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MILITARY MEDICINE, 170, 4:3, 2005 History of U.S. Military Contributions to the Study of Vaccines against Infectious Diseases Guarantor: Andrew W. Artenstein, MD Contributors: Andrew W. Artenstein, MD*; Jason M. Opal, PhD†; Steven M. Opal, MD*; COL Edmund C. Tramont, MC USA (Ret.)‡; Georges Peter, MD§; MG Phillip K. Russell, MC USA (Ret.)储 The U.S. military has a long and illustrious history of involvement with vaccines against infectious diseases. For more than 200 years, the military has been actively engaged in vaccine research and has made many important contributions to the development of these products for use in disease prevention and control. Through the efforts of military researchers, numerous serious threats to the health of American troops and their families have been mitigated. tory. The definition of “contribution” in this work involves findings by U.S. military researchers that led, either directly or indirectly, to an effective, licensed vaccine against a human pathogen. Therefore, significant epidemiologic, microbiologic, or immunologic discoveries or pivotal clinical trial findings constitute contributions. We have excluded other work that, although important in advancing vaccine science, does not meet the criteria. Such work includes areas of active or previous military research that have not resulted in an effective vaccine, development of vaccines used by the military in which military researchers played no significant role, and nonpivotal clinical trials performed in a military setting. We have also omitted coverage of certain infectious diseases, e.g., bioterrorism-associated diseases, viral hepatitis, and encephalitides, that are discussed in detail in other articles in this supplement. Table I presents a comprehensive summary of U.S. military contributions, as defined, to vaccines against infectious diseases. We have endeavored to review selected highlights of military vaccine history. Introduction he history of vaccination conventionally dates from Jenner’s work T published in 1798, which demonstrated that deliberate inoculation with material from cowpox lesions resulted in protection against smallpox.1 Following a relatively quiescent period of more than 85 years, the nascent field of vaccinology began in earnest in the last quarter of the 19th century, heralded by a series of discoveries that established the modern fields of bacteriology, microbiology, and immunology. With the 1931 discovery by Goodpasture that chorioallantoic membranes of fertile hens’ eggs supported viral growth, coupled with the landmark demonstration by Enders, Weller, and Robbins in 1949 that viruses could be efficiently grown in tissue culture outside of a living host, vaccinology truly entered its “golden age.”1 Figure 1 provides a time line for vaccine development within the historical context of the 200 years since Jenner’s discovery. U.S. military interest in the concept of immunization preceded the work of Jenner and continues unabated today. Historically, communicable diseases have been extremely important to the military, because infectious illnesses contribute greatly to troop morbidity and mortality rates in times of both war and peace. For this reason, vaccines against infectious diseases not only are widely used by the military to protect the fighting forces but also have been the focus of longstanding, substantial, military research efforts. In fact, the military has been a prime mover in many areas of vaccine development, in some cases because of military exigencies and in others because of the availability of military scientific expertise related to a specific public health problem. In this article, we highlight areas of vaccine research in which the military has contributed in a substantive way and we provide insights regarding some of the key figures in this illustrious his- Smallpox and the Inoculation of the Continental Army Smallpox, caused by the brick-shaped virus variola, was endemic in Europe and elsewhere during the early modern period (1400–1700), periodically erupting in epidemics that ravaged whole cities, killing nearly 30% of the victims and leaving the rest immune but scarred. In the 1720s, Lady Mary Wortley Montagu introduced to England the Near Eastern practice of variolation, i.e., the deliberate infection of a healthy subject with dried pus from smallpox pustules through an incision in the upper arm. Inoculees generally endured a mild case of disease and gained lifelong immunity, although 2 to 3% died as a result of smallpox contracted through the procedure.1 The practice of variolation spread slowly to Europe’s ruling classes, raising hopes that smallpox might be conquered and complementing Enlightenment precepts of applied reason and proactive statehood.2 In Colonial North America, where a dispersed population kept smallpox in relative check, sporadic inoculation began during a 1721 epidemic in Boston. Cotton Mather, the Puritan divine and scientist, inoculated 242 persons, of whom only six died.3 By the middle of the century, American luminaries such as Benjamin Franklin celebrated the “uncontroverted success” of the technique.4 Nonetheless, inoculation sparked resistance. Physicians and clergymen in Boston accused Mather of mocking God’s will by interfering with the course of a plague, rather than addressing its effects. Variolation had other drawbacks, for example, cost, including not only the hefty price of the procedure itself but also the labor time lost during the 1- to 2-month preparation for and recovery from the induced illness. In addition, inoculees posed a clear transmission risk to the rest of the population. As a result of these concerns, every colony except Pennsylvania passed laws to restrict the practice.2 *Center for Biodefense and Emerging Pathogens, Memorial Hospital of Rhode Island, Pawtucket, RI 02860 and Brown Medical School, Providence, RI 02912. †Department of History, Colby College, Waterville, ME 04901-8840. ‡Division of AIDS, National Institute of Allergy and Infectious Diseases, National Institutes of Health, Bethesda, MD 20892-6612. §Division of Pediatric Infectious Diseases, Hasbro Children’s Hospital, Providence, RI 02903 and Brown Medical School, Providence, RI 02912. 