Scientists
Alexander Fleming
Alexander Fleming Biography
Alexander Fleming (August 6, 1881 – March 11, 1955), his homeland located in Lochfield, Great Britain. His first stage of life was spent in a rural family dedicated to the cultivation and breeding of animals. His father Hugh Fleming died when Alexander was only seven years old, his mother being fortuitously left in the care of the family estate with the help of the eldest of her children. Fleming received a fairly elementary education, achieved with difficulty, however, his taste for detailed observation and tracking of objects, which emanated from his great curiosity were the key to achieving the future.
By 1894, when he was thirteen years old, he was transferred to London with a stepbrother who worked as a doctor. For four years he worked in a maritime company as an administrative one. Thanks to the money raised he completed two courses at the Polytechnic Institute of Regent Street, where he graduated with honors. In 1900 he enlisted in the London Scottish Regiment with the intention of being part of the Boer War, but it ended before his unit arrived to embark. However, his liking for military life led him to remain attached to his regiment, participating in the First World War in the role of an officer of the Royal Army Medical Corps in France.
At the age of twenty, due to his intelligence and dedication, he obtained a scholarship to the St. Mary’s Hospital Medical School in Paddington. At the end of his studies, he joined the team of bacteriologist Sir Almroth Wright, who deserved great respect, was associated for forty years. years with Wright. Simultaneously in 1908 he worked as a professor of bacteriology for twenty years at the University of London, was appointed professor emeritus and at the end of his work he was awarded the gold medal. He held until 1954 the address of the Wright-Fleming Institute of Microbiology, founded on his honor and on that of his former teacher and a great friend.
“The researcher suffers the disappointments, the long months spent in the wrong direction, the failures. But failures are also useful, because, well analyzed, they can lead to success. And for the researcher, there is no joy comparable to that of a discovery, no matter how small … “Alexander Fleming
The professional life of Alexander Fleming was dedicated to the investigation of the defense mechanisms of the human body to get rid of bacterial infections. Fleming discovered lysozyme in 1922 when he found that the nasal secretion had the ability to dissolve certain types of bacteria. Then he understood that this depended on an active enzyme present in numerous body tissues, although when the tissue has some affectation the activity of lysozyme is restricted. The finding proved to be highly interesting. As a result of the investigations undertaken by Paul Ehrlich thirty years earlier, the world of medicine celebrated this result, although there was still much to analyze.
During arduous days in the laboratory studying the alterations of certain staphylococcal colonies, Fleming proved that one of the cultures had been contaminated by a microorganism originated from the outside air, a fungus that he later identified as the Penicillium notatum. His scrupulous observation led him to verify that around the initial zone of contamination, the staphylococci had been arranged transparent, a phenomenon that Alexander correctly interpreted as the effect of an antibacterial substance distilled by the fungus.
His hours in the laboratory increased in order to verify that a pure culture broth of the fungus acquired, in a short time, a considerable level of antibacterial activity. He carried out several proposed practices to establish the degree of susceptibility to the broth of a wide range of pathogenic bacteria, noting that many of them were rapidly destroyed; He injected the culture in rabbits and mice, showed that it was innocuous for leukocytes, in a few words it was harmless for cells, in this case, animals. Finally, in the month of September 1928 discovered penicillin, one of the most important acquisitions of modern therapeutics. Although Alexander Fleming and his collaborators failed to obtain pure penicillin, we owe this to Ernst Boris Chain and Howard Walter Florey.
In 1941 the first satisfactory results with human patients began to come to light. Due to the context of war, the government allocated large resources for the multiplication of penicillin and its research development. As a result, in 1944 all the seriously wounded of the Battle of Normandy were treated with penicillin, thanks to their use And they saved many lives. Some months after his first observations, Fleming divulged the results obtained in a memory that today is a classic in the matter, but that at that time did not have the deserved resonance.
Although Fleming understood from the beginning the importance of the antibiosis phenomenon he had discovered, penicillin took about fifteen years to become the therapeutic agent of universal use that it is today. The discovery of Alexander Fleming, in fact, is understood as the finding of a substance, which was able to destroy pathogenic germs without harming the organism. Not only would it be responsible for saving millions of lives, but it would also revolutionize therapeutic methods, beginning the era of antibiotics and modern medicine. For this work, he was appointed sir in 1944.
