Zhou Yiqing | |
---|---|
周义清 | |
Born | 1929 |
Nationality | Chinese |
Citizenship | People's Republic of China |
Education | PLA Second Military Medical University |
Known for | Invention of Coartem |
Awards | European Inventor Award (2009) |
Scientific career | |
Fields | Medicine |
Institutions | Eighth Route Army Institute of Microbiology and Epidemiology of the People's Liberation Army Academy of Military Medical Sciences |
Zhou Yiqing (born 1929) is a professor of medicine at the Institute of Microbiology and Epidemiology of the People's Liberation Army Academy of Military Medical Sciences. [1] He was one of the scientists who participated in the Project 523 of the Chinese Government under Chairman Mao Zedong. The project resulted in the discovery of artemisinins, a class of antimalarial drugs, from the medicinal plant Artemisia annua . [2] [3]
Zhou specifically worked on artemether, one of the derivatives of artemisinin. In 1985 he combined artemether with another drug lumefantrine into a single tablet, which he successfully used for the treatment of severe malaria. With the support of Novartis, the drug was produced in 1991 under the brand name Coartem, and it became the first artemisinin-based combination therapy. [4] For this invention he and his team were awarded the European Inventor Award of 2009 in the category "Non-European countries". [5]
Zhou was a son of Chinese peasants. At age 16 he was enlisted in the Eighth Route Army of the National Revolutionary Army of China. Having a medical background he served in the healthcare of the army. He was a nurse in the beginning, then the head of a nursing squad, assistant physician and eventually doctor-in-charge during the Second Sino-Japanese War (1937–1945) and throughout the Chinese Civil War. After the civil war he studied medicine at the Second Military Medical University in Shanghai. He graduated in 1960, and then joined the Institute of Microbiology and Epidemiology of the Chinese Academy of Military Medical Sciences as a researcher. [1]
Zhou was among more than 500 Chinese scientists assigned to investigate for a new antimalarial medication during the Cultural Revolution. Established by Mao Zedong-led government in 1967, the collaborative research was called Project 523. In 1972 Tu Youyou and her team discovered artemisinin (originally known as qinghaosu). A more stable compound artemether was synthesised from artemisinin. In 1981 the National Chinese Steering Committee for Development of Qinghaosu (artemisinin) and its Derivatives authorised Zhou to work on artemether. Zhou showed that artemether combined with another antimalarial lumefantrine was the most potent of all antimalarial drugs. He worked alone for four years, and was joined by Ning Dianxi and his team in 1985. They found that in clinical trials the combined tablet (artemether/lumefantrine) had very high cure rate of severe malaria, more than 95%, including in areas where multi-drug resistance is experienced. [6] They applied for patent in 1991, but granted only in 2002. In 1992 they got it registered as a new drug. Novartis then noticed the new drug and made a deal for mass production. [1] In 1999 Novartis obtained the international licensing rights and gave the brand name Coartem. It was approved by the US Food and Drug Administration in 2009. [4]
Malaria is a mosquito-borne infectious disease that affects humans and other vertebrates. Human malaria causes symptoms that typically include fever, fatigue, vomiting, and headaches. In severe cases, it can cause jaundice, seizures, coma, or death. Symptoms usually begin 10 to 15 days after being bitten by an infected Anopheles mosquito. If not properly treated, people may have recurrences of the disease months later. In those who have recently survived an infection, reinfection usually causes milder symptoms. This partial resistance disappears over months to years if the person has no continuing exposure to malaria.
Antimalarial medications or simply antimalarials are a type of antiparasitic chemical agent, often naturally derived, that can be used to treat or to prevent malaria, in the latter case, most often aiming at two susceptible target groups, young children and pregnant women. As of 2018, modern treatments, including for severe malaria, continued to depend on therapies deriving historically from quinine and artesunate, both parenteral (injectable) drugs, expanding from there into the many classes of available modern drugs. Incidence and distribution of the disease is expected to remain high, globally, for many years to come; moreover, known antimalarial drugs have repeatedly been observed to elicit resistance in the malaria parasite—including for combination therapies featuring artemisinin, a drug of last resort, where resistance has now been observed in Southeast Asia. As such, the needs for new antimalarial agents and new strategies of treatment remain important priorities in tropical medicine. As well, despite very positive outcomes from many modern treatments, serious side effects can impact some individuals taking standard doses.
Plasmodium falciparum is a unicellular protozoan parasite of humans, and the deadliest species of Plasmodium that causes malaria in humans. The parasite is transmitted through the bite of a female Anopheles mosquito and causes the disease's most dangerous form, falciparum malaria. It is responsible for around 50% of all malaria cases. P. falciparum is therefore regarded as the deadliest parasite in humans. It is also associated with the development of blood cancer and is classified as a Group 2A (probable) carcinogen.
Artemisia annua, also known as sweet wormwood, sweet annie, sweet sagewort, annual mugwort or annual wormwood, is a common type of wormwood native to temperate Asia, but naturalized in many countries including scattered parts of North America.
