A seven-step plan for becoming a moderately rich and famous biochemist.

Omega-6 polyunsaturated fatty acids were identified as essential nutrients in 1930. Their essentiality is largely due to their function as prostaglandin (PG) precursors. I spent most of my career in biochemistry determining how PG biosynthesis is regulated. PGs are lipid mediators formed in response to certain circulating hormones and cytokines. PGs act near their sites of synthesis to signal neighboring cells to coordinate their responses (e.g. when platelets interact with blood vessels). The committed step in PG synthesis is the conversion of a 20-carbon omega-6 fatty acid called arachidonic acid to prostaglandin endoperoxide H2 (PGH2). Depending on the tissue and the hormone or cytokine stimulus, this reaction is catalyzed by either cyclooxygenase-1 or cyclooxygenase-2 (COX-1 or COX-2). Once formed, PGH2 is converted, again depending on the context, to one of several downstream PG subtypes that act via specific G protein-coupled receptors. Nonsteroidal anti-inflammatory drugs (e.g. aspirin, ibuprofen, and naproxen) block PG synthesis by inhibiting COX-1 and COX-2. COX-2 is also inhibited by COX-2-selective inhibitors. Inhibition of COX-1 by low-dose aspirin prevents thrombosis. COX-2 inhibition reduces inflammation and pain. Investigating the mysteries of COXs anchored my scientific career. I attribute my successes to the great good fortune of having been surrounded by people who helped me make the most of my talents. I have written this reflection in a light-hearted fashion as a self-help essay, while highlighting the people and factors that most impacted me during my upbringing and then during my maturation and evolution as a biochemist.

History of NSAID Use in the Treatment of Headaches Pre and Post-industrial Revolution in the United States: the Rise and Fall of Antipyrine, Salicylic Acid, and Acetanilide.

PURPOSE OF REVIEW: Non-steroid anti-inflammatory drugs (NSAIDs) constitute a vital class of medications in today's headache regimen. However, up until the nineteenth century, they were largely unknown to most of the medical community. The purpose of this review is to explore the evolution of NSAIDs in the treatment of headaches spurred on by the Industrial Revolution in the USA. RECENT FINDINGS: The currently available data on the impact of NSAIDs reflects their significant contribution to headache treatment. The emergence of mass production spurred on by the Industrial Revolution, lead to widespread use of antipyrine, salicylic acid, and acetanilide. However, along with it came the growing awareness of consumer safety, leading to their ultimate downfall, and the subsequent birth of the Food and Drug Act.

The first 3500 years of aspirin history from its roots - A concise summary.

Aspirin is currently the most widely used drug worldwide, and has been clearly one of the most important pharmacological achievements of the twentieth century. Historians of medicine have traced its birth in 1897, but the fascinating history of aspirin actually dates back >3500 years, when willow bark was used as a painkiller and antipyretic by Sumerians and Egyptians, and then by great physicians from ancient Greece and Rome. The modern history of aspirin precursors, salicylates, began in 1763 with Reverend Stone - who first described their antipyretic effects - and continued in the 19th century with many researchers involved in their extraction and chemical synthesis. Bayer chemist Felix Hoffmann synthesized aspirin in 1897, and 70 years later the pharmacologist John Vane elucidated its mechanism of action in inhibiting prostaglandin production. Originally used as an antipyretic and anti-inflammatory drug, aspirin then became, for its antiplatelet properties, a milestone in preventing cardiovascular and cerebrovascular diseases. The aspirin story continues today with the growing evidence of its chemopreventive effect against colorectal and other types of cancer, now awaiting the results of ongoing primary prevention trials in this setting. This concise review revisits the history of aspirin with a focus on its most remote origins.

Phenylbutazone (Bute, PBZ, EPZ): one drug across two species.

In this article we explore the different trajectories of this one drug, phenylbutazone, across two species, humans and horses in the period 1950-2000. The essay begins by following the introduction of the drug into human medicine in the early 1950s. It promised to be a less costly alternative to cortisone, one of the "wonder drugs" of the era, in the treatment of rheumatic conditions. Both drugs appeared to offer symptomatic relief rather than a cure, and did so with the risk of side effects, which with phenylbutazone were potentially so severe that it was eventually banned from human use, for all but a few diseases, in the early 1980s. Phenylbutazone had been used with other animals for many years without the same issues, but in the 1980s its uses in veterinary medicine, especially in horses, came under increased scrutiny, but for quite different reasons. The focus was primarily the equity, economics, and ethics of competition in equine sports, with differences in cross-species biology and medicine playing a secondary role. The story of phenylbutazone, a single drug, shows how the different biologies and social roles of its human/animal subjects resulted in very different and changing uses. While the drug had a seemingly common impact on pain and inflammation, there were inter-species differences in the drug's metabolism, the conditions treated, dosages, and, crucially, in intended clinical outcomes and perceptions of its benefits and risks.

The aspirin story - from willow to wonder drug.