储Office of the Assistant Secretary for Public Health Emergency Preparedness, Department of Health and Human Services, Washington, DC 20201. Reprint & Copyright © by Association of Military Surgeons of U.S., 2005. 3 Military Medicine, Vol. 170, April Supplement 2005 4 History of U.S. Military Vaccine Development Fig. 1. Time line of important events in vaccine history, anchored by world events. During the War of the American Revolution (1775–1783), a massive smallpox epidemic brought the inoculation controversy to the fore. Although the Continental Army faced British troops who were largely immune to the disease, as a result of either childhood exposure or army inoculation, most colonists were susceptible. Wartime conditions brought men from diverse geographic locations into crowded camps and then shipped them through civilian populations, expanding variola transmission into vulnerable populations. Many of the enlightened statesmen in the Continental Congress considered smallpox the Army’s most dangerous enemy and inoculation its only hope. However, in grappling with what John Adams called “the King of Terrors to America,” General George Washington encountered nonscientific barriers that ultimately stemmed from his own countrymen’s fear of concentrated authority.5 Smallpox struck shortly after hostilities began at Lexington and Concord during April 1775. Militiamen converged on the British Army encampment in Boston, trapping their countryMilitary Medicine, Vol. 170, April Supplement 2005 men and the British inside the seaport. By early summer, the first cases of smallpox appeared on Boston’s streets, prompting some to pay for inoculation and others to proclaim that inoculation itself only magnified the epidemic. Washington recognized the dire threat posed to his troops but also gleaned that inoculation would render them unfit for service for weeks or months. Long skeptical of the practice, Washington opted instead to isolate diseased troops.6 Although such measures prevented a major outbreak among the troops in 1775, the epidemic widened. Variola flourished in the crowded camps during the American expedition to Quebec in the winter of 1775–1776. In Montreal, 1,800 of the 7,000 American troops died from smallpox in the last 2 weeks of May alone.7 Washington, whose strategy revolved as much around preserving his own army as around defeating the British, knew that further outbreaks would seal the defeat he had endured on the battlefield during 1776. Inoculation of the entire Continental Army, man by man, repre- History of U.S. Military Vaccine Development 5 TABLE I U.S. MILITARY CONTRIBUTIONS IN VACCINES AGAINST INFECTIOUS DISEASES Disease/Agent Dates Military Relevance Smallpox 1777 Yellow fever 1900 Highly contagious scourge of troops Epidemic disease associated with high mortality rates in American-occupied areas Typhoid 1909 Communicable cause of outbreaks among deployed troops Pneumococcus 1945 Prominent respiratory pathogen among troops Hepatitis A 1945; 1985–1990 Cause of major outbreaks among troops in settings of military conflict Adenovirus 1952–1969 Major cause of ARD among recruits, disruptions in training, economic losses Influenza 1957 Rubella 1961 Epidemic and pandemic disease impeding military readiness and fighting force Consequences of disease in pregnancy affect military families Meningococcal disease 1966–1972 Japanese encephalitis 1950s; 1980s Hepatitis B 1970s– early 1980s Epidemic meningitis in basic training settings causes significant morbidity and mortality among troops Epidemic neurologic disease in Asia; outbreaks in American forces in Korea; potential for impacting deployed troops throughout Asia Bloodborne and sexually transmitted disease Military Contribution First large-scale inoculation of an army Demonstrated that the etiologic agent was a filterable virus transmitted by Aedes aegypti mosquitoes, leading to disease control through vector eradication and, eventually, through vaccination Development of killed typhoid vaccine that became mandatory for all Army and Navy personnel in 1911 and greatly reduced the morbidity and mortality rates of typhoid among military personnel Tested first multivalent polysaccharide vaccine at the Army Air Base, Sioux Falls, SD (under the auspices of the Armed Forces Epidemiological Board), reduced incidence of pneumonia and the pneumococcal carrier state 1945, demonstrated that passive immunization with pooled normal human immunoglobulin could prevent or attenuate disease; 1980s– 1990, investigated safety and immunogenicity of inactivated vaccines and directed a pivotal efficacy study of inactivated hepatitis A vaccine among ⬃40,000 Thai children Isolated causative agent, later named adenovirus, at Fort Leonard Wood; described epidemiology and