One year later he shared the Nobel Prize in Physiology and Medicine with British scientists Howard Walter Florey and Ernst Boris Chain for their contributions to the improvement of penicillin. He then received the Gold Medal of Honor from the Royal College of Surgeons and was decorated with the Grand Cross of the order of Alfonso X, the Sage. Fame and recognition finally reached Fleming, who was elected a member of the Royal Society in 1942. During his time at the Royal Society, his wife Sarah Marion McElroy, an Irish nurse, was very supportive in his life and helped him achieve the recognition he had. But the life of this illustrious doctor ended on March 11, 1955, because of a heart attack. He was buried in the Cathedral of Saint Paul, in London.
History
Robert Oppenheimer
Robert Oppenheimer Biography
Julius Robert Oppenheimer (April 22, 1904 – February 18, 1967) was a physicist widely acknowledged as the father of atomic bomb. He was born in New York City, United States. Oppenheimer is renowned for his pivotal role in the development of the Manhattan Project during World War II, which culminated in the creation of the first atomic bombs.
Early years
Robert Oppenheimer was an American theoretical physicist, scientist, and university professor. He was the son of German-born Julius S. Oppenheimer and artist Ella Friedman. Coming from a wealthy and educated family in New York, his father was a Jewish owner of a significant fortune amassed through his textile factory. This allowed Oppenheimer to enjoy certain comforts and attend the best schools in the city.
In this regard, he was educated at the Ethical Culture School in New York, where he excelled as the top student, with some teachers even asserting that he was better than many of them. Upon graduating from school, he enrolled at Harvard University, where he stood out in all areas, from chemistry to Eastern philosophy, Greek, and Latin, completing his studies at the age of 21.
Career
After some time, Robert Oppenheimer decided to delve into the world of physics, capitalizing on both his aptitude for the subject and its burgeoning prominence across Europe. He moved to England, where he worked with Ernest Rutherford and J. J. Thomson. Alongside these two great scientists, he felt somewhat inadequate, as he believed his performance did not meet the required standards. However, Oppenheimer did not give up.
With the passage of time, he learned from his mentors, and by 1925, feeling more adapted, he began researching atomic energy and secondary-atomic particle energy processes at the Cavendish Laboratory.
A year later, he was at the University of Göttingen, collaborating with Max Born to develop his classical contribution to molecular quantum theory, known in physics as the “Born-Oppenheimer method”. He returned to his home country to teach theoretical physics at the California Institute of Technology and the University of Berkeley between 1929 and 1942. Oppenheimer was a highly political person. Therefore, in the 1930s, he decided to align himself with communist students to support the Republic during the Spanish Civil War, but certain actions led to the demise of his sympathy for the Communist Party.
Contribution to the Manhattan Project
The civil and political situation in Europe was becoming increasingly dangerous. By 1939, Albert Einstein and Leo Szilard warned the U.S. government about the dangers of nuclear energy falling into the hands of the Nazis. In response, President Franklin Roosevelt initiated the project for creating the atomic bomb, which was initially under military control, led by General Leslie Groves, an engineer known for overseeing construction projects, including the Pentagon. Later, Oppenheimer was brought on board to manage the administration of the project, which culminated in the construction of the atomic bomb by 1945.
Oppenheimer’s most significant contribution to the Manhattan Project was his leadership and effective coordination among diverse teams of scientists. His vision and problem-solving skills were crucial in overcoming the scientific and technological challenges involved in building an atomic bomb. He supervised the design and testing of the first atomic bombs, including the successful detonation of the plutonium bomb at the Trinity test site in New Mexico on July 16, 1945.
This American physicist had the support of many prominent figures in science, such as the great scientist Werner Heisenberg, Erwin Schrödinger, Max Born, Wolfgang Pauli, Paul Dirac, and Enrico Fermi, with whom he also developed close friendships. The work carried out by these scientists on quantum physics provided significant support for his own research. He gained valuable insights into quantum and relativistic physics, which kept him abreast of new scientific developments. He made contributions to the application of quantum theory to the concept of electron spin.
In his role as the director of the Institute for Advanced Study in Princeton, he fostered discussion and research in quantum and relativistic physics. In 1953, his past ties with the Communist Party led to certain defamation issues. As a result, he was called to a security hearing where the accusation was dismissed, but his access to military secrets was still prohibited. One of the institutions that attacked the scientist the most was the Federation of American Scientists. Oppenheimer was humiliated, and his communications were monitored. Nine years later, President John F. Kennedy, in an effort to rectify this mistake, awarded him the Enrico Fermi Award, granted by the Atomic Energy Commission, which he received from President Johnson himself.
“Now I Am Become Death, the Destroyer of Worlds”.
