EMERGING INFECTIOUS DISEASES
Volume 1, Number 1, January-March 1995

Perspectives

Emerging Infections: Getting Ahead of the Curve

David Satcher, M.D., Ph.D.
Centers for Disease Control and Prevention, Atlanta, Georgia, USA

Abstract
The early history of infectious diseases was characterized by
sudden, unpredictable outbreaks, frequently of epidemic proportion.
Scientific advances in the late 19th and early 20th centuries
resulted in the prevention and control of many infectious diseases,
particularly in industrialized nations. Despite these improvements
in health, outbreaks of infectious disease continue to occur, and
new infections emerge. Since 1987, the National Academy of
Science's Institute of Medicine (IOM) has published three reports
that have identified erosion of the public health infrastructure
among the factors contributing to new and reemerging infectious
diseases. In partnership with many public and private organizations
in the United States and abroad, the Centers for Disease Control
and Prevention (CDC) has developed a strategic plan that addresses
the priorities set forth in the IOM reports and serves as a guide
for CDC and its partners to combat emerging microbial threats to
health. Laboratory-based surveillance, better communication
networks, and improvements in the public health infrastructure are
the cornerstones of the strategy. Emerging Infectious Diseases, a
new periodical produced by CDC, will serve as a forum for exchange
of information about incipient trends in infectious diseases,
analysis of factors contributing to disease emergence, and
development and implementation of prevention measures.

"Nothing in the world of living things is permanently fixed."  
Hans Zinnser--Rats, Lice and History, 1935




Early History of Infectious Diseases

Infectious diseases have plagued humans since the dawn of
civilization (1-5). The history of these diseases provides a
valuable perspective for evaluating current trends. Humans are
presumed to have originated in tropical climates and to have been
affected by the same parasitic diseases as other primates in these
areas. As available supplies of game diminished, early hunters
migrated into temperate zones which were free of tropical
parasites. Historians speculate that humans were relatively safe
from infectious diseases during that period. Later, however, as
agriculture began to provide a substantial portion of the human
diet, populations stabilized and grew. Eventually, populations
reached a size that would support persistent person-to-person
spread of infectious microorganisms. With this newly established
mode of transmission, infectious diseases soon became widespread.
The exact origins of many infectious agents remain obscure, but
with the advent of large populations, humans eventually became the
established reservoir of many agents. Infected animals and
contaminated food and water were additional sources of infectious
microorganisms.

Dissemination of infectious diseases intensified as civilizations
progressed. Caravans of traders carried new pathogens to
unsuspecting and susceptible populations. Explorers and later
conquering armies brought infectious microorganisms to new
continents. Stowaway rats and other vermin in the holds of ships
traveled down the moorings when the ships docked, bringing fleas,
lice, and deadly pathogens to a new world. Sporadic epidemics of
plague, smallpox, typhus, and measles ravaged cities, decimated
armies, and altered the course of history.

19th Century Discoveries Lead to Infectious Disease Prevention and
Control

Control of many infectious diseases became possible with the
pioneering work of Robert Koch and Louis Pasteur and the
introduction of the germ theory of disease. With bacteriologic
cultivation techniques came the first isolation and identification
of etiologic agents; virus cultivation and identification became
available some decades later. Reservoirs of microorganisms and
their life cycles were identified; the epidemiology and natural
history of many infectious diseases were described, and successful
control measures were initiated. Water treatment, vector control,
and rodent reduction programs followed. By the beginning of the
20th century, the principles of vaccination, established
empirically by Edward Jenner more than 100 years earlier, began to
be realized in earnest. Antibiotics were discovered, and
disinfectants were developed. Collectively, these control measures
dramatically decreased the incidence and prevalence of many
infectious diseases and their fatality rates. The early part of
this century is appropriately regarded as a golden age in public
health.

New and Reemerging Infectious Diseases--A Contemporary Problem

Compared with earlier generations, we possess an enormous
scientific base, and the rate of acquisition of new information
about infectious diseases is at a historic high. Moreover, thanks
in large measure to effective childhood immunization programs,
including the President's Childhood Immunization Initiative, many
infectious diseases are under control, particularly in the
industrialized world. The elimination of smallpox in 1977 stands as
a towering achievement in the fight against infectious diseases.
However, many infectious diseases have persisted and have displayed
a remarkable ability to re-emerge after lengthy periods of
stability. Therefore, we must be ever mindful of the cyclical
nature of disease trends. 

