’s
natural resistance to infection because they were killing white blood cells.
Fleming demonstrated
that antiseptic agents were only useful in treating superficial wounds, but
were harmful when applied to deep wounds.
Almroth Wright
believed that a saline solution – salt water – should be used to clean deep
wounds, because this did not interfere with the body’s own defenses and in fact
attracted white cells. Fleming proved this result in the field.
Wright and Fleming
published their results, but most army doctors refused to change their ways,
resulting in many preventable deaths.
Nurses come to the aid of a wounded soldier. Fleming saved many
soldiers’ lives in World War One by washing deep wounds with saline solution
rather than the antiseptics recommended by medical textbooks.
Discovery of Lysozyme
In 1919 Fleming
returned to research at St Mary’s Hospital Medical School in London. His
wartime experience had firmly established his view that antibacterial agents
should only be used if they worked with the body’s natural defenses rather than
against them; in particular, they must not harm white blood cells.
His first discovery
of such an agent came in 1922, when he was 41 years old.
Fleming had taken
secretions from inside the nose of a patient suffering from a head cold. He
cultured the secretions to grow any bacteria that happened to be present. In
the secretions, he discovered a new bacterium he called Micrococcus lysodeikticus,
now called M luteus.
A few days later,
Fleming was examining these bacteria. He himself was now suffering from a head
cold, and a drop of mucus fell from his nose on to the bacteria. The bacteria
in the area the drop had fallen were almost instantly destroyed. Always on the
lookout for natural bacteria killers, this observation excited Fleming
enormously.
He tested the effect
of other fluids from the body, such as blood serum, saliva, and tears, on these
bacteria and found that bacteria would not grow where a drop of one of these
fluids had been placed.
Fleming discovered
the common factor in the fluids was an enzyme.
He named his newly
discovered enzyme lysozyme.
The effect of lysozyme was to destroy certain types of microbe, rendering them
harmless to people. The presence of lysozyme in our bodies prevents some
potentially pathogenic microbes from causing us harm. It gives us natural
immunity to a number of diseases.
However, lysozyme’s
usefulness as a medicine is rather limited, because it has little or no effect
on many other microbes that infect humans.
It did, however,
mean that Fleming had discovered a natural antibiotic which did not kill white
blood cells. If only he could find a more powerful antibiotic, then medicine
could be transformed.
Today, lysozyme is
used as a food and wine preservative. It is naturally present in especially
large concentrations in egg-whites, offering protection against infection to
chicks.
It is also used in
medicines, particularly in Asia, where it is used in treatments for head colds,
athlete’s foot and throat infections.
Lysozyme is shown here in blue. It is an enzyme, meaning it is a
type of protein. It destroys bacteria by breaking down their cell walls, shown
in pink.
“The view has been generally held that the
function of tears, saliva and sputum, so far as infections are concerned, was
to rid the body of microbes by mechanically washing them away… however, it is
quite clear that these secretions, together with most of the tissues of the
body, have the property of destroying microbes to a very high degree.” ALEXANDER FLEMING : Bacteriologist
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Discovery of Penicillin :
In the month of
August 1928, Fleming did something very important. He enjoyed a long vacation
with his wife and young son.
On Monday, September
3, he returned to his laboratory and saw a pile of Petri dishes he had left on
his bench. The dishes contained colonies of Staphylococcus bacteria. While he was away, one of
his assistants had left a window open and the dishes had become contaminated by
different microbes.
Annoyed, Fleming
looked through the dishes and found something remarkable had taken place in one
of them.
A fungus was growing
and the bacterial colonies around it had been killed. Farther from the fungus,
the bacteria looked normal. Excited by his observation, he showed the dish to
an assistant, who remarked on how similar this seemed to Fleming’s famous
discovery of lysozyme.
Hoping he had
discovered a better natural antibiotic than lysozyme, Fleming now devoted
himself to growing more of the fungus. He identified that it belonged to the Penicillium genus and that it produced a
bacteria-killing liquid. On March 7, 1929 he formally named the antibiotic – it
would be known as penicillin.
Fleming published
his results, showing that penicillin killed a variety of bacteria which were
then the scourge of humanity, including those responsible for scarlet fever,
pneumonia, meningitis and diphtheria. Furthermore, penicillin was non-toxic and
it did not attack white blood cells.
Unfortunately, the
scientific world was largely underwhelmed, ignoring his discovery.
Fleming faced a
number of problems:
·
it was difficult to
isolate penicillin from the fungus producing it
·
he could not find a
way of producing penicillin in high concentrations
·
penicillin seemed to
be slow acting
·
clinical tests of
penicillin as a surface antiseptic showed it was not especially effective
·
Fleming’s boss,
Almroth Wright, had a generalized dislike of chemists and refused to allow them
in his laboratory. The presence of a skilled chemist would have been a huge
benefit in terms of isolating, purifying, and concentrating penicillin.
Regardless of these
issues, Fleming continued with some work on penicillin in the 1930s, but never
made the breakthrough he needed to produce it in large, concentrated
quantities. Others, however, did.
In the early 1940s a
large team of University of Oxford scientists led by pharmacologist Howard
Florey and biochemist Ernst Boris Chain finally transformed penicillin into the
medicine we know today.
In 1945 Alexander
Fleming shared the Nobel Prize in Medicine or Physiology with Florey and Chain.
The award was made:
“for the discovery
of penicillin and its curative effect in various infectious diseases.”
In his Nobel Prize
winning speech in 1945, Fleming warned of a danger which today is becoming ever
more pressing
“It is not difficult to make microbes resistant
to penicillin in the laboratory by exposing them to concentrations not
sufficient to kill them, and the same thing has occasionally happened in the
body. The time may come when penicillin can be bought by anyone in the shops.
Then there is the danger that the ignorant man may easily underdose himself and
by exposing his microbes to non-lethal quantities of the drug make them
resistant.” ALEXANDER FLEMING : Bacteriologist
Fleming was always
fulsome in his praise for Florey, Chain, and their team, and he downplayed his
own role in penicillin’s story. Despite his modesty, he became a worldwide
hero. Millions of people owed their lives to the antibiotic he had discovered.
In 1945 he toured
America, where chemical companies offered him a personal gift of $100,000 as a
mark of respect and gratitude for his work. Typically of Fleming, he did not
accept the gift for himself: he donated it to the research laboratories at St
Mary’s Hospital Medical School.
Some Personal Details and The End
In 1915, while a
captain in the Medical Corps, Fleming married Sarah Marion McElroy. Their only
son, Robert, became a general medical practitioner.
In 1944 he was
knighted and became Sir Alexander Fleming.
His wife Sarah died
in 1949.
In 1953 Fleming
married Dr. Amalia Koutsouri-Voureka, who was working in his research group at
St Mary’s Hospital Medical School.
Alexander Fleming
died aged 73 of a heart attack in London on March 11, 1955. His ashes were
placed in St Paul’s Cathedral.