Oppenheimer, confessed to President Harry Truman, that he was not entirely comfortable with the fate of the atomic bomb. After some time, the Cold War erupted, and the Soviet Union announced its possession of an atomic weapon. In response, the United States decided to develop an even more powerful weapon. They approached Oppenheimer to lead the Atomic Energy Commission, but he declined the offer, resulting in his removal from the position. However, he remained the director at the Institute for Advanced Study, thanks to the support given by Einstein, Von Neumann, and Bohr.
After this event, his life took a different turn as he decided to distance himself from the laboratories and leaned towards writing about the studies conducted throughout his scientific career. Notable works include “Science and the Common Understanding” (1954) and a book related to electrodynamics (published posthumously in 1970). In the aftermath of the events in Japan and the grave consequences the atomic bomb had on humanity, he made several proposals aimed at internationally regulating the use of atomic energy to ensure peace.
He staunchly opposed the creation of the hydrogen bomb. However, despite his efforts and those of the General Advisory Committee of the Atomic Energy Commission, its development continued. Disheartened, Oppenheimer made the decision to retire from Princeton in 1966. A year later, on February 18, 1967, he passed away from throat cancer.
Filmography
Visual works inspired by Robert Oppenheimer:
- “Fat Man and Little Boy” (1989): Oppenheimer was portrayed by Dwight Schultz in this film.
- “One Day” (1989): The scientist was portrayed by David Strathairn.
- “Oppenheimer” (2023): The biography of Julius Robert Oppenheimer was brought to the screen in this movie, based on the biographical work “American Prometheus” by author Kai Bird. The character of Julius Robert Oppenheimer was played by Cillian Murphy and directed by Christopher Nolan.
Scientists
Friedlieb Ferdinand Runge
Friedlieb Ferdinand Runge Biography
Friedlieb Ferdinand Runge (February 8, 1794 – March 25, 1867) was born in Hamburg, Germany. Chemist and pharmacist, famous for discovering caffeine in 1820, after being encouraged to study coffee beans by renowned German scientist Johann Wolfgang Goethe.
Runge is considered one of the most prominent scientists of the 19th century. However, he was little appreciated at the time. Among his most outstanding findings are: atropine, aniline, phenol, quinine, pyrrole, and tar distilled dyes, as well as chromatography. Throughout his academic career he served as a professor at the universities of Berlin and Wroclaw, subsequently worked for a pharmaceutical company in which he sought financial support to make his discoveries profitable. However, his efforts were ignored.
Studies and beginnings
He was born into a humble family that lived in Billwerder (Hamburg). His father was a Lutheran pastor. He studied at the primary school located in Schiffbeck, after a few years he began to be interested in science, a passion he has cultivated since then. After carrying out his basic academic training, he chose as a profession the pharmaceutical company, an area in which she quickly excelled, thus earning her own livelihood since she was young. At the beginning of the 1810s, he observed how a drop of belladonna increased the diameter of the pupil of the eye in a cat, thus discovering the mydriatic effect of the plant. In 1816, he entered the University of Berlin, where he studied medicine, two years later he continued his training in Göttingen, the city in which he carried out his practices in chemistry.
Career
At the end of his formative period in Göttingen, he moved to Jena, where shortly thereafter he obtained his Ph.D. in Physics, after presenting an essay in which he delved into the poisoning with Belan and Belladonna. At that time he had as a Professor of Chemistry Johann Wolfgang Döbereiner, a renowned German chemist who invited Johann Wolfgang Goethe to observe Runge’s discovery about the effect of belladonna on the pupil, for this the young scientist presented himself with a cat, which had pupils of different diameter, impressed by his discovery, Goethe gave him a box of coffee beans and asked him to analyze the chemical composition of coffee, research that resulted in the discovery of caffeine in 1820.
Before his great discovery, he returned to Berlin, where he began to work as a university professor while continuing to work as a pharmacist. During this period, he lived with the famous physicist Johann Christian Poggendorf who was his school partner in Schiffbeck. Together, they turned their home into a laboratory, where they conducted numerous experiments. At the beginning of the 1820s, he carried out various studies related to indigo dye and its chemical composition (salts and metal oxides), information that was part of his doctoral thesis. He later published Recent phytochemical discoveries, a work in which he delved into this area of science, seeking to establish scientific phytochemistry.
During his stay in Berlin, he began teaching about plants and technical chemistry. In 1823, he traveled to Paris to continue studying, later moved to Wroclaw for a short time, then visited Switzerland, France, Germany, Holland, and England. After traveling through Europe, Runge settled in Wroclaw, a city where he served as an associate professor at the Faculty of Philosophy at the University of Wroclaw, without receiving a fixed salary. In the course of these years he gave various conferences and focused on his research, with the goal of carrying out chemical studies that had a practical benefit; a short time later he left his job at the university to devote himself fully to research. In 1832 he was hired to direct the technical management of a chemical factory sponsored by the Prussian government, located in Oranienburg.
