Waging war on microbes

The sentences "You have a viral infection? You should take antibiotics!" has always been an anathema to microbiologists. However, this thread of logic is surprisingly commonplace. Therefore, before delving into the history of antibiotics it is important to set the record straight. Antibiotics usually are used to treat bacterial infections. Therefore, antibiotics are completely ineffective against viruses, which are inhibited by antiviral drugs. The discovery of antimicrobial drugs was based on the underlying principle of microbial war- in nature microbes are always battling each other in order to dominate a particular habitat. Sometimes this entails secreting toxic molecules that can destroy other microbes, clearing the playground for the the host microbe to dominate. Thus, some of earliest antibiotics were discovered when scientists chanced upon these molecules and then used them to combat bacterial infections.

The earliest records of treating microbial infections date back to ancient Egypt in 1500 BC. By trial and error, they discovered that bread that had been infected by fungus could be used to cure bacterial infections. As disgusting as this may sound, this treatment was commonplace all over the world: Greeks in 16th century BC would use fungus scraped from cheese to treat wounded soldiers, the Chinese used moldy soya beans, and aborigines in Australia used mold that grew in the shade of eucalyptus trees. A more palatable source of antibiotics was discovered in the 1990s during the investigation of Nubian mummies. These mummies, dated back to 350-550 AD, contained the antibiotic tetracycline in their bones. This antibiotic, named because of it's four-ringed structure was produced from contaminating Streptomyces bacteria which grew in beer; the bacteria were competing against the yeast that was also present in the beer, leading to the production of the antibiotic.

Figure 1: The fungus responsible for moldy bread, Aspergillus species, as viewed under a microscope. Aspergillus is still used to produce antibiotics. Interestingly, this bacteria was given its name because its shape resembles a holy water sprinkler (aspergillum). Source.

The systematic search for antibiotics began with the observation that bacteria could be stained with certain dyes. Therefore, it could be argued that if dyes could enter bacterial cells, there were chemicals which do the same and could be used to kill bacteria. In 1889, Paul Ehrlich, a German physician, pursued this thread of logic to search for such bactericidal chemicals. In 1900 he hypothesized the concept of a magic bullet, a compound that could be used to only kill bacteria without damaging the human body. After several trials, he was successful in finding the first magic bullet in 1909; the compound Salvarsan, meaning saving arsenic, was very effective in curing syphilis, which is caused by the bacteria Treponema pallidum. Although this drug became an instant success around the world, it was controversial because it was thought to promote promiscuity. Furthermore, because of the serious side effects, Ehrlich was accused of criminal negligence in what came to be known as the Salvarsan Wars. Another famous synthesized antibiotic, Prontosil, was developed in 1932. This antibiotic was the first sulfonamide drug. Unlike Salvarsan, Prontosil and other sulfa drugs were effective against a wide range of infectious bacteria, which was why they remained popular well into World War II. In fact, the dependance of the German troops on these drugs ultimately tipped the balance of the war in favor of the Allied troops as discussed below.

Figure 2: Salvarsan was also known as compound 606 because it was sixth in the sixth group of chemicals that were synthesized for testing their antibiotic activity. Source.

The antagonism between mold and bacteria was observed by several scientists in the 19th century who recognized specific strains of fungi, such as Penicillium that is used to produce cheese, would also be resistant to bacterial contamination. The specific molecule, penicillin, that was responsible for this inhibition was recognized in 1928 by Alexander Fleming, a Scottish physician. The discovery of penicillin is best described by the quote "Chance favors the prepared mind" by Louis Pasteur, another giant in the field of microbiology. The story is that Fleming was on the search for a compound that could inhibit the growth of bacteria. To this end, he was studying the properties of staphylococci, a group of bacteria that frequently colonize the skin and upper respiratory tract of animals resulting in infections. Fleming's lab was frequently untidy, and as a result some of the cultures of the bacteria were contaminated by a fungus. He noticed that the bacterial colonies that were close to the fungus were killed, but those further away remained normal. Upon seeing this he famously remarked "That's funny", an expression that has probably been used by countless scientists over the years whenever they have made interesting discoveries. Fleming identified the fungus as being a Penicillium species, and after some months of calling the inhibitor by the eloquent name of "mould juice", renamed the molecule as penicillin. Unfortunately, he could not characterize penicillin further because he lacked the knowledge and skill required to do so. He was helped by Howard Florey, an Australian pharmacologist, and Ernst Chain, a British biochemist. Florey and Chain studied the therapeutic action of penicillin and discovered how to concentrate the active ingredient in penicillin that was responsible for its killing action. Subsequently all three of them received the Nobel Prize for Physiology or Medicine in 1945 for their work on penicillin.