clinical spectrum of adenovirus infections; developed killed bivalent vaccine; recognition of SV40 contamination; developed oral, attenuated, multivalent vaccine Described antigenic drift and shift, developed surveillance system for epidemic disease Isolated the causative virus after noting interference with enteroviral growth in African green monkey kidney cell cultures, led to development of a safe effective vaccine using this virologic technique Described immunologic responses to the bacteria and identified protective responses, developed first polysaccharide immunogen and proved its efficacy in clinical trials Early attempts at vaccination (World War II); significant contributions to the epidemiology and ecology of the virus in the 1950s to 1960s, pivotal field trial of inactivated vaccine in Thailand Demonstrated protective effect of antibodies sented one way to stop smallpox. From 1775 to 1776, the idea percolated among delegates to the Continental Congress in Philadelphia. A bastion of colonial medicine and Enlightenment science, revolutionary Philadelphia was the home of Dr. Benjamin Rush, chair of Congress’ Medical Department (Fig. 2). Rush had been inoculating patients since 1769, and he exemplified the En- Key Personnel Gen George Washington, Dr. Benjamin Rush MAJ Walter Reed, Maj James Carroll, Aristide Agramonte, Jesse Lazear, COL William Gorgas Maj Frederick F. Russell Dr. Colin MacLeod, Dr. Michael Heidelberger, Lt Richard Hodges Col Charles Hoke, Lt Col Bruce Innis, Dr. Len Binn, Dr. Stanley Lemon Dr. Maurice Hilleman, COL Edward Buescher, Maj Franklin Top, Col Phillip Russell Dr. Maurice Hilleman Cpt Paul Parkman, Cpt Malcolm Artenstein, Lt Col Edward Buescher Dr. Malcolm Artenstein, Dr. Irving Goldschneider, Dr. Emil Gotschlich, Maj Ronald Gold Dr. Joseph Smadel, Dr. Albert Sabin, Cpt Edward Buescher, Cpt William Scherer, Col Charles Hoke Dr. Saul Krugman, Col William Bancroft, Dr. Maurice Hilleman lightenment belief that science could uplift “the whole family of mankind.”8 Through mass inoculation, Rush and others argued, the ancient scourge of smallpox could be tamed, saving the Continental Army and thus the infant republic.9 However, inoculating the entire Continental Army represented a logistical nightmare. Every regiment would have to identify its susceptible troops, send Military Medicine, Vol. 170, April Supplement 2005 6 History of U.S. Military Vaccine Development Battle of Trenton on December 26, 1776, could convince the troops to sign on for further service. Of the 11,000 soldiers Washington commanded at Trenton, only 1,400 remained by early January. The Army simply melted away, leaving Washington to wait for new, smallpox-naive recruits to join camp in New Jersey.11 New cases of smallpox began to appear within weeks. Therefore, on February 5, 1777, Washington ordered the inoculation of all susceptible troops in the Continental camp and of every new recruit, the first time an American force had been immunized by command order. With the active unwavering support of Benjamin Rush, Washington enjoined regimental commanders to have all new soldiers “inoculated, and in all respects prepared for the field” before they reached camp.12 His letters made clear that inoculation ranked as a regiment’s first priority, topping even supply and recruitment.13 Despite the Continental Army’s administrative and disciplinary deficiencies, the new directive worked remarkably well. For more than a year, the Army provided free compulsory inoculation for all soldiers. The new policy simply codified a practice that many had sought on their own, often against orders, in 1775 and 1776.14 Washington did not detect (or at least did not record) any resistance from the troops. By the time Washington temporarily halted the inoculations in 1778, the Continental Army was free of epidemic smallpox. Sporadic cases emerged for the duration of the war, but never again did variola devastate an American force as it had in Canada in the winter of 1775–1776. Prompted and enabled by Enlightened science, the Army’s inoculation program robbed the British of a major tactical advantage. Fig. 2. Dr. Benjamin Rush, physician, teacher, and humanitarian. Benjamin Rush (1746 –1813) embodied the progressive spirit of the Enlightenment. A graduate of the College of New Jersey (now Princeton University) in 1760 at the age of 14, he studied medicine under Dr. John Redman in Philadelphia before crossing the Atlantic to Scotland, where he earned his medical degree at the University of Edinburgh in 1768. Rush returned to America in 1769 and opened a private practice in Philadelphia, becoming America’s first chemistry professor in the College of Philadelphia’s Medical Department. In 1776, he was elected a member of the Continental Congress and signed the Declaration of Independence. The same year, Rush contributed his medical proficiency to the cause, serving as a surgeon in the Continental Army, and was appointed Surgeon General of the Armies of the Middle Department. His visionary support for programmatic smallpox inoculation helped save Washington’s troops from the ravages of variola. In 1789, Rush returned to teaching medicine at the College of Philadelphia and became the chairman of the Institutes of Medicine and Clinical Practice at the newly formed University of Pennsylvania. He taught more than 3,000 medical students during his career (photograph courtesy of the American Antiquarian Society; used with permission). them to a secure inoculation center (to prevent inadvertent