Historical perspectives
The discovery of ether for the use as an anesthetic was in 1846 which marked the birth of a modern age in anesthesiology. Although its use has been abandoned in the developed world, ether was safely and effectively used as an inhalation anesthetic for over one hundred years. Prior to the middle of the 19
th century and the discovery of ether, surgery was a rare and gruesome procedure. One of the most common operations was extremity amputation. There the surgeon used saws and knives to remove an appendage and scalding irons to cauterize the wound. Before the discovery of anesthesia, the sound of patients thrashing and screaming vibrated throughout the operating rooms [
2]. They resorted to a variety of methods to control the patient’s pain including alcohol, opiates, ice, and various distractions.
Ether (diethyl ether) was first prepared in 1540 by Valerius Cordus, a Prussian botanist. Cordus produced the compound, known as “sulfuric ether” at the time, by distilling sulfuric acid (oil of vitriol) with fortified wine to make an “oleum vitrioli dulce” (sweet oil of vitriol) [
3]. Despite this early synthesis, ether was rarely used over the next three decades. In fact, it’s only routine consumption was as a recreational drug among poor Britians who sometimes drank an ounce of ether when traditional alcohol was not available. American students adopted a variation of this practice in the “ether frolics” of the early 1800s to achieve a feeling of euphoria. Participants would hold ether soaked towels to their faces until losing consciousness.
Ether was first made use of as a general anesthetic by Dr. Crawford Williamson Long on March 30, 1842. Long was a physician and pharmacist who learned about ether while studying medicine in college. In 1842, Long removed a tumor from the neck of a patient who was under the effects of ether anesthesia. Unfortunately, the successful and unprecedented use of anesthesia during surgery was not credited to Long due to his laxity in publishing the results of the surgery until several years later.
The first true demonstration of ether as an inhalation anesthetic was on October 16, 1846 by William T.G. Morton, a Boston dentist. He discovered the anesthetic properties of ether in his search to provide patients with relief from painful dental procedures [
4]. Prior to 1846, anesthesia was not used during surgical procedures and patients often avoided surgical intervention at all cost. Additionally, prior to the monumental events of 1846, Morton attended a public demonstration of the anesthetic properties of nitrous oxide given by Horace Wells. Wells, also a dentist, administered nitrous oxide to a patient and then extracted a wisdom tooth. Unfortunately, the patient did not appear to be fully anesthetized and the public deemed the demonstration to be a failure.
The exhibition furthered Morton’s interest in inhalation anesthetics and led him to consult a professor of chemistry at Harvard Medical School, Charles A. Jackson [
4]. Jackson recommended a trial of sulfuric ether as an alternative to nitrous oxide, commonly known as “laughing gas”. Morton began experimenting with the ether and learned that a drop on the skin produced local analgesia. Further investigation with inhaled ether revealed that the agent was more versatile than inhaled nitrous oxide. As opposed to nitrous oxide, bottles of ether could be transported easily and the volatility of the drug permitted effective inhalation. In addition, the concentration of the drug required for surgical anesthesia was so low that the patients did not become hypoxic when breathing ether vaporized in air which is an advantage compared to nitrous oxide. Morton, who had entrepreneurial aspirations, quickly became convinced that ether was a suitable surgery anesthetic for hospital surgery and knew the significance of ether as a surgical anesthetic. He also knew that since ether has been available for centuries, it could not be patented, so Morton added some odor-masking impurities to ether, and called the concoction Letheon.
As a result of Morton’s “success”, he began to promote the use of ether in his dental practice. His success also prompted a demonstration at Harvard Medical School. On October 16, 1846, Morton publicly administered inhaled ether to a patient at Massachusetts General Hospital which took place in an amphitheater now known as the “Ether Dome”. The patient was successfully anesthetized and the surgeon, Dr. John Warren, removed a tumor from Mr. Gilbert Abbot’s neck. The patient had muttered as if in a semi-conscious state during the operation and after the surgery was complete, he stated that the pain was considerable, though mitigated. On the following day, the vapor was administered to another patient with complete success [
4]. The public demonstration of ether anesthesia signaled the birth of the field of anesthesiology as a specialty. Ether anesthesia was adopted rapidly around the world and surgical anesthesia and analgesia became an accepted standard in surgical care.
