This article is from the source 'nytimes' and was first published or seen on . It last changed over 40 days ago and won't be checked again for changes.
You can find the current article at its original source at http://www.nytimes.com/2017/03/12/business/lloyd-conover-dead-inventor-of-groundbreaking-antibiotic.html
The article has changed 5 times. There is an RSS feed of changes available.
| Version 0 | Version 1 |
|---|---|
| Lloyd Conover, Inventor of Groundbreaking Antibiotic, Dies at 93 | Lloyd Conover, Inventor of Groundbreaking Antibiotic, Dies at 93 |
| (35 minutes later) | |
| Lloyd H. Conover, a chemist whose breakthrough invention of one of the most effective and widely prescribed antibiotics, tetracycline, led to a whole new approach to developing such drugs, died on Saturday in St. Petersburg, Fla. He was 93. | Lloyd H. Conover, a chemist whose breakthrough invention of one of the most effective and widely prescribed antibiotics, tetracycline, led to a whole new approach to developing such drugs, died on Saturday in St. Petersburg, Fla. He was 93. |
| His death was confirmed by his son Craig. | His death was confirmed by his son Craig. |
| Dr. Conover started his research at Pfizer in Brooklyn in 1950, when pharmaceutical companies, spurred by the success of penicillin against battlefield infections during World War II, were racing to find new antibiotics. Most early antibiotics were naturally occurring chemicals produced by microorganisms that lived in soil or on decaying fruit; the strain of penicillin used to protect wounded soldiers came from a moldy melon. | Dr. Conover started his research at Pfizer in Brooklyn in 1950, when pharmaceutical companies, spurred by the success of penicillin against battlefield infections during World War II, were racing to find new antibiotics. Most early antibiotics were naturally occurring chemicals produced by microorganisms that lived in soil or on decaying fruit; the strain of penicillin used to protect wounded soldiers came from a moldy melon. |
| Few scientists at the time thought it was possible to improve on antibiotics, which they viewed as a result of an evolutionary process that equipped microorganisms with the ultimate chemical weapons to survive. | Few scientists at the time thought it was possible to improve on antibiotics, which they viewed as a result of an evolutionary process that equipped microorganisms with the ultimate chemical weapons to survive. |
| Dr. Conover, however, became intrigued with two naturally occurring antibiotics that, except for two atoms, were chemically identical. To Dr. Conover, the atoms seemed out of place. Each antibiotic had a chlorine or oxygen atom where he expected to find a hydrogen atom. Would swapping in hydrogen improve the potency of the drugs? | Dr. Conover, however, became intrigued with two naturally occurring antibiotics that, except for two atoms, were chemically identical. To Dr. Conover, the atoms seemed out of place. Each antibiotic had a chlorine or oxygen atom where he expected to find a hydrogen atom. Would swapping in hydrogen improve the potency of the drugs? |
| Using a routine chemical procedure, he stripped chlorine from one antibiotic and inserted hydrogen, creating a more stable molecule. He worked with a single assistant. “I didn’t want an audience if we failed,” he told The Cleveland Plain Dealer in 1992. | Using a routine chemical procedure, he stripped chlorine from one antibiotic and inserted hydrogen, creating a more stable molecule. He worked with a single assistant. “I didn’t want an audience if we failed,” he told The Cleveland Plain Dealer in 1992. |
| The result was tetracycline, a powerful antibiotic with fewer side effects than the drug from which it was derived — proof, Dr. Conover wrote, that “a superior drug could be made by chemical modification.” | The result was tetracycline, a powerful antibiotic with fewer side effects than the drug from which it was derived — proof, Dr. Conover wrote, that “a superior drug could be made by chemical modification.” |
| Virtually all antibiotics today are semisynthetic, meaning they are chemically altered to increase the number of infections that can be treated or to reduce side effects. | Virtually all antibiotics today are semisynthetic, meaning they are chemically altered to increase the number of infections that can be treated or to reduce side effects. |
| Hailed as a wonder drug, tetracycline proved effective against numerous potentially deadly infections, including salmonella, which causes food poisoning, and bacteria responsible for bloodstream, skin and urinary infections, gonorrhea, pneumonia and strep throat. | Hailed as a wonder drug, tetracycline proved effective against numerous potentially deadly infections, including salmonella, which causes food poisoning, and bacteria responsible for bloodstream, skin and urinary infections, gonorrhea, pneumonia and strep throat. |
| Hog and chicken farmers embraced the drug, which was used to encourage growth and ward off infections among animals raised in close quarters. Fruit growers sprayed tetracycline in orchards to prevent fire blight and other diseases. | Hog and chicken farmers embraced the drug, which was used to encourage growth and ward off infections among animals raised in close quarters. Fruit growers sprayed tetracycline in orchards to prevent fire blight and other diseases. |
| With tetracycline’s commercial success, however, came a slew of patent challenges. Three pharmaceutical companies claimed that their scientists had discovered tetracycline before Dr. Conover, though their patent applications were filed later. After Pfizer licensed tetracycline to its competitors to end the dispute, the federal government challenged the licensing deals as anticompetitive, along with the validity of the patent. | |