transmission), and then wait for them to recover. Washington had reservations about the plan, because he knew that the American war effort was hamstrung by the very principles that had propelled the Revolution; patriot leaders feared centralized authority, and a similar spirit pervaded the rank-and-file forces. Continental troops thought of themselves as contracted laborers who fought for a designated span of time and for a specified wage only. In this way they defined themselves against the redcoats, who suffered under the heels of brutal haughty officers. Although Washington tried to bring the discipline of European armies to his own troops, they remained undersupplied, unruly, and altogether unsuited for an effort on the order of mass inoculation.10 Despite Washington’s reservations regarding mass inoculation, circumstances forced his hand. The New Year 1777 ended the enlistment terms for the bulk of the Continental Army, and not even their victory at the Military Medicine, Vol. 170, April Supplement 2005 Yellow Fever Control and Vaccine Development Yellow fever, a systemic viral disease endemic to sub-Saharan Africa, was probably first transported to the Americas by infected “stowaway” mosquitoes on sailing vessels used in the slave trade. It quickly spread to nonimmune populations in major seaports from Boston to New Orleans to Havana, causing recurrent epidemics in coastal America from the 1600s to the early 20th century.15 Epidemic yellow fever crippled the fledgling national capital of Philadelphia in 1793,16 nearly wiped out Napoleon’s expeditionary forces in New Orleans in 1801 (convincing Napoleon to sell the Louisiana Territory to the United States), and destroyed the valiant French effort to build the Panama Canal in the 1880s.17 Nonimmune workers in the Canal Zone developed a febrile illness associated with flushing, headache, and myalgia, followed by a brief interlude of relative remission of symptoms that heralded the recurrence of fevers accompanied by jaundice, mucosal hemorrhage, “black vomit” (hematemesis), shock, and, inevitably, death. Fully loaded supply ships dropped off equipment for the canal excavation project and returned fully loaded with caskets of dead workers, most of whom died of yellow fever or malaria. The French effort was abandoned in 1889 after enormous financial losses (estimated to be in excess of $300,000,000) and the loss of nearly 22,000 workers to yellow fever.17 The U.S. military’s involvement in yellow fever control began in 1897, with the establishment by President McKinley of a scientific commission to study its causes.18 The acquisition of Cuba by the United States in the Spanish-American War provided impetus to the commission’s work, because the disease was rampant throughout the island, and Cuba served as a staging area for the exportation of yellow fever to susceptible populations in coastal U.S. cities. Surgeon General George Sternberg appointed a young officer in the Army History of U.S. Military Vaccine Development Medical Corps, MAJ Walter Reed, to head the commission (Fig. 3).19 The Yellow Fever Commission correctly focused its attention on the mechanisms of disease transmission, rather than its etiology. Although Reed was convinced that a bacterial etiology (i.e., Sanarelli’s Bacillus icteroides hypothesis) was unlikely,20 actual identification of the viral etiology of yellow fever was decades away. A number of different hypotheses concerning yellow fever transmission, including those involving fomites or airborne “miasmas” related to poor sanitation, were widely held at the time.21 Carlos Finlay, a Cuban physician, first proposed that yellow fever was transmitted by a mosquito vector in 1881.22 His work was ham- Fig. 3. MAJ Walter Reed. Walter Reed (1851–1902), the son of a Methodist minister from Virginia, received his first medical degree in 1869 from the University of Virginia and a second medical degree in 1870 from Bellevue Hospital Medical College in New York City. While serving as an assistant sanitary officer in Brooklyn, he developed a lifelong interest in communicable diseases. Reed joined the Army Medical Corps in 1875 and was assigned largely to outposts in the American West. After advanced study in bacteriology in the early 1890s at Johns Hopkins Hospital, he was assigned to Cuba in 1899 to study typhoid fever, a major problem for American troops during the Spanish-American War. This led to work on cholera and malaria and his seminal work as the leader of the Yellow Fever Commission at Camp Lazear in 1900. Although he died from peritonitis following rupture of his appendix in 1902, Reed lived to see the importance of his discoveries in the eradication of yellow fever from Cuba, a public health standard that still stands today for the control of vector-borne diseases worldwide (photograph courtesy of Historical Collections and Services, Claude Moore Health Services Library, University of Virginia; used with permission). 