Morton kept the true composition of Letheon a secret with the hopes of becoming wealthy. However, it was not long before surgeons recognized the smell of Letheon and associated it with ether. Morton attempted to fight the widespread use of ether which even included petitioning Congress for two decades to award him as the discoverer of ether. Nonetheless, Congress was knowledgeable of ether’s ancient origins and no monetary reward was given to Morton.
Oliver Wendell Holmes Sr. created the term anesthesia that was derived from the Greek word
anaisthēsia meaning “lack of sensation” [
5]. Holmes was a professor of anatomy and physiology at Harvard and had rejoiced saying that “The knife is searching for disease, the pulleys are dragging back dislocated limbs, nature herself is working out the primal curse which doomed the tenderest of her creatures to the sharpest of her trials, but the fierce extremity of suffering has been steeped in the waters of forgetfulness, and the deepest furrow in the knotted brow of agony has been smoothed forever [
6].”
Ether was safe, easy to use, and remained the standard general anesthetic until the 1960s when the fluorinated hydrocarbons (halothane, enflurane, isofluorane and sevoflurane) came into common use. Although these newer agents reduced the postoperative nausea, vomiting and flammability that were problematic with ether, they were expensive to produce and included a host of undesirable side effects.
Anesthetics used today are almost unrecognizable from anesthetics used in the late 1800s. Ether has been replaced completely by newer inhalation agents and open drop delivery systems have been exchanged for complicated vaporizers and monitoring systems. Anesthesia in the developing world, however, where lack of financial stability has halted the development of the field, still closely resembles primitive anesthetics.
Anesthesia in undeveloped countries
Shortages of personnel who are adequately trained to administer anesthetics, drugs, and equipment are commonplace in third world countries. Operating room conditions are primitive by U.S. standards [
7]. Pulse oximeters, tilting operating tables and appropriately sized endotracheal tubes are often unavailable. A functional oxygen source, running water and electricity are often unreliable. Furthermore, there are an inadequate number of anesthesiologists in third world nations and anesthesia is also usually delivered by non-physician anesthetists and nurses under the direction of a surgeon. These providers typically have minimal or no formal training in medicine and usually even less training in anesthesiology [
1,
8]. A recent study in Uganda, for example, found that among 91 anesthesia providers, 85 % attended training courses of only 1 year to 19 months duration. The same study found that there are only 13 anesthesiologists and 330 non physician anesthetists for the entire Ugandan population of 27 million. By comparison, there are approximately 12,000 anesthesiologists for a population of 60 million in the United Kingdom [
1].
In an attempt to provide anesthesia, developing countries have had to make cost saving adjustments. “One time use” items such as endotracheal tubes are reused and recycled, often becoming unsafe because of balloon rupture after a few uses [
9]. Expensive anesthetic vaporizers and circle systems, the mainstay of western anesthesiology have been largely abandoned. These devices are not only expensive, but they are also costly to maintain. Service, parts, and appropriate safety training eparts are rarely available.. In addition, these vaporizers are dependent on a continuous supply of oxygen, which is not reliably available in developing nations.
Consequently, “draw-over anesthesia” is extensively utilized. In draw-over anesthesia, the carrier gas (atmospheric air) is drawn over the volatile liquid (anesthetic agent) by the patients’ respiratory efforts. Drawover systems are simple to assemble and use. Most importantly, drawover technique is safe for patients.
Anesthetic drugs, common in western anesthesiology, are rarely available in developing nations. Sevofluorane, desfluorane and isofluorane, the fluorinated hydrocarbons that are the major inhalation agents of the west, are unavailable in developing countries. These agents are both expensive and require extensive equipment for delivery. Instead, halothane is the most widely used volatile agent in developing nations [
8]. Ether is also used, but its use is limited due to decreased availability and flammability. Substituting ether for halothane in developing nations, most importantly in those already using drawover anesthesia, could both save money and improve the safety of surgical anesthesia.
