An epidemic (from Greek ἐπί epi "upon or above" and δῆμος demos "people") is the rapid spread of disease to a large number of patients among a given population within an area in a short period of time.
This example of an epidemic of 2014 is showing the number of new infections at this time.
Epidemics of infectious diseases are generally caused by several factors including a significant change in the ecology of the areal population (e.g., increased stress maybe additional reasion or increase in the density of a vector species), the introduction of an emerging pathogen to an areal population (by movement of pathogen or host) or an unexpected genetic change that is in the pathogen reservoir.
Generally, epidemics concerns with the patterns of infectious disease spread. An epidemic may occur when host immunity to either an established pathogen or newly emerging novel pathogen is suddenly reduced below that found in the endemic equilibrium and the transmission threshold is exceeded.
An epidemic may be restricted to one location within one country or further develop more locations in a country, however, if it spreads to other regional countries or even among continents but only if affects or threatens a substantial number of population, it may be overseen as within the terms of pandemic. The registering and announcing of epidemic usually requires a good understanding of a baseline rate of incidence; epidemics for certain diseases, such as influenza, are defined as reaching some defined increase in incidence above this baseline. A few cases of a very rare disease may be classified as an epidemic, while many cases of a common disease (such as the common cold) would not. An epidemic can cause enormous damage through financial and economic losses in addition to impaired health and loss of life.
In medicine epidemics where well known and studied in 19th century. We can trace the study of epidemics to late 18th century when this medical population studies emerged.
However even early philosopher in Ancient Greece and Rome studied diseases and it was Hippocrates who first noticed that some diseases have epidemic type (he wrote on pestilence).Galen also studied the epidemic diseases and how they appear.
It is possible to notice some medical knowledge also in Greek literature, including Homer (8th century), but it was first Thucydides who wrote during the time of Hippocrates on Peloponnesian wars using or referring to term epidemic for disease that with weather and wind and air spreads among wider regions.
The term epidemic is derived from a word form attributed to Homer's Odyssey, which work later was taken by epidemiologists and epidemology's medical meaning for the Epidemics, as treatise made by Hippocrates.
Before Hippocrates, epidemios, epidemeo, epidamos, and other variants had meanings similar to the current definitions of "indigenous" or "endemic".
Thucydides' description of the Plague of Athens is considered one of the earliest written accounts of a disease epidemic using the exact term. By the early 17th century, the terms endemic and epidemic referred to contrasting conditions of population-level disease, with the endemic condition at low rates of occurrence and the epidemic condition widespread. The term "epidemic" has become emotionally charged.
The Centers for Disease Control and Prevention defines epidemic broadly: "the occurrence of more cases of disease, injury, or other health condition than expected in a given area or among a specific group of persons during a particular period. Usually, the cases are presumed to have a common cause or to be related to one another in some way (see also outbreak)." The terms "epidemic" and "outbreak" have often been used interchangeably. Researchers Manfred S. Green and colleagues propose that the latter term be restricted to smaller events, pointing out that Chambers Concise Dictionary and Stedman's Medical Dictionary acknowledge this distinction.
The conditions which govern the outbreak of epidemics include infected food supplies such as contaminated drinking water and the migration of populations of certain animals, such as rats or mosquitoes, which can act as disease vectors.
Epidemics can be related to seasonality of certain infectious agents. Seasonality may enter into any of the eight key elements of the system: (1) susceptible recruitment via reproduction, (2) transmission, (3) acquired immunity and recovery, (4) waning immunity, (5) natural mortality, (6) symptomatology and pathology (which may be acute or chronic, depending on the disease), (7) disease-induced mortality, and (8) cross-species transmission. Influenza, the common cold, and other infections of the upper respiratory tract, such as sore throat, occur predominantly in the winter.
There is another variation, both as regards the number of people affected and the number who die in successive epidemics: the severity of successive epidemics rises and falls over periods of five or ten years.