Figure 3: A vintage advertisement. Interestingly, there are several online recipes for homemade penicillin for the enthusiastic chemists. Disclaimer: do not attempt it unless there's an apocalypse. Source.

Later Florey's research team attempted to mass produce penicillin, a herculean task because massive volumes of the fungal cultures needed to be grown to get a reasonable yield of the drug. Inspired by Florey's work, several companies in the U.S. and the United Kingdom began working on producing penicillin with the objective of having enough supplied for the D-day invasion of Europe. Finally, the mass production of penicillin was successfully standardized by the Northern Regional Research Laboratory (NRRL) in Peoria, Illinois. Following this, the United States had an unlimited supply by 1944, which was one of the reasons why the Allied troops had an advantage over the Germans, who were content with using sulfa drugs and therefore did not invest much effort in the production of penicillin. The "wonder drug" was far superior to any of the drugs that were available at the time and thousands of Axis troops died from wound infections and venereal diseases that were easily cured by penicillin. Interestingly penicillin saved the life of Hitler after a botched assassination attempt left him wounded; his physician at the time was aware of the effects of penicillin and could therefore treat Hitler. 

Following the discovery of penicillin, several new classes of antibiotics were discovered between the 1950s and the 1970s. These antibiotics are categorized based on their chemical structure, the bacteria they target, and their mechanism of action. Unfortunately the era of antibiotic discovery went into a hiatus and after almost 40 years, the new classes of antibiotics were discovered only in the late 2000s and early 2010s. The primary reason for this seemingly reduced pace in innovation is that previously antibiotics were discovered by testing the inhibitory activity of various chemical compounds. Therefore, the lower hanging fruits were already known and it became harder to find new and effective chemicals. Furthermore, even the latest antibiotics that were discovered in the 2000s belonged to antibiotic classes that already been described between 1950 and 1970. This underscores the main problem with antibiotic discovery- limited chemical diversity among antibiotics; they must be able to enter the bacteria and they should not be pumped out of the bacteria, which excludes a wide array of chemicals. A second problem is the ability of bacteria to gain resistance to antibiotics. Bacteria have the astounding capability of mutating the pathways that are targeted by antibiotics and thus gain resistance. To further complicate the situation, bacteria can then pass on this information to other bacteria via horizontal gene transfer leading to a further increase in antibiotic resistance in the bacterial population. These antibiotic resistant strains, also called "superbugs", have become thus become progressively harder to treat. Each year about 25,000 patients in the EU and more than 63,000 patients in the U.S. die from infections caused by multidrug-resistant bacterial infections. 

Figure 4: The causes and consequences of antibiotic resistance. Antibiotics were introduced in livestock to prevent infections that result due to the high animal densities. However, by 2001 it was discovered that almost 90% of the antimicrobials in the U.S. were being used for agriculture. The Food and Drug Administration is currently working to reduce the use of antibiotics to the bare minimum levels.  Source.