A careful review of infectious disease trends shows a fragile
equilibrium between humans and infectious microorganisms.
Infectious diseases are still broadly endemic and maintain a large
reservoir of agents that have the potential for rapid and
widespread dissemination. Infectious diseases remain the leading
cause of death worldwide, even as the International Code of
Diseases places many infectious diseases in other categories. For
example, meningitis and cirrhosis are classified as diseases of the
nervous system and liver, respectively, and only 17% of deaths
attributable to infections are actually included in the codes for
parasitic and infectious diseases (6). In the United States, each
year, approximately 25% of physician visits are attributable to
infectious diseases, with direct and indirect costs, including
those for human immunodeficiency virus (HIV) infection and related
illnesses, estimated at more than $120 billion (7).

Persons living in tropical climates are still as vulnerable to
infectious diseases as their early ancestors were. Each year more
than one million children die of malaria in sub-Saharan Africa
alone (8); worldwide, approximately 200 million people have
schistosomiasis (9), and each year 35-60 million people contract
dengue (10). Moreover, infectious diseases and their attendant
problems are not confined to tropical climates. For example, an
estimated 600,000 cases of pneumonia occur in the United States
each year and cause 25,000 to 50,000 deaths (11). More than 10,000
cases of diphtheria have occurred in Russia since 1993 because of
inadequate levels of immunization (12). Despite a century of
scientific progress, infectious diseases still cause enormous human
suffering, deplete scarce resources, impede social and economic
development, and contribute to global instability. The potential
for even greater dissemination looms as a continuous threat.

Recent outbreaks underscore the potential for the sudden appearance
of infectious diseases in currently unaffected populations. In the
United States, contamination of the municipal water supply in
Milwaukee, Wisconsin, in 1993 resulted in an outbreak of
cryptosporidiosis that affected an estimated 400,000 people;
approximately 4,400 persons required hospitalization (13). In the
1990s, epidemic cholera reappeared in the Americas, after being
absent for nearly a century; from 1991 through June of 1994 more
than one million cases and nearly 10,000 deaths were reported (14).
During the 1980s, tuberculosis reemerged in the United States after
decades of decline, and drug-resistant strains have made its
control more difficult (15,16). The increasing prevalence of
antibiotic-resistant strains of gonococci, pneumococci,
enterococci, and staphylococci portend of other serious treatment
and control failures. Many other examples of emerging infections
could be given (17,18). 

New infectious diseases, often with unknown long-term public health
impact, continue to be identified. Table 1 lists major diseases or
etiologic agents identified just within the last 20 years (19-41).
New agents are regularly added to the list, particularly with the
availability of nucleic acid amplification techniques for detecting
and identifying otherwise noncultivable microorganisms (40, 42).

Table 1. Major Etiologic Agents, Infectious Diseases Identified
Since 1973*

Year  Agent             Disease                           Reference

1973 Rotavirus        Major cause of infantile diarrhea       19
                       worldwide
1975 Parvovirus       Fifth disease; Aplastic crisis          20
      B19              in chronic hemolytic anemia 
1976 Cryptosporidium  Acute enterocolitis                     21
      parvum
1977 Ebola virus      Ebola hemorrhagic fever                 22
1977 Legionella       Legionnaires' disease                   23
      pneumophila
1977 Hantaan virus    Hemorrhagic fever with renal            24
                       syndrome (HFRS)
1977 Campylobacter    Enteric pathogens distributed           25
      sp.              globally
1980 Human T-cell     T-cell lymphoma--leukemia                26
      lymphotropic 
      virus-I (HTLV I)
1981 Staphylococcus   Toxic shock syndrome associated         27
      toxin            with tampon use 
1982 Escherichia coli O157:H7, Hemorrhagic colitis;           28
                        hemolytic uremic syndrome 
1982 HTLV II          Hairy cell leukemia                     29
1982 Borrelia         Lyme disease                            30
      burgdorferi
1983 Human immuno-    Acquired immunodeficiency               31
      deficiency       syndrome (AIDS)
      virus (HIV)
1983 Helicobacter     Gastric ulcers                          32
      pylori
1988 Human            Roseola subitum                         33
      herpesvirus-6 
      (HHV-6)
1989 Ehrlichia        Human ehrlichiosis                      34
       chaffeensis
1989 Hepatitis C      Parenterally transmitted non-A,         35
                       non-B hepatitis
1991 Guanarito virus  Venezuelan hemorrhagic fever            36
1992 Vibrio cholerae  New strain associated with              37
      O139             epidemic cholera
1992 Bartonella        Cat-scratch disease; bacillary         38,39
      (= Rochalimaea)  angiomatosis 
      henselae 
1993 Hantavirus        pulmonary syndrome          40
      isolates
1994 Sabi  virus       Brazilian hemorrhagic fever            41