Ether versus halothane
Although abandoned in western anesthesia, ether has long been known as a relatively safe and inexpensive anesthetic. Halothane costs approximately U.S. $140 per liter (U.S. $0.14 per ml). In one study, Eltingham, using a Glostavent Anesthetic Machine with halothane as the sole agent, found that the mean use of halothane was 16 ml per hour. This results in a cost of U.S. $2.24 per hour of use. While this cost is relatively minor by western standards (approximately a tenth of the price of Sevoflurane), it is still a considerable portion of the small budget of anesthesiology departments in developing nations. In a study conducted in 1994 in Malawi, halothane accounted for a quarter of the entire anesthesiology department budget [
8].
In contrast, ether costs a mere U.S. $10 per liter (approximately U.S. $0.01 per ml). Using the same calculations as above, this would lead to a cost of U.S. $0.16 per hour of use (a U.S. $2.08 per hour savings compared to halothane). The cost difference could save struggling anesthesiology departments thousands of dollars each year.
Hospitals located in rural areas could also save money by increasing the use and production of ether. While halothane is relatively expensive to produce and must be manufactured in large factories and then transported to rural health care centers, ether can be easily and cheaply produced from ethanol at a local level. Purchasing locally manufactured anesthetic ether could have significant effects by decreasing cost, supporting local economies, and making rural hospitals in developing nations more self-sufficient.
Both halothane and ether can be administered easily using drawover anesthetic techniques. Halothane, however, is a relatively unsafe agent to use without intra-operative monitoring. As mentioned earlier, developing nations rarely have either a reliable oxygen source or electricity. As a result, intra-operative monitoring and intervention with supplemental oxygen are not possible. Halothane depresses both the ventilatory drive and cardiac output making supplemental oxygen and cardiac monitoring crucial. Ether, on the other hand, acts as a sympathomimetic agonist, stimulating cardiac output, respiratory rate, and causing bronchodilation. While not ideal, it is therefore safe to use ether when supplemental oxygen, endotracheal intubation and cardiac monitoring aren’t available.
Finally, the side effects of ether anesthesia are relatively minor when compared with those of halothane. Halothane hepatitis is a well-documented toxicity in patients exposed to the drug. Although relatively rare (affecting only 1/10,000 patients), halothane hepatitis has a mortality rate of 50 % [
10]. In addition, halothane has been known to cause cardiac arrhythmias as well as fatal bradycardia. Due to the concerns surrounding its hepatotoxicity, halothane has been primarily eliminated for use in adults in the United States and many other countries. Halothane was eventually replaced by safer newer volatile anesthetics. However, in countries with different medico legal climates, halothane still plays a vital role due to its relatively low cost. For example, halothane is still being used as the main anesthetic in more than 80 % of the hospitals in Iran. As a result, increasing numbers of halothane hepatitis is being reported in Iran and among other countries still using halothane [
11]. Ether, on the other hand, is a relatively safe agent with its main side effect being postoperative nausea and vomiting.
The major problem with ether is its extreme flammability, especially in the presence of oxygen. Ether is extremely volatile and has a low boiling point, two characteristics which make it prone to explosion. The number of surgical fires in 1960 (when ether was the primary inhalation anesthetic used in the United States), was reported at one in approximately 100,000 anesthesia [
12]. Therefore, the number of fires caused by ether is therefore relatively small.
There are relatively easy to implement precautions that operating rooms in developing countries can mandate to combat the ether’s flammability. First, open flames, such as those provided by alcohol lamps, Bunsen burners, matches, and smoking must be prohibited in rooms where anesthetics are either administered or present. Next, the use of incandescent or high frequency cautery or coagulation within a distance of two feet from the mouth of a patient receiving flammable anesthetics must be prohibited unless a rubber sheet and wet drapes are properly applied. Last, ether should be stored in original cans or dark glass bottles to avoid explosions due to the effect of sunlight [
12].