Paul Ehrlich
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| Born | 14 March 1854
Strehlen, Lower Silesia, Prussia (now Strzelin, Poland)
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| Died | 20 August 1915 (aged 61)
Bad Homburg, Hesse, Germany
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| Citizenship | German |
| Known for | Chemotherapy, Immunology |
| Spouse(s) | Hedwig Pinkus (1864–1948) (m. 1883; 2 children) |
| Children | Stephanie and Marianne |
| Awards | Nobel Prize in Physiology or Medicine (1908) |
| Scientific career | |
| Fields | Immunology |
| Notable students | Hans Schlossberger |
| Signature | |
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Paul Ehrlich was a Nobel prize-winning German-Jewish physician and scientist who worked in the fields of hematology, immunology, and antimicrobial chemotherapy. He is credited with finding a cure for syphilis in 1909. He invented the precursor technique to Gram staining bacteria. The methods he developed for staining tissue made it possible to distinguish between different types of blood cells, which led to the capability to diagnose numerous blood diseases.
His laboratory discovered arsphenamine (Salvarsan), the first effective medicinal treatment for syphilis, thereby initiating and also naming the concept of chemotherapy. Ehrlich popularized the concept of a magic bullet. He also made a decisive contribution to the development of an antiserum to combat diphtheria and conceived a method for standardizing therapeutic serums.
In 1908, he received the Nobel Prize in Physiology or Medicine for his contributions to immunology. He was the founder and first director of what is now known as the Paul Ehrlich Institute.
Life and career
Paul Ehrlich was the second child of Rosa (Weigert) and Ismar Ehrlich.
His father was an innkeeper and distiller of liqueurs and the royal
lottery collector in Strehelen, a town of some 5,000 inhabitants in the
province of Lower Silesia,
now in Poland. His grandfather, Heymann Ehrlich, had been a fairly
successful distiller and tavern manager. Ismar Ehrlich was the leader of
the local Jewish community.
After elementary school, Paul attended the time-honored secondary school Maria-Magdalenen-Gymnasium in Breslau, where he met Albert Neisser, who later became a professional colleague. As a schoolboy (inspired by his cousin Karl Weigert who owned one of the first microtomes),
he became fascinated by the process of staining microscopic tissue
substances. He retained that interest during his subsequent medical
studies at the universities of Breslau, Strasbourg, Freiburg im Breisgau and Leipzig. After obtaining his doctorate in 1882, he worked at the Charité in Berlin as an assistant medical director under Theodor Frerichs, the founder of experimental clinical medicine, focusing on histology, hematology and color chemistry (dyes).
He married Hedwig Pinkus (1864–1948) in 1883 in the synagogue in Neustadt. The couple had two daughters, Stephanie and Marianne. Hedwig was a sister of Max Pinkus, who was an owner of the textile factory in Neustadt (later known as ZPB "Frotex").
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Commemorative plaque at Bergstraße 96 in Berlin-Steglitz, where Ehrlich lived and worked from 1890 to 1899
After completing his clinical education and habilitation at the prominent Charité medical school and teaching hospital in Berlin in 1886, Ehrlich traveled to Egypt
and other countries in 1888 and 1889, in part to cure a case of
tuberculosis which he had contracted in the laboratory. Upon his return
he established a private medical practice and small laboratory in
Berlin-Steglitz. In 1891, Robert Koch
invited Ehrlich to join the staff at his Berlin Institute of Infectious
Diseases, where in 1896 a new branch, the Institute for Serum Research
and Testing (Institut für Serumforschung und Serumprüfung), was established for Ehrlich's specialization. Ehrlich was named its founding director.
Ehrlich's grave in the Jewish cemetery on Rat-Beil-Straße in Frankfurt am Main
In 1899 his institute moved to Frankfurt am Main and was renamed the Institute of Experimental Therapy (Institut für experimentelle Therapie).
One of his important collaborators there was Max Neisser. In 1904,
Ehrlich received a full position of honorary professor from the University of Göttingen.
In 1906 Ehrlich became the director of the Georg Speyer House in
Frankfurt, a private research foundation affiliated with his institute.
Here he discovered in 1909 the first drug to be targeted against a
specific pathogen: Salvarsan,
a treatment for syphilis, which was at that time one of the most lethal
and infectious diseases in Europe. Among the foreign guest scientists
working with Ehrlich were two Nobel Prize winners, Henry Hallett Dale and Paul Karrer. The institute was renamed Paul Ehrlich Institute in Ehrlich's honour in 1947.