Common source outbreakEdit
In a common source outbreak epidemic, the affected individuals had an exposure to a common agent. If the exposure is singular and all of the affected individuals develop the disease over a single exposure and incubation course, it can be termed a point source outbreak. If the exposure was continuous or variable, it can be termed a continuous outbreak or intermittent outbreak, respectively.: 56
In a propagated outbreak, the disease spreads person-to-person. Affected individuals may become independent reservoirs leading to further exposures.: 56
Many epidemics will have characteristics of both common source and propagated outbreaks (sometimes referred to as mixed outbreak).
For example, secondary person-to-person spread may occur after a common source exposure or an environmental vector may spread a zoonotic diseases agent.: 56–58
Airborne transmission: Airborne transmission is the spread of infection by droplet nuclei or dust in the air. Without the intervention of winds or drafts the distance over which airborne infection takes place is short, say 10 to 20 feet.
Arthropod transmission: Arthropod transmission takes place by an insect, either mechanically through a contaminated proboscis or feet, or biologically when there is growth or replication of an organism in the arthropod.
Biological transmission: Involving a normal biological process, e.g., passing a stage of development of the infecting agent in an intermediate host. Opposite to mechanical transmission.
Contact transmission: The disease agent is transferred directly by biting, sucking, chewing or indirectly by inhalation of droplets, drinking of contaminated water, traveling in contaminated vehicles.
Cyclopropagative transmission: The agent undergoes both development and multiplication in the transmitting vehicle.
Developmental transmission: The agent undergoes some development in the transmission vehicle.
Fecal-oral transmission: The infectious agent is shed by the infected host in feces and acquired by the susceptible host through the ingestion of contaminated material.
Horizontal transmission: Lateral spread to others in the same group and at the same time; spread to contemporaries.
Propagative transmission: The agent multiplies in the transmission vehicle.
Vertical transmission: From one generation to the next, perhaps transovarially or by intrauterine infection of the fetus. Some retroviruses are transmitted in the germline, i.e. their genetic material is integrated into the DNA of either the ovum or sperm.
Prevention and prevention preparationsEdit
Disease prevention preparations for an epidemic include having a disease indicators or rates surveillance system; the ability to quickly dispatch emergency workers, especially local-based emergency workers; and a legitimate way to guarantee the safety and health of health workers.
Effective preparations for a response to a pandemic are multi-layered. The first layer is a disease surveillance system. Tanzania, for example, runs a national lab that runs testing for 200 health sites and tracks the spread of infectious diseases. The next layer is the actual response to an emergency. According to U.S.-based columnist Michael Gerson in 2015, only the U.S. military and NATO have the global capability to respond to such an emergency. Still, despite the most extensive preparatory measures, a fast-spreading pandemic may easily exceed and overwhelm existing health-care resources. Consequently, early and aggressive mitigation efforts, aimed at the so-called "epidemic curve flattening" need to be taken. Such measures usually consist on non-pharmacological interventions such as social/physical distancing, aggressive contact tracing, "stay-at-home" orders, as well as appropriate personal protective equipment (i.e., masks, gloves, and other physical barriers to spread).
^ abcdefGreen MS, Swartz T, Mayshar E, Lev B, Leventhal A, Slater PE, Shemer J (January 2002). "When is an epidemic an epidemic?" (PDF). The Israel Medical Association Journal. 4 (1): 3–6. PMID11802306.
^Further Report and Papers on Epidemic Influenza, 1889-92: With an Introduction by the Medical Officer of the Local Government Board. Great Britain. Local Government Boardр H.M. Stationery Office, 1893
^ abcA Brief History of Epidemic and Pestilential Diseases, Noah Webster, Hudson & Goodwin, 1799, p. 1-11
^ abcdeMartin PM, Martin-Granel E (June 2006). "2,500-year evolution of the term epidemic". Emerging Infectious Diseases. 12 (6): 976–80. doi:10.3201/eid1206.051263. PMC3373038. PMID16707055.
^Lodge T (1603). A treatise of the plague: containing the nature, signes, and accidents of the same, with the certaine and absolute cure of the fevers, botches and carbuncles that raigne in these times. London: Edward White.