While working at the factory, he discovered the aniline and phenol by distilling the coal tar, aware of the entrepreneurial potential of this discovery, he sought the support of the company. However, the factory director rejected the proposals proposed by Runge. For this discovery, he was exalted at the Industrial Congress in London and was later awarded in Berlin. For this same period, he investigated the intensities of the colors through the filter paper. In 1852 he was fired after being accused of working for a short time, an accusation that was linked to the academic activity of the scientist, who at this time focused on his studies and published about seven books. Runge lived for a short time of the pension of the company, which stopped arriving after the death of the owner.
The last years of his life faced serious financial problems, falling into oblivion. However, he continued to carry out research on practical chemistry, produced artificial fertilizers and wrote several books, including maintenance letters, a book in which he gave advice on the domestic environment, such as preparations, recipes, and Tricks to eliminate stains and odors. After a long academic career the scientist died on March 25, 1867, in Oranienburg, was buried in the municipal cemetery.
Although his studies and approaches were little appreciated in his time, currently Runge, he is considered one of the most relevant scientists of the nineteenth century.
Friedlieb Ferdinand Runge doodle
Google honored the scientist on the 225th anniversary of his birth, becoming the center of the Doodle on February 8th. In the image, the scientist is seen surrounded by his discoveries such as caffeine and the mydriatic effect of belladonna on the cat’s eyes.
physicist
Anders Celsius
Anders Celsius biography
Anders Celsius (November 27, 1701 – April 25, 1744) was born in Uppsala, Sweden. Physicist and astronomer, creator of the centesimal scale of the thermometer known as Grade Celsius (° C), which replaced the scale proposed by the German scientist, Daniel Gabriel Fahrenheit in 1724. Celsius, like many other scientists of his day, had a careful education that covered various fields. However, he focused fully on physics and astronomy, areas in which he excelled being considered one of the most prominent scientists of the 18th century. Throughout his academic career, he served as a professor of astronomy at the University of Uppsala. He was also one of the supervisors of the construction of the Uppsala Observatory, which he directed for several years.
He was born in a family belonging to the academic circle of the country. His father was Nils Celsius, an outstanding astronomer, a descendant of Magnus Celsius, a renowned mathematician and astronomer, who deciphered the runes of Staveless. His uncle Olof Celsius was the creator of a botanical school in Uppsala and a professor famous for his knowledge about mosses. On the maternal side, Celsius is related to Anders Spole, an astronomer and mathematician who served as a professor at Upsala University.
Career
After completing his studies he began to practice as a professor at the University of Uppsala (1730-1744) for 14 years. During this time, he conducted various investigations related to the field of astronomy. In the early years of the 1730s, he undertook a trip through Europe in which he visited the most outstanding astronomical observatories of the time, arriving to work with renowned astronomers. In 1733, he published a compilation of 316 observations of northern lights, in which he speculated about their relationship with magnetism.
Between 1736 and 1737 he was part of the group of researchers that accompanied the French astronomer Pierre Louis Maupertuis, on his journey through the northern region of Sweden where he sought to measure the length of the meridian near the pole, to compare it with the measurement made in Peru near to Ecuador. This research was known as the Lapland Expedition, which sought to demonstrate that Newton’s predictions about the flattening of the earth at the poles were correct, a conclusion they reached after the measurements. The calculations and conclusions of the expedition were included in La Figure de la Terre, a book published by Maupertuis in 1738.
For his participation in the expedition, Celsius was rewarded as an annual pension of 1,000 pounds, economic income that allowed him to invest in the construction of the Uppsala Observatory, which was one of the most modern of his time, after the opening he was appointed director of the observatory (1740). During the following years, he made various geographical measures used in the Swedish map. In the 1740s he carried out the studies in relation to the temperature scale by which he is known.
By 1742, he proposed to the Swedish academy a new way of measuring the temperature based on two established points: 0 indicated the boiling point of water and 100 represented the degree of freezing; which meant that as the heat increased the temperature dropped. This proposal would replace the scale created by Daniel Gabriel Fahrenheit in 1724, known as Fahrenheit Grade (° F), which ranged from 32 to 212 degrees.