| “I had essentially a second career, preparing for and giving depositions and testifying,” Dr. Conover wrote in a 1984 article in the journal Research Management. | |
| At scientific meetings, he wrote, he felt a coolness from peers who believed that his patent claim was false. A federal appeals court in Philadelphia finally affirmed the patent — and, by extension, the licensing agreements — in 1982, three decades after Dr. Conover invented tetracycline. | At scientific meetings, he wrote, he felt a coolness from peers who believed that his patent claim was false. A federal appeals court in Philadelphia finally affirmed the patent — and, by extension, the licensing agreements — in 1982, three decades after Dr. Conover invented tetracycline. |
| By the time the litigation ended, widespread use of tetracycline had caused many kinds of bacteria to become resistant to the antibiotic, reducing its potency against many infections. | By the time the litigation ended, widespread use of tetracycline had caused many kinds of bacteria to become resistant to the antibiotic, reducing its potency against many infections. |
| Tetracycline is still commonly used against acne and certain tick-borne diseases, such as Lyme disease, Rocky Mountain spotted fever and Q fever. To control bacterial resistance, many European and the United States countries now ban restrict the nontherapeutic use of tetracycline in agriculture. | |
| Lloyd Hillyard Conover was born on June 13, 1923, in Orange, N.J. His father, John, was a lawyer; his mother, the former Marguerite Anna Cameron, an artist. His interest in chemistry began in childhood when he watched his father mix cement to repair a retaining wall. | Lloyd Hillyard Conover was born on June 13, 1923, in Orange, N.J. His father, John, was a lawyer; his mother, the former Marguerite Anna Cameron, an artist. His interest in chemistry began in childhood when he watched his father mix cement to repair a retaining wall. |
| “There was something about the physical change in matter that really fascinated me,” he said in an interview for this obituary. To feed his curiosity, he devised science projects with things he found around his house. In one instance, he took his mother’s pots and pans and melted down lead left behind by a plumber to make a miniature cannon that fired lead pellets, powered by steam. | |
| He entered Amherst College in 1941 to study chemistry, but his education was interrupted by World War II. He spent three years in the Navy, serving on an amphibious ship in the Pacific and rising to lieutenant junior grade. | He entered Amherst College in 1941 to study chemistry, but his education was interrupted by World War II. He spent three years in the Navy, serving on an amphibious ship in the Pacific and rising to lieutenant junior grade. |
| After the war, he returned to Amherst and received his bachelor’s degree in 1947. He received his doctorate in chemistry from the University of Rochester in 1950 and went to work for Pfizer, where salaries were higher than in academia, to support his family. | After the war, he returned to Amherst and received his bachelor’s degree in 1947. He received his doctorate in chemistry from the University of Rochester in 1950 and went to work for Pfizer, where salaries were higher than in academia, to support his family. |
| His first wife, the former Virginia Kirk, died in 1988; his second wife, the former Marie Solomon, died in 2003. | |
| Besides his son Craig, survivors include his wife, the former Katharine Meacham; two other sons, Kirk and Roger; a daughter, Heather Conover; four stepdaughters, Sue Love, Virginia Karopvich, Katharine Meacham and Laura Keane; two stepsons, Walter Solomons and Andrew Meacham; 16 grandchildren; and seven great-grandchildren. | |
| At Pfizer, Dr. Conover was assigned to a team working to determine the chemical structures of the antibiotics oxytetracycline and chlortetracycline — a project that laid the groundwork for Dr. Conover’s discovery. After the team completed its task, the senior scientists went off to write papers about their findings, leaving Dr. Conover with time on his hands. | |
| “Everyone thought that was the end of the project,” Dr. Conover said in the interview. “But I wanted to keep working with these wonderfully interesting molecules.” | “Everyone thought that was the end of the project,” Dr. Conover said in the interview. “But I wanted to keep working with these wonderfully interesting molecules.” |
| Dr. Conover completed his tetracycline experiment in a matter of months. “It worked the first time, unlike most of the experiments I ever ran,” he said. Within a year, Pfizer was testing tetracycline on people. | Dr. Conover completed his tetracycline experiment in a matter of months. “It worked the first time, unlike most of the experiments I ever ran,” he said. Within a year, Pfizer was testing tetracycline on people. |
| Dr. Conover spent his entire career at Pfizer. He went on to help invent Pyrantel and Morantel, which are used to treat parasitic worm infections, and rose through the company’s executive ranks to become senior vice president of agricultural products research and development. He retired in 1984. | Dr. Conover spent his entire career at Pfizer. He went on to help invent Pyrantel and Morantel, which are used to treat parasitic worm infections, and rose through the company’s executive ranks to become senior vice president of agricultural products research and development. He retired in 1984. |
| Although Pfizer vigorously defended Dr. Conover’s patent, the company was less aggressive than competitors in marketing his invention. | Although Pfizer vigorously defended Dr. Conover’s patent, the company was less aggressive than competitors in marketing his invention. |
| “Pfizer sold tetracycline, but never pushed it,” Dr. Conover said. “That was a disappointment.” | “Pfizer sold tetracycline, but never pushed it,” Dr. Conover said. “That was a disappointment.” |