The story of the discovery of aspirin stretches back more than 3500 years to when bark from the willow tree was used as a pain reliever and antipyretic. It involves an Oxfordshire clergyman, scientists at a German dye manufacturer, a Nobel Prize-winning discovery and a series of pivotal clinical trials. Aspirin is now the most commonly used drug in the world. Its role in preventing cardiovascular and cerebrovascular disease has been revolutionary and one of the biggest pharmaceutical success stories of the last century.

The evil of the unknown--risk-benefit evaluation of new synthetic drugs in the 19th century.

In the 19th century, synthetic chemistry discovered completely new chemical entities for medicinal use, which dramatically enriched the therapeutic armamentarium. However, no information was available regarding the safety of these new drugs, which were unrelated to most of the medicinal agents formerly known. Therefore, the question arises, if and how far, considerations regarding the relationship between benefit and risks were made. In this study, chloroform, phenazone (antipyrine) and sulfonal, were investigated as examples for drugs newly introduced in the 19th century. The results revealed that these drugs were provided by the manufacturer, tested by the physicians in a multicentre pattern and side effects were published in the medical literature soon after. Within a few years, several hundred cases were reported but the data were rarely summarized statistically. Therefore, physicians needed to stay updated with the medical literature because neither systematic industrial research nor regulatory authorities existed. The number of case reports within the first years were sufficient to detect common (> 1/100 to < 1/10) side effects but rare events were also reported. An extraordinary example is the drug-induced toxic epidermal necrolysis, which is commonly known as the Lyell syndrome or its less severe form, the Stevens-Johnson syndrome. This reaction has been clearly described by Baruch Spitz (1854-1932) as a side effect of antipyrine in 1887, several decades before Stevens, Johnson and particularly Lyell.

Origins and impact of the term 'NSAID'.

This article is an historical investigation of the term non-steroidal anti-inflammatory drugs and its acronym NSAIDs. Drug names and categories tend to be taken at face value in everyday practice, as natural categories existing in their own right. The main argument of this article is that the term NSAID is a reminder that drug names and categories are complex cultural and social products that have been created by specific people, for specific purposes, through specific historical processes, and that this is relevant for their use today. The article locates the first appearances of the phrase non-steroidal at the entry to the 1960s, when the iatrogenic tragedies that followed from the introduction of corticosteroids had become apparent, and where a clear separation between these drugs and emerging anti-inflammatory alternatives was needed. The article then shows how both the phrase and the acronym appeared for the first time out of specific textual contexts in publications by Michael W. Whitehouse, before they were taken up by a wider community and transformed into concepts independent on the context of their first appearances.

Aspirin hypersensitivity.

Hypersensitivity reactions to acetylsalicylic acid and non-steroidal anti-inflammatory drugs constitute a major medical concern worldwide. This article presents an overview of the observations that led to the discovery of cyclooxygenase inhibitors, as a prerequisite to better understand the basic concepts supporting seminal investigations carried out in order to elucidate the clinical features, pathogenic mechanisms, diagnosis and modern management of these common conditions. There are some unmet needs in this clinical area which will have to be solved in the future, especially concerning the pathogenesis of these reactions and the availability of novel in vitro diagnostic methods sparing both patient and physician of the risks inherent to in vivo provocation tests.

Introduction: Szczeklik's contributions to our understanding of aspirin, NSAIDs, asthma, and allergy.

Andrew Szczeklik was born in 1938 and died on Feb 3rd, 2012. He was the most influential expert in the field of aspirin and NSAID sensitivity reactions and associated diseases in the world. This edition of NACAI is dedicated to Andrew. In the introductory chapter, we elected to highlight his accomplishments as reflected in his publications. Andrew published at least 503 articles including many invited review articles. We present 20 of his most important publications all of which contributed significantly to our understanding of these diseases.

Classification of reactions to nonsteroidal antiinflammatory drugs.

Hypersensitivity reactions to NSAIDs may occur in susceptible individuals and vary in symptom (skin, respiratory tract, and solid organs), severity (from mild skin or respiratory reactions to severe generalized) and timing (from acute to delayed). The current classification of NSAID-induced reactions emerged with the understanding of the pathologic mechanism of reactions to NSAIDs which may be either non-allergic (related to cyclooxygenase inhibition) or immunologically mediated. In this chapter we discuss the implications of accurate NSAIDs hypersensitivity classification for proper diagnosis and patient management.

Aspirin desensitization in aspirin-exacerbated respiratory disease.

Although aspirin desensitization was discovered in 1922, it was not until 1979 that a therapeutic use for aspirin treatment, under the protection of desensitization, was discovered. In the last 33 years, details of aspirin treatment have been refined to the point where it is now recognized and accepted as a major therapeutic intervention in the treatment of aspirin-exacerbated respiratory disease, with therapeutic efficacy in approximately two-thirds of patients. It is only effective in patients who have aspirin-exacerbated respiratory disease and none of the other nonsteroidal anti-inflammatory drugs, despite their cross-reactive inhibition of cyclooxygenase-1, can effectively take the place of aspirin.