35.3 Fighting Infectious Disease Lesson Overview 35.3 Fighting Infectious Disease

THINK ABOUT IT More than 200 years ago, English physician Edward Jenner noted that milkmaids who contracted a mild disease called cowpox didn’t develop smallpox. At the time, smallpox was a widespread disease that killed many people. Could people be protected from smallpox by deliberately infecting them with cowpox?

Acquired Immunity How do vaccines and externally produced antibodies fight disease?

Acquired Immunity How do vaccines and externally produced antibodies fight disease? A vaccine stimulates the immune system with an antigen. The immune system produces memory B cells and memory T cells that quicken and strengthen the body’s response to repeated infection. Antibodies produced against a pathogen by other individuals or animals can be used to produce temporary immunity.

Acquired Immunity Dr. Edward Jenner performed an experiment in which he put fluid from a cowpox patient’s sore into a small cut he made on the arm of a young boy named James Phipps. As expected, James developed mild cowpox. Two months later, Jenner injected James with fluid from a smallpox infection. The boy didn’t develop smallpox. The boy’s cowpox infection had protected him from smallpox infection.

Acquired Immunity The injection of a weakened form of a pathogen, or of a similar but less dangerous pathogen, to produce immunity is known as a vaccination. The term comes from the Latin word vacca, meaning “cow,” as a reminder of Jenner’s work.

Active Immunity Active immunity may develop as a result of natural exposure to an antigen (fighting an infection) or from deliberate exposure to the antigen (through a vaccine). Vaccination stimulates the immune system with an antigen. The immune system produces memory B cells and memory T cells that quicken and strengthen the body’s response to repeated infection.

Passive Immunity Antibodies produced against a pathogen by other individuals or animals can be used to produce temporary immunity. If externally produced antibodies are introduced into a person’s blood, the result is passive immunity. Passive immunity lasts only a short time because the immune system eventually destroys the foreign antibodies.

Passive Immunity Passive immunity can occur naturally or by deliberate exposure. Natural passive immunity occurs when antibodies are passed from a pregnant woman to her fetus (across the placenta), or to an infant through breast milk. For some diseases, antibodies from humans or animals can be injected into an individual. For example, people who have been bitten by rabid animals are injected with antibodies for the rabies virus.

Public Health and Medications How do public health measures and medications fight disease?

Public Health and Medications How do public health measures and medications fight disease? Public health measures help prevent disease by monitoring and regulating food and water supplies, promoting vaccination, and promoting ways that avoid infection. Antibiotics can kill bacteria, and some antiviral medications can slow down viral activity.

Public Health and Medications In 1900, more than 30 percent of deaths in the United States were caused by infectious disease. In 2005, less than 5 percent of deaths were caused by infectious disease. Two factors that contributed to this change are public health measures and the development of medications.

Public Health Measures In 1854, Dr. John Snow learned, through interviewing residents and mapping, that the source of a London cholera outbreak was a water pump. This is a major event in the history of public health. The field of public health offers services and advice that help provide healthy conditions.

Public Health Measures Promoting childhood vaccinations and providing clean drinking water are two important public health measures that have greatly reduced the spread of infectious disease.

Medications Medications, such as antibiotics and antiviral drugs, are other weapons that can fight pathogens. An antibiotic is a compound that kills bacteria without harming its host. In 1928, Alexander Fleming noticed that a mold, Penicillium notatum, seemed to produce something that inhibited bacterial growth. Research determined that this “something” was a compound Fleming named penicillin. Researchers learned to mass-produce penicillin just in time for it to save thousands of World War II soldiers.

Medications Antibiotics have no effect on viruses. However, antiviral drugs have been developed to fight certain viral infections. These drugs generally inhibit the ability of viruses to invade cells or to multiply once inside cells. http://youtu.be/txyValP55no Antibiotics video

New and Re-Emerging Diseases Why have patterns of infectious diseases changed?

New and Re-Emerging Diseases Why have patterns of infectious diseases changed? Two major reasons for the emergence of new diseases are the ongoing merging of human and animal habitats and the increase in the exotic animal trade. Misuse of medications has led to the re-emergence of diseases that many people thought were under control.

New and Re-Emerging Diseases By 1980, many people thought that medicine had conquered infectious disease. Vaccination and other public health measures had wiped out polio in the United States and had eliminated smallpox globally. Antibiotics seemed to have bacterial diseases under control. Some exotic diseases remained in the tropics, but researchers were confident that epidemics would soon be history.

New and Re-Emerging Diseases In recent decades, a host of new diseases have appeared, including AIDS, SARS, hantavirus, monkeypox, West Nile virus, Ebola, and avian influenza (“bird flu”). Other diseases that people thought were under control are re-emerging as a threat and spreading to new areas.

Changing Interactions With Animals Pathogens are also evolving in ways that enable them to infect different hosts. As people clear new areas of land and as environments change, people come in contact with different pathogens.

Changing Interactions With Animals Exotic animal trade, for pets and food, has also given pathogens new opportunities to jump from animals to humans. In 2003, dormice from Ghana spread monkeypox to prairie dogs in the United States, which then infected humans. The spread of SARS also has been associated with the wild animal trade.

Misuse of Medications Misuse of medications has led to the re-emergence of diseases that many people thought were under control. For example, many strains of the pathogens that cause tuberculosis and malaria are evolving resistance to a wide variety of antibiotics and other medications. In addition, diseases such as measles are making a comeback because some people fail to follow vaccination recommendations.