In 1914 Ehrlich signed the controversial Manifesto of the Ninety-Three
which was a defense of Germany's World War I politics and militarism.
On 17 August 1915 Ehrlich suffered a heart attack and died on 20 August
in Bad Homburg vor der Höhe. Wilhelm II
the German emperor, wrote in a telegram of condolence, “I, along with
the entire civilized world, mourn the death of this meritorious
researcher for his great service to medical science and suffering
humanity; his life’s work ensures undying fame and the gratitude of both
his contemporaries and posterity”.
Paul Ehrlich was buried at the Old Jewish Cemetery, Frankfurt (Block 114 N).
Research
Hematological staining
In the early 1870s, Ehrlich's cousin Karl Weigert
was the first person to stain bacteria with dyes and to introduce
aniline pigments for histological studies and bacterial diagnostics.
During his studies in Strassburg under the anatomist Heinrich Wilhelm Waldeyer,
Ehrlich continued the research started by his cousin in pigments and
staining tissues for microscopic study. He spent his eighth university
semester in Freiburg im Breisgau investigating primarily the red dye
dahlia (monophenylrosanilin), giving rise to his first publication.
In 1878 he followed his dissertation supervisor Julius Friedrich Cohnheim
to Leipzig, and that year obtained a doctorate with a dissertation
entitled "Contributions to the Theory and Practice of Histological
Staining" (Beiträge zur Theorie und Praxis der histologischen Färbung).
Photo of cultured mast cells at 100X stained with Tol Blue
One of the most outstanding results of his dissertation
investigations was the discovery of a new cell type. Ehrlich discovered
in the protoplasm of supposed plasma cells
a granulate which could be made visible with the help of an alkaline
dye. He thought this granulate was a sign of good nourishment, and
accordingly named these cells mast cells, (from the German word for an animal-fattening feed, Mast).
This focus on chemistry was unusual for a medical dissertation. In it,
Ehrlich presented the entire spectrum of known staining techniques and
the chemistry of the pigments employed.
While he was at the Charité, Ehrlich elaborated upon the differentiation
of white blood cells according to their different granules. A
precondition was a dry specimen technique, which he also developed. A
drop of blood placed between two glass slides and heated over a Bunsen
burner fixed the blood cells while still allowing them to be stained.
Ehrlich used both alkaline and acid dyes, and also created new “neutral”
dyes. For the first time this made it possible to differentiate the lymphocytes among the leucocytes
(white blood cells). By studying their granulation he could distinguish
between nongranular lymphocytes, mono- and poly-nuclear leucocytes, eosinophil granulocytes, and mast cells.
Starting in 1880, Ehrlich also studied red blood cells. He demonstrated the existence of nucleated red blood cells, which he subdivided
into normoblasts, megaloblasts, microblasts and poikiloblasts; he had
discovered the precursors of erythrocytes. Ehrlich thus also laid the
basis for the analysis of anemias, after he had created the basis for systematizing leukemias with his investigation of white blood cells.
His duties at the Charité included analyzing patients’ blood and
urine specimens. In 1881 he published a new urine test which could be
used to distinguish various types of typhoid from simple cases of
diarrhea. The intensity of staining made possible a disease prognosis.
The pigment solution he used is known today as Ehrlich's reagent.
Ehrlich's great achievement, but also a source of problems during his
further career, was that he had initiated a new field of study
interrelating chemistry, biology and medicine. Much of his work was
rejected by the medical profession, which lacked the requisite chemical
knowledge. It also meant that there was no suitable professorship in
sight for Ehrlich.
Serum research
Friendship with Robert Koch
Robert Koch, around 1900
When a student in Breslau, Ehrlich was given an opportunity by the
pathologist Julius Friedrich Cohnheim to conduct extensive research and
was also introduced to Robert Koch,
who was at the time a district physician in Wollstein, Posen Province.
In his spare time, Koch had clarified the life cycle of the anthrax pathogen and had contacted Ferdinand Cohn,
who was quickly convinced by Koch's work and introduced him to his
Breslau colleagues. From 30 April to 2 May 1876, Koch presented his
investigations in Breslau, which the student Paul Ehrlich was able to
attend.
On 24 March 1882, Ehrlich was present when Robert Koch, working since 1880 at the Imperial Public Health Office (Kaiserliches Gesundheitsamt) in Berlin, presented the lecture in which he reported how he was able to identify the tuberculosis pathogen.