* Compiled by CDC staff. Dates of discovery are assigned on the
basis of the year the isolation or identification of etiologic
agents was reported.


In some cases, etiologic agents have been identified as the causes
of known diseases or syndromes (e.g., rotavirus, parvovirus, human
T-cell lymphotropic viruses I and II (HTLV I/II), and human
herpesvirus type 6, (HHV-6); in other cases, diseases became better
recognized or defined (e.g., Legionnaires' disease, Lyme disease,
human ehrlichiosis). Still others are entirely new: with some
parallels to medieval times, a previously unknown and deadly
disease, acquired immunodeficiency syndrome (AIDS), originated from
uncertain sources in one part of the world and became globally
disseminated; this time the disease spread at a rate that would
have been unthinkable in medieval times. Clearly, the complete
history of infectious diseases remains to be written.

Getting Ahead of the Curve

Recent disquieting infectious disease trends have not gone
unrecognized, and their similarity to earlier disease trends with
immense global consequences has not gone unnoticed. Primary
responsibility for addressing new and reemerging infectious
diseases rests squarely with the custodians of public health.
Indeed, the fundamental maxim of public health must guide current
prevention programs: the health of the individual is best ensured
by maintaining or improving the health of the entire community.
Core functions necessary to ensure the health of the public were
defined in the National Academy of Science's Institute of Medicine
(IOM) report on The Future of Public Health (43):

Assessment of health status, risks, and services
Development of health policy
Assurance of quality health services

Surveillance (assessment) is the sine qua non of infectious disease
prevention programs; however, for surveillance to be effective it
must be specific. Consider, for example, surveillance of viral
hepatitis. Only after the various agents of viral hepatitis were
identified and specific laboratory testing became available was it
possible to explain trends in disease prevalence and establish the
epidemiologic principles underlying the different modes of
transmission. Specific laboratory testing is also the basis of
screening programs that ensure the safety of the blood supply
against hepatitis B and hepatitis C. Agent-specific surveillance is
a critical component of many immunization programs. Vaccines to
Haemophilus influenzae type b, (Hib), for example, were developed
in response to laboratory-based surveillance that identified Hib as
a major cause of invasive disease in children. The effectiveness of
the Hib vaccination campaign in the United States has been dramatic
(Figure 1).  (Figure cannot be viewed in ASCII.) Similar approaches
will ensure appropriate formulation of other developmental
vaccines. Monitoring antibiotic resistance is yet another important
example of the value of laboratory-based surveillance. Within this
context, current discoveries of etiologic agents and diseases
(Table 1) are reasons for optimism. The potential for improvements
in assessment and prevention of these and other newly discovered
diseases is reminiscent of the watershed years of Koch and Pasteur.

We cannot overstate the role of behavioral science in our effort to
"get ahead of the curve" with emerging infections. Having the
science or laboratory technology to control infectious diseases is
not enough, unless we can influence people to behave in ways that
minimize the transmission of infections and maximize the efforts of
medical interventions. For example, even though HIV/AIDS does not
have a vaccine or cure, it is almost entirely preventable. For many
people, however, reducing the risk for HIV infection and AIDS
requires important changes in lifestyle or behavior. We must use
our knowledge of human behavior to help people make lifestyle
changes and prevent disease.