^Controlling the global obesity epidemic, the World Health Organization
^Martinez ME (November 2018). "The calendar of epidemics: Seasonal cycles of infectious diseases". PLOS Pathogens. 14 (11): e1007327. doi:10.1371/journal.ppat.1007327. PMC6224126. PMID30408114.
^Marcovitch H, ed. (2009). "Epidemic". Black's Medical Dictionary (42nd ed.). London: A&C Black. ISBN 978-1-4081-4564-7.
^ abcdStawicki SP, Jeanmonod R, Miller AC, Paladino L, Gaieski DF, Yaffee AQ, et al. (2020). "The 2019-2020 Novel Coronavirus (Severe Acute Respiratory Syndrome Coronavirus 2) Pandemic: A Joint American College of Academic International Medicine-World Academic Council of Emergency Medicine Multidisciplinary COVID-19 Working Group Consensus Paper". Journal of Global Infectious Diseases. 12 (2): 47–93. doi:10.4103/jgid.jgid_86_20. PMC7384689. PMID32773996. S2CID 218754925.
^Studdert VP, Gay CC, Charles Blood DC, eds. (2012). "Transmission". Saunders Comprehensive Veterinary Dictionary (4th ed.). Philadelphia: Elsevier Health Sciences. ISBN 978-0-7020-3231-8.
^Gates B (April 2015). "The next epidemic--lessons from Ebola". The New England Journal of Medicine. 372 (15): 1381–4. doi:10.1056/NEJMp1502918. PMID25853741.
Presentation by Brown on Influenza, March 5, 2019, C-SPAN
American Lung Association (April 2007). "Multidrug Resistant Tuberculosis Fact Sheet". Archived from the original on 30 November 2006. Retrieved 29 November 2007.
Bancroft, EA (October 2007). "Antimicrobial resistance: it's not just for hospitals". JAMA. 298 (15): 1803–04. doi:10.1001/jama.298.15.1803. PMC2536104. PMID17940239.
Brook, Timothy; et al. "Comparative pandemics: the Tudor–Stuart and Wanli–Chongzhen years of pestilence, 1567–1666" Journal of Global History (2020) 14#3 pp 363–379 emphasis on Chinese history, compared to England
Brown J (2018). Influenza: The Hundred Year Hunt to Cure the Deadliest Disease in History. New York: Atria. ISBN 978-1501181245.
Eisenberg, Merle, and Lee Mordechai. "The Justinianic Plague and Global Pandemics: The Making of the Plague Concept." American Historical Review 125.5 (2020): 1632–1667.
Honigsbaum, Mark (18 October 2020). "How do pandemics end? In different ways, but it's never quick and never neat". The Guardian. ISSN 0261-3077. Retrieved 28 October 2020.
Larson, E (2007). "Community factors in the development of antibiotic resistance". Annual Review of Public Health. 28: 435–47. doi:10.1146/annurev.publhealth.28.021406.144020. PMID17094768.
McKenna, Maryn, "Return of the Germs: For more than a century drugs and vaccines made astounding progress against infectious diseases. Now our best defenses may be social changes", Scientific American, vol. 323, no. 3 (September 2020), pp. 50–56. "What might prevent or lessen [the] possibility [of a virus emerging and finding a favorable human host] is more prosperity more equally distributed – enough that villagers in South Asia need not trap and sell bats to supplement their incomes and that, low-wage workers in the U.S. need not go to work while ill because they have no sick leave." (p. 56.)
Quammen, David, "The Sobbing Pangolin: How a threatened animal may be linked to the [Covid-19] pandemic's beginnings", The New Yorker, 31 August 2020, pp. 26–31. "More field research is needed [...]. More sampling of wild animals. More scrutiny of genomes. More cognizance of the fact that animal infections can become human infections because humans are animals. We live in a world of viruses, and we have scarcely begun to understand this one [ COVID-19 ]. (p. 31.)