Ehrlich later described this lecture as his “greatest experience in
science.” The day after Koch's lecture, Ehrlich had already made an
improvement to Koch's staining method, which Koch unreservedly welcomed.
From this date on, the two men were bound in friendship.
In 1887 Ehrlich became an unsalaried lecturer in internal medicine (Privatdozent für Innere Medizin)
at Berlin University, and in 1890 took over the tuberculosis station at
a public hospital in Berlin-Moabit at Koch's request. This was where
Koch's hoped-for tuberculosis therapeutic agent tuberculin was under study; and Ehrlich had even injected himself with it. In the ensuing tuberculin scandal,
Ehrlich tried to support Koch and stressed the value of tuberculin for
diagnostic purposes. In 1891 Koch invited Ehrlich to work at the newly
founded Institute of Infectious Diseases (Institut für Infektionskrankheiten – now the Robert Koch Institute) at Friedrich-Wilhelms-Universität
(now Humboldt University) in Berlin. Koch was unable to give him any
remuneration, but did offer him full access to laboratory staff,
patients, chemicals and laboratory animals, which Ehrlich always
remembered with gratitude.
First work on immunity
Ehrlich had started his first experiments on immunization already in his private laboratory. He accustomed mice to the poisons ricin and abrin.
After feeding them with small but increasing dosages of ricin he
ascertained that they had become "ricin-proof." Ehrlich interpreted this
as immunization and observed that it was abruptly initiated after a few
days and was still in existence after several months, but mice
immunized against ricin were just as sensitive to abrin as untreated
animals.
This was followed by investigations on the "inheritance" of acquired immunity. It was already known that in some cases after a smallpox
or syphilis infection, specific immunity was transmitted from the
parents to their offspring. Ehrlich rejected inheritance in the genetic
sense because the offspring of a male mouse immunized against abrin and
an untreated female mouse were not immune to abrin. He concluded that
the fetus was supplied with antibodies
via the pulmonary circulation of the mother. This idea was supported by
the fact that this “inherited immunity” decreased after a few months.
In another experiment he exchanged the offspring of treated and
untreated female mice. The mice which were nursed by the treated females
were protected from the poison, providing the proof that antibodies can
also be conveyed in milk.
Ehrlich also researched autoimmunity,
but he specifically rejected the possibility that an organism's immune
system could attack the organism's own tissue calling it "horror
autotoxicus." Ironically it was Ehrlich's student, Ernest Witebsky, who demonstrated that autoimmunity could cause disease in humans.
Work with Behring on a diphtheria serum
Emil Behring had worked at the Berlin Institute of Infectious Diseases until 1893 on developing an antiserum for treating diphtheria and tetanus
but with inconsistent results. Koch suggested that Behring and Ehrlich
cooperate on the project. This joint work was successful to the extent
that Ehrlich was quickly able to increase the level of immunity of the
laboratory animals based on his experience with mice. Clinical tests
with diphtheria serum early in 1894 were successful and in August the
chemical company Hoechst started to market Behring's “Diphtheria Remedy
synthesized by Behring-Ehrlich.” The two discoverers had originally
agreed to share any profits after the Hoechst share had been subtracted.
Their contract was changed several times and finally Ehrlich was
eventually pressured into accepting a profit share of only eight
percent. Ehrlich resented what he considered as unfair treatment, and
his relationship with Behring was thereafter problematic, a situation
which later escalated over the issue of the valency of tetanus serum. Ehrlich recognized that the principle of serum therapy had been developed by Behring and Kitasato.
But he was of the opinion that he had been the first to develop a serum
which could also be used on humans, and that his role in developing the
diphtheria serum had been insufficiently acknowledged. Behring, for his
part, schemed against Ehrlich at the Prussian Ministry of Culture, and
from 1900 on Ehrlich refused to collaborate with him. von Behring was
the sole recipient of the first Nobel Prize in Medicine, in 1901, for
contributions to research on diphtheria.
The valency of serums
Commemorative plaque at the entrance of the anatomy institute of Freiburg Univeristy where Paul Ehrlich, as a medical student in the winter semester 1875/76, discovered the mast cells.
Since antiserums were an entirely new type of medicine whose quality
was highly variable, a government system was established to guarantee
their safety and effectiveness. Beginning 1 April 1895, only
government-approved serum could be sold in the German Reich. The testing
station for diphtheria serum was provisionally housed at the Institute
of Infectious Diseases. At the initiative of Friedrich Althoff, an Institute of Serum Research and Testing (Institut für Serumforschung und Serumprüfung)
was established in 1896 in Berlin-Steglitz, with Paul Ehrlich as
director (which required him to cancel all his contracts with Hoechst).