Artemisinin and its semisynthetic derivatives are a group of drugs used in the treatment of malaria due to Plasmodium falciparum. It was discovered in 1972 by Tu Youyou, who shared the 2015 Nobel Prize in Physiology or Medicine for her discovery. Artemisinin-based combination therapies (ACTs) are now standard treatment worldwide for P. falciparum malaria as well as malaria due to other species of Plasmodium. Artemisinin is extracted from the plant Artemisia annua a herb employed in Chinese traditional medicine. A precursor compound can be produced using a genetically engineered yeast, which is much more efficient than using the plant.
Artemether is a medication used for the treatment of malaria. The injectable form is specifically used for severe malaria rather than quinine. In adults, it may not be as effective as artesunate. It is given by injection in a muscle. It is also available by mouth in combination with lumefantrine, known as artemether/lumefantrine.
Artesunate (AS) is a medication used to treat malaria. The intravenous form is preferred to quinine for severe malaria. Often it is used as part of combination therapy, such as artesunate plus mefloquine. It is not used for the prevention of malaria. Artesunate can be given by injection into a vein, injection into a muscle, by mouth, and by rectum.
Artemether/lumefantrine, sold under the trade name Coartem among others, is a combination of the two medications artemether and lumefantrine. It is used to treat malaria caused by Plasmodium falciparum that is not treatable with chloroquine. It is not typically used to prevent malaria. It is taken by mouth.
Chlorproguanil/dapsone/artesunate was an experimental antimalarial treatment that entered Phase III clinical trials in 2006. Development was halted because it was associated with an increased risk of haemolytic anaemia in patients with glucose-6-phosphate dehydrogenase deficiency.
Halofantrine is a drug used to treat malaria. Halofantrine's structure contains a substituted phenanthrene, and is related to the antimalarial drugs quinine and lumefantrine. Marketed as Halfan, halofantrine is never used to prevent malaria and its mode of action is unknown, although a crystallographic study showed that it binds to hematin in vitro, suggesting a possible mechanism of action. Halofantrine has also been shown to bind to plasmepsin, a haemoglobin degrading enzyme unique to the malarial parasites.
Dihydroartemisinin is a drug used to treat malaria. Dihydroartemisinin is the active metabolite of all artemisinin compounds and is also available as a drug in itself. It is a semi-synthetic derivative of artemisinin and is widely used as an intermediate in the preparation of other artemisinin-derived antimalarial drugs. It is sold commercially in combination with piperaquine and has been shown to be equivalent to artemether/lumefantrine.
Artelinic acid is an experimental drug that is being investigated as a treatment for malaria. It is a semi-synthetic derivative of the natural compound artemisinin. Artelinic acid has a lower rate of neurotoxicity than the related artemisinin derivatives arteether and artemether, but is three times more toxic than artesunate. At present, artelinic acid seems unlikely to enter routine clinical use, because it offers no clear benefits over the artemesinins already available. Artelinic acid has not yet been evaluated for use in humans.
Lumefantrine is an antimalarial drug. It is only used in combination with artemether. The term "co-artemether" is sometimes used to describe this combination. Lumefantrine has a much longer half-life compared to artemether, and is therefore thought to clear any residual parasites that remain after combination treatment.
Artesunate/amodiaquine, sold under the trade name Camoquin among others, is a medication used for the treatment of malaria. It is a fixed-dose combination of artesunate and amodiaquine. Specifically it recommended for acute uncomplicated Plasmodium falciparum malaria. It is taken by mouth.
Dichroa febrifuga is a flowering plant in the family Hydrangeaceae.
The history of malaria extends from its prehistoric origin as a zoonotic disease in the primates of Africa through to the 21st century. A widespread and potentially lethal human infectious disease, at its peak malaria infested every continent except Antarctica. Its prevention and treatment have been targeted in science and medicine for hundreds of years. Since the discovery of the Plasmodium parasites which cause it, research attention has focused on their biology as well as that of the mosquitoes which transmit the parasites.
Pyronaridine is an antimalarial drug. It was first made in 1970 and has been in clinical use in China since the 1980s.
Project 523 is a code name for a 1967 secret military project of the People's Republic of China to find antimalarial medications. Named after the date the project launched, 23 May, it addressed malaria, an important threat in the Vietnam War. At the behest of Ho Chi Minh, Prime Minister of North Vietnam, Zhou Enlai, the Premier of the People's Republic of China, convinced Mao Zedong, Chairman of the Chinese Communist Party, to start the mass project "to keep [the] allies' troops combat-ready", as the meeting minutes put it. More than 500 Chinese scientists were recruited. The project was divided into three streams. The one for investigating traditional Chinese medicine discovered and led to the development of a class of new antimalarial drugs called artemisinins. Launched during and lasting throughout the Cultural Revolution, Project 523 was officially terminated in 1981.
Tu Youyou is a Chinese malariologist and pharmaceutical chemist. She discovered artemisinin and dihydroartemisinin, used to treat malaria, a breakthrough in twentieth-century tropical medicine, saving millions of lives in South China, Southeast Asia, Africa, and South America.
Moses R Kamya, is a Ugandan physician, academic, researcher and academic administrator, who serves as Professor and Chair of the Department Medicine, Makerere University School of Medicine, a component of Makerere University College of Health Sciences.