The transmission of disease through small particulates that can be transmitted through the air over time and distance is known as airborne transmission. Diseases capable of airborne transmission include many of considerable importance both in human and veterinary medicine. The relevant pathogens may be viruses, bacteria, or fungi, and they may be spread through breathing, talking, coughing, sneezing, raising of dust, spraying of liquids, flushing toilets, or any activities which generate aerosol particles or droplets. Human airborne diseases do not include conditions caused by air pollution such as volatile organic compounds, gases, and any airborne particles.
Airborne transmission is distinct from transmission by respiratory droplets. Respiratory droplets are large enough to fall to the ground rapidly after being produced, as opposed to the smaller particles that carry airborne pathogens. Also, while respiratory droplets consist mostly of water, airborne particles are relatively dry, which damages many pathogens so that their ability to transmit infection is lessened or eliminated. Thus the number of pathogens that can be transmitted through an airborne route is limited.
Both aerosols and respiratory droplets are part of the respiratory route of transmitting communicable diseases. Individuals generate aerosols and droplets across a wide range of sizes and concentrations, and the amount produced varies widely by person and activity. Larger droplets, greater than 100 ?m fall to the ground, and settle within 2 m, except when propelled. Smaller particles can carry airborne pathogens for extended periods of time. There is a greater concentration of airborne pathogens within 2m, however, they can travel farther and build up in concentration in a room.
The traditional hard size cutoff of 5 ?m between airborne and respiratory droplets has been criticized as a false dichotomy not grounded in science, as exhaled particles form a continuum of sizes whose fates depend on environmental conditions in addition to their initial sizes. However, it has informed hospital-based transmission-based precautions for decades. Recent data on indoor respiratory secretion transfer suggest that droplets in the 20 ?m size range initially travel with the airflow from cough jets and air conditioning like aerosols but fall out gravitationally at a larger distance. As this size range is most efficiently filtered out in the nasal mucosa, the primordial infection site in COVID-19, droplets in this size range may contribute to driving the COVID-19 pandemic.
Airborne diseases include any that are caused via transmission through the air. Many airborne diseases are of great medical importance. The pathogens transmitted may be any kind of microbe, and they may be spread in aerosols, dust, or liquids. The aerosols might be generated from sources of infection such as the bodily secretions of an infected animal or person, or biological wastes such as accumulate in lofts, caves, garbage, and the like. Such infected aerosols may stay suspended in air currents long enough to travel for considerable distances; sneezes, for example, can easily project infectious droplets the full length of a bus.
Airborne pathogens or allergens often cause inflammation in the nose, throat, sinuses, and lungs. This is caused by the inhalation of these pathogens that affect a person's respiratory system or even the rest of the body. Sinus congestion, coughing, and sore throats are examples of inflammation of the upper respiratory airway due to these airborne agents. Air pollution plays a significant role in airborne diseases which are linked to asthma. Pollutants are said to influence lung function by increasing airway inflammation. Many common infections can spread by airborne transmission at least in some cases, including but not limited to COVID-19; measles morbillivirus, chickenpox virus; Mycobacterium tuberculosis, influenza virus, enterovirus, norovirus, and less commonly coronavirus, adenovirus, and possibly a respiratory syncytial virus.
Transmission likely often starts with inhalation of the infectious agent and is expected to be most likely after long stays in crowded, poorly ventilated rooms. Crowded rooms are more likely to contain an infected person, with poor ventilation the infectious agent will persist in the room air, and the longer they stay, the more air a susceptible person breathes in. Airborne transmission is complex and hard to demonstrate unequivocally. Airborne diseases can also affect non-humans. For example, Newcastle disease is an avian disease that affects many types of domestic poultry worldwide which are transmitted via airborne contamination.
Airborne transmission can be classified into three categories; obligate, preferential, and opportunistic. The first category, obligate airborne infections, are only through aerosols and the most common example of this category is tuberculosis. Preferential airborne infections, such as chickenpox, can be obtained through different routes, but mainly by aerosols. The last category, opportunistic airborne infections typically transmit through other routes, however, under favorable conditions, aerosol transmission can occur. An example of an opportunistic airborne infection includes influenza. Because the drying process often damages the pathogens, the number of diseases that can be spread through an airborne route is limited.
Airborne infections usually occur by the respiratory route, with the agent present in aerosols. This includes dry particles, often the remainders of an evaporated wet particle called nuclei, and wet particles. This kind of infection usually requires independent ventilation during treatment e.g. tuberculosis. Relative humidity plays an important role in the evaporation of droplets and the distance they travel. The 30 ?m droplets evaporate in seconds. If the relative humidity goes below 35%, there are more viruses with infectious potential in the air.
Environmental factors influence the efficacy of airborne disease transmission; the most evident environmental conditions are temperature and relative humidity. The sum of all the factors that influence temperature and humidity, either outdoor or indoor, as well as other circumstances influencing the spread of droplets containing infectious particles, as winds, or human behavior, influence the transmission of airborne diseases. Rainfall, the number of rainy days being more important than total precipitation; mean daily sunshine hours; latitude and altitude are relevant when assessing the possibility of spread of any airborne infection. Some infrequent or exceptional events influence the dissemination of airborne diseases, including tropical storms, hurricanes, typhoons, or monsoons.
Climate determines temperature, winds, and relative humidity, the main factors affecting the spread, duration, and infectiousness of droplets containing infectious particles. The influenza virus is spread easily in the Northern Hemisphere winter due to climate conditions that favor the infectiousness of the virus. Socioeconomics has a minor role in airborne disease transmission. In cities, the spread of airborne disease is more rapid than in rural areas and urban outskirts. Rural areas generally favor higher airborne fungal dissemination. Proximity to large bodies of water such as rivers and lakes can be a cause of some outbreaks of airborne disease.
Poor maintenance of air conditioning systems has led to outbreaks of Legionella pneumophila. Hospital-acquired airborne diseases are associated with poorly-resourced medical systems, which make isolation challenging. Some ways to prevent airborne diseases include disease-specific immunization, wearing a respirator, and limiting time spent in the presence of any patient likely to be a source of infection. Wearing a face mask can also lower the risk of transmission, as it slows down the airflow between individuals.
Exposure to a patient or animal with an airborne disease does not guarantee to contract the disease, as the infection is dependent on host immune system competency plus the number of infectious particles ingested. Antibiotics may be used in dealing with air-borne bacterial primary infections, such as pneumonic plague. Many public health specialists recommend physical distancing to reduce the transmission of airborne infections.
The writer is a columnist.
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