In this function and as honorary professor at Berliner University he had
annual earnings of 6,000 marks, approximately the salary of a
university professor. In addition to a testing department the institute
also had a research department.
In order to determine the effectiveness of diphtheria antiserum, a stable concentration of diphtheria toxin
was required. Ehrlich discovered that the toxin being used was
perishable, in contrast to what had been assumed, which for him led to
two consequences: He did not use the toxin as a standard, but instead a
serum powder developed by Behring, which had to be dissolved in liquid
shortly before use. The strength of a test toxin was first determined in
comparison with this standard. The test toxin could then be used as a
reference for testing other serums. For the test itself, toxin and serum
were mixed in a ratio so that their effects just cancelled each other
when injected into a guinea pig. But since there was a large margin in
determining whether symptoms of illness were present, Ehrlich
established an unambiguous target: the death of the animal. The mixture
was to be such that the test animal would die after four days. If it
died earlier, the serum was too weak and was rejected. Ehrlich claimed
to have made the determination of the valency of serum as accurate as it
would be with chemical titration. This again demonstrates his tendency to quantify the life sciences.
Influenced by the mayor of Frankfurt am Main, Franz Adickes, who
endeavored to establish science institutions in Frankfurt in preparation
of the founding of a university, Ehrlich's institute moved to Frankfurt
In 1899 and was renamed the Royal Prussian Institute of Experimental
Therapy (Königlich Preußisches Institut für Experimentelle Therapie).
The German quality-control methodology was copied by government serum
institutes all over the world, and they also obtained the standard serum
from Frankfurt. After diphtheria antiserum, tetanus serum and various
bactericide serums for use in veterinary medicine were developed in
rapid sequence. These were also evaluated at the institute, as was tuberculin and later on various vaccines. Ehrlich's most important colleague at the institute was the Jewish doctor and biologist Julius Morgenroth.
Ehrlich’s side-chain theory
Paul Ehrlich around 1900 in his Frankfurt office
He postulated that cell protoplasm contains special structures which have chemical side chains (today's term is macromolecules)
to which the toxin binds, affecting function. If the organism survives
the effects of the toxin, the blocked side-chains are replaced by new
ones. This regeneration can be trained, the name for this phenomenon
being immunization. If the cell produces a surplus of side chains, these might also be released into the blood as antibodies.
In the following years Ehrlich expanded his side chain theory
using concepts (“amboceptors,” “receptors of the first, second and third
order,” etc.) which are no longer customary. Between the antigen and
the antibody he assumed there was an additional immune molecule, which
he called an “additive” or a “complement.” For him, the side chain
contained at least two functional groups.
For providing a theoretical basis for immunology as well as for
his work on serum valency, Ehrlich was awarded the Nobel Prize for
Physiology or Medicine in 1908 together with Élie Metchnikoff. Metchnikoff, who had researched the cellular branch of immunity, Phagocytosis, at the Pasteur Institute had previously sharply attacked Ehrlich.
Cancer research
In
1901, the Prussian Ministry of Finance criticized Ehrlich for exceeding
his budget and as a consequence reduced his income. In this situation
Althoff arranged a contact with Georg Speyer, a Jewish philanthropist
and joint owner of the bank house Lazard Speyer-Ellissen. The cancerous
disease of Princess Victoria,
the widow of the German Emperor Friedrich II, had received much public
attention and prompted a collection among wealthy Frankfurt citizens,
including Speyer, in support of cancer research. Ehrlich had also
received from the German Emperor Wilhelm II
a personal request to devote all his energy to cancer research. Such
efforts led to the founding of a department for cancer research
affiliated with the Institute of Experimental Therapy. The chemist Gustav Embden,
among others, worked there. Ehrlich informed his sponsors that cancer
research meant basic research, and that a cure could not be expected
soon.
Among the results achieved by Ehrlich and his research colleagues
was the insight that when tumors are cultivated by transplanting tumor
cells, their malignancy increases from generation to generation. If the
primary tumor is removed, then metastasis
precipitously increases. Ehrlich applied bacteriological methods to
cancer research. In analogy to vaccination, he attempted to generate
immunity to cancer by injecting weakened cancer cells. Both in cancer
research and chemotherapy research (see below) he introduced the
methodologies of Big Science.