7 pered by numerous experimental limitations and, despite exhaustive attempts, Finlay was ultimately unable to prove his hypothesis. Reed, however, thought the mosquito hypothesis had merit. In preliminary experiments by the commission in 1900, Culex fasciatus mosquitoes (later renamed Aedes aegypti) were allowed to obtain a blood meal from a patient with yellow fever. The mosquitoes were then “ripened” in test tubes for more than 12 days, which, unbeknownst to the researchers, allowed the virus to replicate and migrate to the salivary glands of the mosquito. One commission member, Dr. James Carroll, became seriously ill with yellow fever after an intentional bite from one of the infected vectors; another, Dr. Jesse Lazear, died from yellow fever after unintentional exposure to an experimentally infected mosquito.23,24 On the basis of their preliminary data, commission members designed a detailed series of experiments to confirm the mosquito hypothesis. These involved intensively exposing military volunteers either to blood-soaked linens, towels, and bedclothes from yellow fever victims (testing the fomite hypothesis) or to infected mosquitoes. An attack rate of more than 80% was observed in the latter group of volunteers, compared with no cases in the former. These experiments also elucidated the 12-day (in summer) to 17day (in winter) incubation period in the mosquito vector. Additional experiments proved that the agent was transmissible by blood from an infected patient, that pasteurizing the blood prevented transmission, and that blood remained infectious after filtration through a submicron filter, thus confirming that the causative agent was a submicroscopic organism. Interestingly, the commission’s experiments also pioneered the use of informed consent in research involving human subjects,18 providing the basis for the initial draft of the Declaration of Helsinki for the use of human subjects in medical research in 1964.25 The Yellow Fever Commission’s findings led directly to the control of yellow fever in Cuba through the application of vectorcontrol programs. MAJ William Gorgas was given the responsibility of directing the Yellow Fever control programs in Cuba and subsequently in the Panama Canal Zone.26 After gaining independence from Colombia, the Panama Canal Zone became an American-controlled territory by treaty in 1903, providing the United States with the opportunity to complete the task abandoned years earlier by the French, namely, building the Panama Canal.17 Predictably, the American effort was beset by the same problems of yellow fever, malaria, and other diseases experienced by their predecessors. As in Cuba, however, aggressive vector-control programs proved their efficacy; within 16 months, Gorgas and his teams eliminated yellow fever from the Canal Zone.27 The work of the military’s Yellow Fever Commission and military efforts to control tropical diseases in Cuba and Panama were instrumental in convincing J.D. Rockefeller to invest enormous resources in work on diseases of relevance to public health; the Rockefeller Foundation was established in 1913. Gorgas, by then the retired Surgeon General and a highly influential physician and scientist, assumed leadership of the Rockefeller Foundation’s commitment to yellow fever research and worked tirelessly with the Foundation to help control yellow fever in South America.27 Public health researchers recognized that a vaccine was the most practical approach to the control of yellow fever in large rural and urban populations in sub-Saharan Africa and South America. Investigators at the Rockefeller Institute sought to attenuate yellow fever virus for vaccine production by serial passage of the virus in Military Medicine, Vol. 170, April Supplement 2005 8 History of U.S. Military Vaccine Development animal tissues, as Pasteur had done with rabies vaccine.28 This approach proved problematic, however, because serial passage in mouse brain tissue attenuated viscerotropic virulence but the virus became more neurotropic. Rhesus monkeys vaccinated with the attenuated virus were protected from wild-type virus challenge but occasionally developed fatal encephalitis.28 Theiler and Smith,29 at the Rockefeller Institute, subsequently found that serial passage of wild-type virus in chick embryos resulted in a viral strain attenuated in both viscerotropic and neurotropic activity. This attenuated strain, 17D, induced long-term immunity against yellow fever in Rhesus monkeys and nonimmune human volunteers, and it has proved to be remarkably safe and effective in more than 60 years of use. Acute Respiratory Disease among Recruits and Adenovirus Vaccine Acute respiratory disease (ARD) has always been a leading cause of morbidity among military recruits.30 Compared with age-matched civilian populations, military personnel appear to be at increased risk of respiratory infections for a variety of reasons, including crowded living conditions and physical stressors.31 ARD in military recruits represents a syndrome caused by a wide variety of microorganisms. In the early 1950s, military researchers produced the first of numerous successes against these agents. Like so many important scientific discoveries, this initial success demonstrated the Pasteurian axiom of “chance favoring the prepared mind.” Following his doctoral work at the University of Chicago and a stint in the industrial sector at Squibb Laboratories, Maurice Hilleman (Fig. 4) joined the scientific staff at the Walter Reed Army Institute of Research (WRAIR), eventually becoming the chief of the Department of Respiratory Disease Research. During the early days of his tenure at WRAIR, his research largely focused on global influenza epidemiology and surveillance.32 In the course of investigating an influenza epidemic at Fort Leonard Wood in 1952–1953, Hilleman led a study to compare wild-type virus collected from the throat washings of ill recruits with virus propagated in embryonated hens’ eggs to determine whether viral adaptation during passage would alter antigenic specificity.33 During the