Another illustration of the need to use behavior science is the
problem of antibiotic resistance. To a great extent, this problem
is related to the behavior of both physicians and patients.
Physicians continue to use antibiotics inappropriately, and
patients continue to demand antibiotic treatment when it is not
indicated, for example, for the common cold. As society changes and
institutions such as day care centers and prisons become more
crowded, the spread of infectious diseases is exacerbated. For
homeless and drug-dependent populations, completing a 6- to 9-month
course of therapy for tuberculosis is difficult, and the failure to
complete the therapy increases the risk for drug-resistant
tuberculosis in the community.

Microbiologists, infectious disease specialists, and other basic
and clinical scientists must collaborate with behavioral scientists
in an interdisciplinary effort to prevent and control emerging
infections.

The Future of Public Health emphasizes the relationship between a
sound public health infrastructure and infectious disease
prevention programs. Infrastructure improvements must become a
national priority: certainly they are among CDC's top priorities.
Improvements in infectious disease surveillance are particularly
needed (44). Enriching the capacity to respond to urgent threats to
health and developing nationwide prevention strategies are also CDC
priorities. To combat new and reemerging infectious diseases, CDC,
in collaboration with other federal agencies, state and local
health departments, academic institutions, professional societies,
international organizations, and experts in public health
infectious diseases and medical microbiology developed a
plan--Addressing Emerging Infectious Disease Threats: A Prevention
Strategy for the United States (7). The plan has four major goals:

Surveillance and response--detect, promptly investigate, and
monitor emerging pathogens, the diseases they cause, and the
factors influencing their emergence

Applied research--integrate laboratory science and epidemiology to
optimize public health practice

Prevention and control--enhance communication of public health
information about emerging diseases and ensure prompt
implementation of prevention strategies

Infrastructure--strengthen local, state, and federal public health
infrastructures to support surveillance and implement prevention
and control programs

CDC's plan provides a framework for the agency to work
collaboratively with its many partners to identify and reverse
worrisome trends in infectious diseases.

The need for implementing CDC's plan is urgent, given the extremely
dynamic nature of disease trends and the complexity of factors
contributing to disease emergence; these were outlined in detail in
the 1992 IOM report--Emerging Infections: Microbial Threats to
Health in the United States (45) and are discussed in a companion
article by Stephen S. Morse, Ph.D., in this issue. The IOM report
concludes that infectious diseases must be viewed as but one
component of a dynamic and complex global ecology, which is shaped
and buffeted by technologic, societal, economic, environmental, and
demographic changes, not to mention microbial change and
adaptation.

Clearly, broader coalitions are needed, and communication must
improve if we are to  get ahead of the curve.  This new periodical
is part of the overall strategy to draw worldwide attention to
emerging infections and improve communication. Given the
multiplicity of factors contributing to disease emergence, Emerging
Infectious Diseases (EID) will present relevant concepts from
professionals in multiple disciplines and disseminate information
about emerging infectious diseases in order to develop and apply
ecologically acceptable interventions that will benefit humankind.
Prevention and control of new and emerging infectious diseases
depend on the participation of scientists and other professionals
in the public and private sectors.

CDC will make EID available by print and electronically to
facilitate rapid communication. We hope that in the process EID
will promote the exchange of infectious disease information through
global electronic networks and bulletin boards.

Although there are many similarities between our vulnerability to
infectious diseases and that of our ancestors, there is one
distinct difference: we have the benefit of extensive scientific
knowledge. Ultimately, our success in combatting infectious
diseases will depend on how well we use available information. A
recent report by the Carnegie Commission  Science, Technology, and
Government for a Changing World,  provides valuable insight in this
regard (46). Commenting on the Earth Summit in Rio de Janeiro in
1992, the report emphasizes the need to shift from the
 manifestations of environmental changes in the air, land, water,
and plant and animal kingdoms to the causes of those changes. 
Indeed, the advice of that report challenges us all--"our capacity
to generate, integrate, disseminate, and apply knowledge will
determine the human prospect in the 21st century."

Dr. Satcher is director of the Centers for Disease Control and
Prevention, Atlanta, Georgia. He was president of Meharry Medical
College, Nashville, Tennessee, from 1982 to 1993 and is a former
faculty member of the King-Drew Medical Center and the UCLA School
of Medicine, Los Angeles, California.

Address for correspondence: David Satcher, Centers for Disease
Control and Prevention, 1600 Clifton Road, Atlanta, GA 30333, USA,
fax 404-639-3030, e-mail eideditor@cidod1.em.cdc.gov.

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