So how can we combat the growing incidences of drug-resistant bacteria? "The first rule of antibiotics is try not to use them, and the second rule is try not to use too many of them" is an excellent lesson mentioned in The ICU Book. This adage is an important step in reducing the instances of antibiotic resistance. Self-prescription, incorrect prescription, such as using antibiotics to combat viral infections, and overuse of antibiotics all contribute to an increase in resistant bacterial strains. Additionally, there have been several measures that have been taken by the scientific community to address the problems of antibiotic discovery and combat the emergence of drug resistant bacteria. These measures can be classified into different categories: changing the targets of the antibiotics, using novel chemicals or other agents to target bacteria, and preemptive measures to combat infections. Historically, antibiotic synthesis has followed a pattern: an accidental discovery followed by an investigation of the inhibitory/killing action in order to pinpoint bacterial targets, which include the cell wall, the machinery involved in DNA and protein synthesis, to name a few. However, it is now possible to identify several novel targets in the bacteria and design the antibiotic accordingly. The caveat is that these targets need to be essential to the bacteria so that they cannot be mutated easily. Alternatively, there have been attempts at developing antibiotics that target various cellular processes simultaneously, which will also reduce the probability of developing resistance as the likelihood of bacteria mutating all of these pathways at the same time is very low. There have also been attempts at using investigating chemicals from plants as a potential source of antibiotics. Plants produce several compounds that have demonstrated antibacterial activity. Another bacterial enemy that can be used are phages- viruses that have evolved to target bacteria. Unlike some antibiotics that indiscriminately kill bacteria, phages can be used to only kill the pathogenic strains leaving the other useful bacteria unaffected. As mentioned in a previous blog, vaccines can also be used to prime the body to stave off infections thereby reducing the need for antibiotics. Thus the war between science and bacterial invaders rages on. 

Soap making 101

The word "soap" originates from the Proto-Indo-European language that was developed during the Neolithic age between 4500-2500 BC to denote dripping or trickling. "Soap" is also related to the Latin word "sebum" which refers to fat or grease, which is an accurate description of the nature of soap. Soap is made from fats or oils by the process of saponification. In this process, the triglycerides are combined with a strong base to produce glycerol and fatty acid salts. The resulting salt is called soap. The glycerol is usually kept incorporated with the soap as a softening agent.

Figure 1: The synthesis of soap. A triglyceride consists of a glycerol backbone, which consists of a three-membered carbon chain. Each of the three carbon atoms is bonded to a fatty acid (palmitic acid in this reaction) via an ester linkage. The base, in this case sodium hydroxide, breaks the linkage to produce glycerol and soap. Source. 

How does this formulation of soap help rid the body surface of dirt? Most of the grime on the skin surface is infused with oil, which is secreted from the sebaceous glands in the skin. The oil is hard to wash off with water because the water molecules are hydrophilic- they are more attracted to each other than to the oil, which is hydrophobic. However, soap can mix with both oil and water because it shares qualities of each- the base gives it hydrophilic head and the fatty acid component gives it a  hydrophobic tail. The mechanism of cleaning has been shown below.

Figure 2: Soap molecules are amphipathic; they have both polar and non-polar properties. Soap forms micelles- tiny spheres in which the non-polar tails form pockets that adhere to oil and the polar heads coat the outside of the spheres, making it easier to wash the dirt off. Using soap also helps reduce the germ load because it increases the washing time involved. Source.

The earliest records of soap dates back to Babylon in 2800 BC. The formula for soap was found on a clay tablet from 2200 BC and included water, alkali (a base that dissolves in water), and cassia oil. Ancient Egyptians also used soap which combined animal and vegetable oils with alkaline soils, as evidenced by papyrus records from 1550 BC. In Ancient China, soap-like materials were synthesized from a mixture of pig pancreas and plant ash to produce bathing beans. The earliest mention of soap by its Latin name sapo occurred in 77-79 AD in the book Historia Naturalis by Pliny the Elder, a Roman author and naturalist. The breadth of topics covered in this book was immense and it later became a model for encyclopedias due to its use of an index and referencing of the original authors. The book described the synthesis of soap from tallow, a rendered form of mutton fat, and ashes. Pliny mentioned it as a pomade to style hair and commented that the Gaul and German men were more likely to use it compared to the women. The Romans differed in their method of cleaning the body- they would massage the oil into the skin and subsequently scrape off the oil, and the accompanying dirt, with a strigil.

Figure 3: A Bronze, Roman strigil from the 1st century AD. Strigils were also often buried with the bodies along with a bottle of oil, allowing for squeaky clean afterlives. Source.

In medieval Europe, soap making had reached its zenith between the 8th and 9th century, being well known in Italy and Spain. However, since this soap was made from animal fat, it  had a very unpleasant smell. The concept of conferring a pleasant smell to hard soap was invented in the Middle East during the 8th to 13th century, also known as the Islamic Golden Age. Soaps were infused with rosemary and lavender and the famous Aleppo soap incorporated laurel oil, which is known for its spicy and sweet scent. By the end of the 13th century the manufacture of soap had become industrialized with centers in Nablus, Aleppo, Fes, and Damascus. 