course of the fieldwork, however, the clinical characteristics of the outbreak changed and it became apparent to the investigators that another etiology had supervened. Nevertheless, the specimen collections continued, because Hilleman thought that “the possible personal consequences of a flawed and expensive investigation was [sic] recognized and the logic for extrication, in this instance, seemed to be to search for the cause of the second respiratory disease (p 508).”32 Using explant tissue culture techniques described by Enders et al.1 just 5 years previously, Hilleman’s team isolated multiple strains of a novel virus from the throats of recruits.34 The newly discovered agents were subsequently determined to be the major cause of ARD and primary atypical pneumonia in noncombat military settings, with as many as 80% of recruits in some settings developing infection and 20% requiring hospitalization.35 The latter rate translated into hundreds of hospital admissions per week at some large recruit centers.36 Newly available tissue culture techniques facilitated the development of quantitative assays for the viruses, resulting in the expeditious characterization of the epidemiology and clinical features of diseases caused Military Medicine, Vol. 170, April Supplement 2005 Fig. 4. Dr. Maurice R. Hilleman. Maurice Hilleman (born in 1919) was born and reared on the family farm in rural Montana, where he developed his interests in biology. A scholarship to Montana State University aborted his plan to become a manager at the local J.C. Penney store and led him to the University of Chicago doctoral program, where he wrote an award-winning dissertation on Chlamydia. Following a brief stint in industry, he became a civilian member of the team at the WRAIR in 1949 studying communicable diseases of military import, under Dr. Joseph Smadel. As chief of the Respiratory Diseases Branch, he developed the technologies to analyze the epidemiology and pathogenesis of epidemic and pandemic influenza and is credited with the codiscovery of the adenoviruses. In 1957, he joined Merck, where he continues his legacy of scientific endeavor and discovery. Hilleman is considered to be responsible for the development of more vaccines than any other individual; his credits include mumps, measles, hepatitis B, and varicella, among a host of others (photograph courtesy of Infectious Diseases Society of America; used with permission). by these agents, as well as the biology of the viruses responsible.37 Multiple serotypes were recognized; one, type 7, was shown to be oncogenic in newborn hamsters.32 During the same time period, other investigators isolated biologically similar viruses from the adenoids and tonsils of healthy children. The two sets of findings were found to be biologically related; the newly discovered agents were classified as “adenoviruses.”38 Because the impact of adenoviral infections on training, medical resources, and overall economic costs to the military was enormous, vaccine development was a high priority. Subsequent studies demonstrated that adenovirus types 4 and 7 accounted for the majority of ARD cases among recruits.39 Using the epidemiologic information and the ability to grow adenoviruses in monkey kidney cells, a Formalin-inactivated, bivalent vaccine for adenovirus was developed in 1956, within 3 years of the initial description of the infectious agent, and safety and efficacy trials of this parenterally administered product were initiated at Fort Dix and Fort Leonard Wood. The vaccine proved to be more than 90% effective in large field trials and was licensed in 1958.40 Manufacturing problems, however, including partial loss of antigenicity in large-scale production and seed lot contamination by simian virus 40 (an oncogenic virus that also contaminated oral and inactivated poliovirus vaccines during the same time period), were identified, and the license was revoked in 1963.41 Live types 4 and 7 adenovirus vaccines, given as enterically History of U.S. Military Vaccine Development coated capsules, were developed in the middle 1960s, under the leadership of COL Edward Buescher (Fig. 5), and were extensively studied at military facilities.42 Selective gastrointestinal infection without illness or transmission of vaccine virus to close contacts occurred after oral vaccination; the vaccines stimulated serum neutralizing antibody in more than 95% of cases.43 The products, given either singly or in combination, were found to be safe, immunogenic, and highly protective, resulting in a 50% decrease in the rate of hospitalization attributable to ARD among recruits and a more than 95% reduction in the rate of illness attributable to type 7 adenovirus.44 Beginning in 1971, the two products were routinely administered to military recruits within hours after their arrival at basic training. A costbenefit analysis of the U.S. military’s adenovirus surveillance and the first 2 years of the vaccination program demonstrated a favorable cost-benefit ratio, even accounting for the one-time costs related to vaccine development.45 As a result of adenovirus vaccine use during the period from 1971 to 1996, essentially no outbreaks in military units of ARD related to either of the adenovirus serotypes used in the vaccines were reported. Unfortunately, the sole manufacturer of the vaccines ceased production in 1996, and a program of reduced vaccine use was instituted before the depletion of stocks in 1999.41 The unavailability of adenovirus vaccines has resulted in