Chemotherapy
In vivo staining
In 1885 Ehrlich‘s monograph "The Need of the Organism for Oxygen," (Das Sauerstoffbedürfnis des Organismus- Eine farbenanalytische Studie) appeared, which he also submitted as a habilitation
thesis. In it he introduced the new technology of in vivo staining. One
of his findings was that pigments can only be easily assimilated by
living organisms if they are in granular form. He injected the dyes alizarin blue and indophenol
blue into laboratory animals and established after their death that
various organs had been colored to different degrees. In organs with
high oxygen saturation, indophenol was retained; in organs with medium
saturation, indophenol was reduced, but not alizarin blue. And in areas
with low oxygen saturation, both pigments were reduced. With this work,
Ehrlich also formulated the conviction which guided his research: that
all life processes can be traced to processes of physical chemistry occurring in the cell.
Methylene blue
Staining in vivo with methylene blue of a cell from the mucous membrane of a human mouth
In the course of his investigations Ehrlich came across methylene blue,
which he regarded as particularly suitable for staining bacteria.
Later, Robert Koch also used methylene blue as a dye in his research on
the tuberculosis pathogen. In Ehrlich's view, an added benefit was that
methylene blue also stained the long appendages of nerve cells, the axons.
He initiated a doctoral dissertation on the subject, but did not follow
up the topic himself. It was the opinion of the neurologist Ludwig Edinger that Ehrlich had thereby opened up a major new topic in the field of neurology.
After mid-1889, when Ehrlich was unemployed, he privately
continued his research on methylene blue. His work on in vivo staining
gave him the idea of using it therapeutically. Since the parasite family
of Plasmodiidae – which includes the malaria
pathogen – can be stained with methylene blue, he thought it could
possibly be used in the treatment of malaria. In the case of two
patients so treated at the city hospital in Berlin-Moabit, their fever
indeed subsided and the malaria plasmodia disappeared from their blood.
Ehrlich obtained methylene blue from the company Meister Lucius &
Brüning AG (later renamed Hoechst AG), which started a long
collaboration with this company.
The search for a chemotherapia specifica
Before
the Institute of Experimental Therapy had moved to Frankfurt, Ehrlich
had already resumed work on methylene blue. After the death of Georg
Speyer, his widow Franziska Speyer endowed the Georg-Speyer House in his
memory
which was erected next door to Ehrlich's institute. As director of the
Georg-Speyer House, Ehrlich transferred his chemotherapeutic research
there. He was looking for an agent which was as effective as methylene
blue, but without its side effects. His model was on the one hand the
impact of quinine
on malaria, and on the other hand, in analogy to serum therapy, he
thought there must also be chemical pharmaceuticals which would have
just as specific an effect on individual diseases. His goal was to find a
"Therapia sterilisans magna," in other words a treatment that could
kill all disease pathogens.
Dr. Paul Ehrlich and Dr. Sahachiro Hata
As a model for experimental therapy Ehrlich used a guinea pig disease trypanosoma
and tested out various chemical substances on laboratory animals. The
trypanosomes could indeed be successfully killed with the dye trypan
red. Beginning in 1906, he intensively investigated atoxyl
and had it tested by Robert Koch along with other arsenic compounds
during Koch's sleeping sickness expedition of 1906/07. Although the name
literally means “nonpoisonous,” atoxyl does cause damage, especially to
the optic nerve. Ehrlich elaborated the systematic testing of chemical
compounds in the sense of screening as now practiced in the
pharmaceutical industry. He discovered that Compound 418 -
Arsenophenylglycine - had an impressive therapeutic effect and had it
tested in Africa.
With the support of his assistant Sahachiro Hata Ehrlich discovered in 1909 that Compound 606, Arsphenamine, effectively combatted "spirillum" spirochaetes bacteria, one of whose subspecies causes syphilis.
The compound proved to have few side effects in human trials, and the
spirochetes disappeared in seven syphilis patients after this treatment.
After extensive clinical testing (all the research participants
had the negative example of tuberculin in mind) the Hoechst company
began to market the compound toward the end of 1910 under the name
Salvarsan. This was the first agent with a specific therapeutic effect
to be created on the basis of theoretical considerations. Salvarsan
proved to be amazingly effective, particularly when compared with the
conventional therapy of mercury salts. Manufactured by Hoechst AG,
Salvarsan became the most widely prescribed drug in the world. It was
the most effective drug for treating syphilis until penicillin became
available in the 1940s. Salvarsan required improvement as to side effects and solubility and was replaced in 1911 with Neosalvarsan. Ehrlich's work illuminated the existence of the blood-brain barrier, although he himself never believed in such a barrier, with Professor Lina Stern later coining the phrase.