The use of soap, however, did not become routine till the 18th century. Soap was popularized by advertising campaigns in Europe and America, which publicized the relationship between health and cleanliness. This was because it become increasingly apparent that hygiene played an important role in reducing the number of pathogenic microorganisms thereby reducing the instances of disease. Therefore, it became necessary to produce soap on an industrial scale. This was a problem because there was no good way to obtain the base that was required to make soap. Previous chemists were dependent on burning kelp or wood and using the ash produced as a source of base. The process resulted in a very low yield and so it was imperative to establish a large-scale synthesis procedure. To this end, in 1780 James Keir, a Scottish chemist, developed a method of extraction which involved slowly passing dilute solutions sulphates of potash (K₂CO₃) or soda (NaHCO₃), which were also present in ash, through a thick paste of lime (Ca(OH)₂). This method was more viable because lime was readily available in large amounts from limestone.

                                             K₂SO₄ + Ca(OH)₂   →  2KOH+ CaSO₄

                                                           _{potassium sulphate}

                          

                                             Na₂SO₄ + Ca(OH)₂   →  2NaOH+ CaSO₄

                                                   sodium sulphate

Armed with this knowledge, Keir set up a manufacturing unit for the synthesis of base and to this unit he later added a soap manufactory. The next advancement came in 1807 when Andrew Pears invented transparent soap by removing the impurities present in soap. His invention was to benefit the upper classes in London whose delicate complexions needed finer soap as opposed to the working class whose tanned complexions could make do with crude soap.

Figure 4: Pears' soap advertisement from the 1880s touting the gentle nature of the soap. Source.

There are other noteworthy improvements in the field of soap-making, which included packaging soap into manageable portions. In 1837, Robert Hudson, an English businessman, developed soap powder by grinding the soap with a mortar and pestle. His advertising campaign convinced his customers that this product was necessary. Furthermore, they could avoid the tiresome labour involved in cutting off soap flakes from the large blocks of soap that were available in the market. However, Hudson never manufactured his own soap, instead he would purchase the raw soap from William Gossage, an English chemical  manufacturer, who optimized the synthesis of cheap, good-quality soap. To do so, he incorporated sodium silicate, which was readily available, into soaps. An additional advantage was that sodium silicate could soften hard water by removing the calcium ions, thereby preventing the deposition of minerals such as calcium carbonate on surfaces. Sodium silicate is now routinely used in the manufacture of commercial detergents. He also added pigments to the soap, resulting in the manufacture of blue mottled soap, which became world famous at the time. The soap even won a medal for "excellence in quality" at the International Exhibition in 1862. Eventually the company became a part of the Unilever group that was founded in 1886. The founder, William Lever, an English industrialist, was known for using large advertising campaigns to broadcast his product.

Figure 5: An advertisement for the Lever Brothers Company's Lifebuoy soap. In 1929 Unilever was formed by the merger of the Dutch company, Margarine Unie, and the Lever Brothers. Source.

The most predominant form of soap these days, liquid soap, was not invented until the 19th century. In 1865, William Sheppard from New York, patented a liquid version of soap. He had discovered that by dissolving a small amount of soap with a solution of aqueous ammonia he could produce thick, liquid soap. The ammonia acted as a base and reacted with oils to form soap. The water in the soap made it easy to clean. A more famous liquid soap was developed in 1898 by B.J. Johnson which was made by combining palm oil and olive oil. The resultant soap became so popular that the company was renamed after the soap- "Palmolive".

On a personal note, while researching this article I learnt a lot about soap making. It was intriguing to see how the ingredients for homemade soap: coconut, sweet almond, rice bran, and all the oils that can possibly be named, are used; making it sound more like a sunday brunch recipe. I've also always been fascinated by the incorporation of flowers, fruit peels, leaves, and what not into the soap structure. It usually begs the question: does using the soap result in a bathtub that looks like a hiking trail? It was fascinating to see how soap evolved from being an afterthought to a necessity and now to pieces of art. 

Figure 6: Cupcake soaps. Use at your own risk! Source.