Explained the operation of the scale, Celsius, created the centesimal scale that ranged from 0 to 100 degrees and invented the mercury thermometer. After three years, the scale was reversed by the Swedish scientist Karl von Linné, a modification with which it has been used since then. The scale of the Swedish scientist was called in the first years, Swedish thermometer, a term used by the scientific community of the time, however, since the 19th century it began to be called Celsius thermometer, in homage to its creator, it has also been known as Grade Celsius (° C). The following century this was replaced by the Kelvin scale (Kelvin K Grade), created in 1848 by William Thomson (Lord Kelvin).
The contributions of Celsius in the field of science are not reduced to scale, he was also the first scientist to raise the relationship between the phenomenon of the auroras and magnetism, also made numerous observations of this phenomenon that allowed his study years late. Another contribution of this scientist in the astronomical field was his studies on eclipses and stars, which included a detailed catalog of 300 stars and their system. Two years after the scale was created, the Swedish scientist contracted tuberculosis, a disease that deteriorated his health in a short time, passing away on April 25th, 1744, at the age of 43.
Doctor
Willem Einthoven
Willem Einthoven Biography
Willem Einthoven (May 21, 1860 – September 28, 1927) Physiologist and physician. Nobel Prize in Medicine in 1924. He was born in Semarang, Indonesia. He is well known for his contributions to the development of the electrocardiograph and its clinical application. His father died when they lived in Java, so Willem moved to the University of Utrecht to study medicine.
After finishing his studies he obtained the position of professor at the University of Leiden to deal with the positions of physiology and histology. He took the opportunity to advance an important work in the field of research. He quickly showed himself as a reputable scientist, participated in numerous international scientific forums and the best thing is that by managing several languages he could communicate his ideas faithfully without the need for translators.
For several years he experimented with the rope galvanometer and its utility for the registration of cardiac potentials, and the results obtained were published in an article in the year 1901. Five years later, he masterfully described the clinical applications of the electrocardiogram in Telecardiogramme (1906). After that, he published another article that laid the foundations for the development of this important tool in cardiology analysis. His investigative work was carried out simultaneously with his work as a professor.
Thanks to his work, the galvanometer was used to measure the differences in electrical potential during systolic and diastolic heart contractions and reproduce them graphically. This procedure is known as an electrocardiogram.
Later, he was interested in analyzing how healthy hearts worked and then defining a reference frame, through which attention was paid to the deviations caused by the disease. To sum up, he revolutionized the study, diagnosis, and treatment of cardiac pathologies. In his honor, the lunar crater Einthoven bears his name.
Doctor
Lucy Wills
Lucy Wills Biography
Lucy Wills (May 10, 1888 – 1964) hematologist and botany. She was born in Sutton Coldfield, United Kingdom. Her family enjoyed a good social and economic position. Therefore, she was able to study at Cheltenham Ladies ’College, an educational institute that offered high educational standards in teaching. Then, she studied Botany and Geology in 1911 but did not receive a Cambridge graduate degree until 1928, when Cambridge began granting degrees to women.
By that time, Wills had admirably managed to graduate as a doctor at the London Royal Free Hospital School of Medicine for Women. From the beginning, he knew that he would devote her knowledge to research and teaching in the Department of Pathological Chemistry of the same center in London. For the year 1928 Margaret Balfour contacted her. For several years she served as chief of pathology until her retirement in 1947.
After her retirement, she worked in South Africa and Fiji studying the effects of nutrition on health. During the last ten years of her life, she was a member of the local government for Chelsea. She started working on macrocytic anemia of pregnancy that primarily affects pregnant women in the tropics, with inadequate diets, this work was developed in several areas of India.
This woman is owed several contributions, such as discovering a nutritional factor in yeast that prevents and cures this disorder: the Wills factor or folate, the natural form of folic acid. In that sense, in the year 1930, she showed that anemia could be reversed with brewer’s yeast, which contains folate.
As part of a recognition of her work and the advancement of medicine, on May 10, 2019, the 131st anniversary of her birth, the Google search engine commemorated Wills with a Doodle available for North America, parts of South America and Europe, Israel, India, and New Zealand. Her knowledge changed the face of prenatal preventive care for women around the world.
WORKS
- Studies on blood and urinary chemistry during pregnancy: blood sugar curves.
- Studies in pernicious anemia of pregnancy (1930). This research has 4 parts.
- Treatment of “pernicious anemia” of pregnancy and “tropical anemia” with special reference to yeast extract as a healing agent.
- The nature of the hemopoietic factor in Marmite.
- A new factor in the production and cure of certain macrocytic anemias.
- Tropical macrocytic anemia: its relationship with pernicious anemia.