a recrudescence of ARD attributable to these agents. Recent surveillance data from sentinel military populations revealed that 55% of throat cultures obtained from recruits with ARD between 1996 and 1998 yielded adenoviruses, largely types 4 Fig. 5. COL Edward L. Buescher. Ed Buescher (1925–1989) grew up in Cincinnati, Ohio, and received his medical degree from the University of Cincinnati in 1948. While there he worked in the laboratory of Dr. Albert Sabin. Buescher entered the U.S. Army in the early 1950s, serving in Korea and earning the Bronze Star. While stationed in Japan after the war, he performed seminal work on the ecology, vector transmission, natural history, and pathogenesis of Japanese B encephalitis, a disease of major military importance in Asia. After his return to WRAIR as chief of the Department of Virus Diseases, he is credited, along with Paul Parkman, Malcolm Artenstein, and a team from Harvard Medical School, with the codiscovery of the rubella virus in 1961, which led within 7 years to an effective rubella vaccine. Buescher was awarded the Gorgas Medal by the Army in 1965, in recognition of his work in the area of infectious diseases; he subsequently earned the Legion of Merit with Presidential Citation for his enormous contributions to military medicine (photograph courtesy of Theodore E. Woodward, MD57; used with permission). 9 and 7.30 Unvaccinated personnel with ARD were significantly more likely to be infected with adenovirus than were their vaccinated counterparts. Outbreaks of adenovirus infection causing ARD have been reported for a variety of military centers since the cessation of routine vaccination and have generally resulted from a large pool of susceptible hosts, exemplified by the findings in one study that nearly 90% of new recruits were seronegative for either type 4 or 7 adenovirus.30 Recognizing the benefit of adenovirus vaccine, the federal government has taken steps to reinstitute the program by contracting with industry sources to develop and produce the product for the future. Meningococcal Meningitis and the Meningococcal Vaccine Meningitis caused by Neisseria meningitidis had been a wellrecognized complication of military mobilizations, whether in or away from a combat theater, since the late 19th century. Epidemic disease erupted during World War I among U.S. troops and, because a similar experience was predicted with the American entry into World War II, the newly formed Armed Forces Epidemiological Board created its Commission on Meningococcal Meningitis in 1941 to accelerate scientific study of the problem.46 From 1941 to 1943, the commission documented more than 5,000 domestic cases among U.S. Army personnel.46 Meningococcal disease was largely a problem of recruits during their first 3 months of military service; the incidence was inversely associated with duration of service, findings consistently noted in the commission’s studies. Although sulfa drugs, which were discovered in 1937, were effective as therapy and prophylaxis for meningococcal disease, reports of sulfa-resistant organisms were already emerging by 1945; by the early 1960s, the majority of meningococci were resistant to these agents.47 An epidemic of group B meningococcal disease in 1964 at Fort Ord, California, in which 50% of the civilian strains were sulfa-resistant and the subsequent report by naval investigators of a Moroccan epidemic of sulfa-resistant group A meningococci48 confirmed the clinical consequences of drug resistance. The problem of the rapid emergence of sulfa resistance (and later rifampin resistance) led experts in the field to the belief that a meningococcal vaccine represented the best hope for long-term control of the problem in military populations. Fortunately, military scientists had predicted the problem of drug resistance and had become engaged, by the middle 1960s, in extensive laboratory investigations into the pathogenesis and immunology of N. meningitidis. In 1969, Dr. Malcolm Artenstein, the chief of the Department of Bacteriology at WRAIR (Fig. 6), and two young Medical Corps officers, CPT Emil Gotschlich and CPT Irving Goldschneider, published a series of five classic articles that described in detail the human immunologic response to meningococci.49–53 They demonstrated, using sera prospectively acquired from military recruits at Fort Dix, New Jersey, the protective role of circulating antibody against clinical disease. Eightynine percent of recruits had preexisting antibodies and none acquired meningococcal disease, whereas 38% of recruits who lacked serum bactericidal antibodies and were exposed to pathogenic strains of meningococci developed systemic disease.49 The investigators also demonstrated that the group-specific polysaccharide was a key antigenic determinant of N. meningitidis,50 and they described novel methods for the preparation of high-molecular weight group A and C polysaccharides.51 Finally, the WRAIR Military Medicine, Vol. 170, April Supplement 2005 10 Fig. 6. Dr. Malcolm S. Artenstein. Malcolm Artenstein (1930 –1976) grew up in Lowell, Massachusetts, attended Brown University, and received his medical degree from Tufts University. There, he studied the fledgling field of infectious diseases under Dr. Louis Weinstein. His early work in viral diseases and the human immune response to these agents led to an assignment in the Department of Virus Diseases, under COL Ed Buescher, at WRAIR in 1959. As a young officer there, he is credited with codiscovering the rubella virus in 