The medication triggered the so-called "Salvarsan war." On one
side there was hostility on the part of those who feared a resulting
moral breakdown of sexual inhibitions. Ehrlich was also accused, with
clearly anti-Semitic undertones, of excessively enriching himself. In addition, Ehrlich's associate, Paul Uhlenhuth claimed priority in discovering the drug.
Because some people died during the clinical testing, Ehrlich was
accused of "stopping at nothing." In 1914, one of the most prominent
accusers was convicted of criminal libel at a trial for which Ehrlich
was called to testify. Though Ehrlich was thereby exonerated, the ordeal
threw him into a depression from which he never fully recovered.
Magic bullet
Ehrlich
reasoned that if a compound could be made that selectively targeted a
disease-causing organism, then a toxin for that organism could be
delivered along with the agent of selectivity. Hence, a "magic bullet" (magische Kugel,
his term for an ideal therapeutic agent) would be created that killed
only the organism targeted. The concept of a "magic bullet" has to some
extent been realized by the development of antibody-drug conjugates
(a monoclonal antibody linked to a cytotoxic biologically active drug),
as they enable cytotoxic drugs to be selectively delivered to their
designated targets (e.g. cancer cells).
Legacy
West German postage stamp (1954) commemorating Paul Ehrlich and Emil von Behring
In 1910, a street was named after Ehrlich in Frankfurt-Sachsenhausen. During the Third Reich, Ehrlich's achievements were ignored while Emil Adolf von Behring was stylized as the ideal Aryan
scientist, and the street named after Ehrlich was given another name.
Shortly after the end of the war the name Paul-Ehrlich-Strasse was
reinstated, and today numerous German cities have streets named after
Paul Ehrlich.
West Germany issued a postage stamp in 1954 on the 100th
anniversary of the births of Paul Ehrlich (14 March 1854) and Emil von
Behring (15 March 1854).
A 200 Deutsche Mark bank note featured Paul Ehrlich.
The German Paul Ehrlich Institute, the successor to the Steglitz
Institute for Serum Research and Serum Testing and the Frankfurt Royal
Institute for Experimental Therapy, was named in 1947 after its first
director, Paul Ehrlich.
1996 series 200 Deutsche Mark banknote
His name is also borne by many schools and pharmacies, by the
Paul-Ehrlich-Gesellschaft für Chemotherapie e. V. (PEG) in Frankfurt am
Main, and the Paul-Ehrlich-Klinik in Bad Homburg vor der Höhe. The Paul Ehrlich and Ludwig Darmstaedter Prize
is the most distinguished German award for biomedical research. A
European network of PhD studies in Medicinal Chemistry has been named
after him (Paul Ehrlich MedChem Euro PhD Network).
The Anti-Defamation League awards a Paul Ehrlich–Günther K. Schwerin Human Rights Prize.
A crater of the moon was named after Paul Ehrlich in 1970.
Ehrlich's life and work was featured in the 1940 U.S. film Dr. Ehrlich's Magic Bullet with Edward G. Robinson in the title role. It focused on Salvarsan (arsphenamine, "compound 606"),
his cure for syphilis. Since the Nazi government was opposed to this
tribute to a Jewish scientist, attempts were made to keep the film a
secret in Germany.
Honors and titles
- 1882 Awarded the title of Professor
- 1890 Appointed Extraordinary Professor at the Friedrich-Wilhelms-Universität (now Humboldt University)
- 1896 Given the nonacademic Prussian title of a Medical Councillor (Geheimer Medizinalrat)
- 1903 Awarded Prussia's highest distinction in science, the Great Golden Medal of Science (which had previously been awarded only to Rudolf Virchow)
- 1904 Honorary professorship in Göttingen; honorary doctorate from the University of Chicago
- 1907 Granted the seldom-awarded title Senior Medical Councillor (Geheimer Obermedizinalrat); granted an honorary doctorate from Oxford University
- 1908 Awarded The Nobel Prize in Physiology or Medicine for his “work on immunity"
- 1911 Granted Prussia's highest civilian award, Privy Councillor (Wirklicher Geheimer Rat with the predicate “Excellency”)
- 1912 Made an honorary citizen of the city of Frankfurt a.M. and of his birthplace Strehlen
- 1914 Appointed full Professor of Pharmacology at the newly established Frankfurt University.