1961. Shortly after leaving the Army and returning to Boston to work with Dr. Weinstein, Artenstein accepted the opportunity to return to WRAIR in 1963, as a civilian, to lead the Department of Bacteriology. During his second tenure at WRAIR, and for the remainder of his career, the major focus of his work was meningococcal disease, a problem of significant military importance and a cause of global epidemics. Artenstein led the team that described the human immune response to N. meningitidis, discovered the correlate of protective immunity, and developed the first effective vaccine against meningococci. He served on the Armed Forces Epidemiological Board Commission on Respiratory Diseases and, in recognition of his seminal contributions to the field of infectious diseases, was awarded the Gorgas Medal by the Army in 1971 and the Squibb Award by the Infectious Diseases Society of America in 1974. His legacy continues in the significant contributions to infectious diseases made by the numerous researchers and clinicians he trained during his career (photograph courtesy of Dr. Andrew W. Artenstein). investigators demonstrated the lack of toxicity of such preparations, administered parenterally, for small mammals; their immunogenicity among humans, with high concentrations of groupspecific bactericidal antibodies being induced after a single intradermal injection; and significant reduction of the carrier rates of group C meningococci in the nasopharyngeal compartment, the major reservoir for transmission.52,53 The idea of using polysaccharides as immunogens was an outgrowth of work on pneumococci performed at the Rockefeller Institute by Drs. Michael Heidelberger, Oswald Avery, and Colin MacLeod in the 1930s and early 1940s.46 The latter two, in collaboration with Dr. Maclyn McCarty, were the first to identify DNA as the carrier of genetic material, in experiments with pneumococci published in 1944. Heidelberger was particularly interested in the immune response to the polysaccharide constituents of Streptococ- Military Medicine, Vol. 170, April Supplement 2005 History of U.S. Military Vaccine Development cus pneumoniae, which led to a successful trial of a tetravalent pneumococcal vaccine among military personnel in 1945 (Table I). Dr. Elvin Kabat, a colleague of Heidelberger at Columbia University, expanded the potential importance of bacterial polysaccharide antigens in host immunity by purifying group A meningococcal polysaccharide and demonstrating the presence of anticapsular antibodies in convalescent sera of experimentally infected animals.52 However, Kabat’s polysaccharide proved to be a poor immunogen in humans, probably because of its low molecular weight. With the novel preparation of high-molecular weight meningococcal polysaccharides developed by the WRAIR investigators,51 elucidation of the determinant of protective immunity against meningococci, and data from a small Phase I clinical trial among humans, military investigators developed plans for a large field trial of a group C meningococcal polysaccharide vaccine. A number of factors complicated the design of a group-specific meningococcal vaccine efficacy study: (1) The relatively low incidence of meningococcal disease, even during epidemics, necessitated a large sample size. (2) The potential “herd” effect of vaccination on the carriage rate in the unimmunized group might have biased the data if too large a sample was vaccinated. (3) Predicting the location of epidemics was impossible, necessitating the use of multiple Army recruit training centers. (4) Because of the known rapid acquisition of the carrier state among newly arrived recruits, informed consent and vaccination had to be accomplished within days of arrival.54 In the pivotal efficacy study, 13,763 men at five different military posts were vaccinated with a group C polysaccharide and more than 53,000 men served as unimmunized control subjects. The vaccine proved safe, reduced the acquisition rate of group C meningococci (although not that of other meningococcal groups), and significantly reduced the rate of systemic meningococcal disease caused by group C organisms during an 8-week period, with 38 cases in the control group and one case involving a vaccinated soldier (p ⬍ 0.01), i.e., an 87% protective effect.54 In a second large field trial, with sample sizes similar to those in the first, the protective effect was similar.55 On the basis of the aforementioned data, the military began administering meningococcal C polysaccharide vaccine to all recruits in late 1970, resulting in the virtual elimination of meningococcal C disease as a major military health problem.56 The current tetravalent (groups A, C, Y, and W135) vaccine, licensed in 1981, is indicated for military recruits, persons without spleens, individuals with terminal complement deficiencies, travelers to areas where meningococcal disease is hyperendemic or epidemic, and subgroups of college students.56 In the United Kingdom and several other countries, group C polysaccharide conjugated to carrier proteins (tetanus toxoid or diphtheria toxin derivatives) has been used with remarkable success in reducing the burden of disease among children, for whom polysaccharides are poorly immunogenic.56 Conclusions The U.S. military has a longstanding vested interest in the development of vaccines, because infectious diseases have traditionally constituted major threats to the health of fighting forces and their families. 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