Identification and Understanding of Illness or Injury

In an emergency, appropriate triage from the ranch environment will enhance survival and minimize morbidity and mortality of the acutely injured patient. Patient outcome is directly related to time from injury to properly delivered definitive care.⁷ Early recognition of multisystem, life- and/or limb-threatening injuries is necessary before directing the EMS transport system to a particular hospital.

Local Medical Care and Regional Tertiary Care Centers

Understanding the capabilities of nearby hospitals is an essential element in making the right triage decision.⁷ It is often the case that patients with relatively more complex injuries and illnesses cannot receive definitive medical or surgical care in the rural setting. In many regions, online medical direction and/or standing orders will be available to assist in determining how and where to transport a patient from the ranch setting to the most appropriate medical care facility. Nonetheless, if a patient is unstable, transport to the nearest hospital regardless of specialty care availability might be necessary in order to stabilize the patient before transport to a facility with higher levels of expertise and specialty care.

EMS Activation

Activation of EMS for local and/or long-distance transportation should be accomplished as soon as possible. In some situations, it will benefit the patient to have advanced-level paramedics and nurses brought by aircraft to the scene so that stabilization can be achieved earlier than otherwise, providing also for safer transport to a tertiary medical center for definitive care.

In communicating with an online medical control service, the rescuer should provide a concise description of the patient, current set of vital signs, mechanism of injury or medical condition, neurologic findings, and the nearest location where EMS personnel can safely pick up the patient. If time permits, the secondary survey can be communicated to the online medical control officer, but this should not delay initiation of EMS dispatch. Patients with respiratory or hemodynamic instability, decreased level of consciousness, and/or open wounds of the head, neck, chest, or abdomen may require advanced-level treatment in the field or initial evaluation and stabilization at a local emergency department before long-distance travel.¹¹³

Confined Spaces

Manure pits and silos are dangerous, gas-containing, confined spaces that can generate hazardous levels of hydrogen sulfide and nitrogen dioxide, respectively.¹²² Methane and carbon dioxide concentrations can also reach toxic levels in manure storage facilities. Simple asphyxiants, such as carbon dioxide and nitrogen, when present in high enough concentrations produce toxicity by lowering the fraction of inspired oxygen (FIO₂), placing the exposed individual at risk for hypoxia. Pulmonary irritants represent a large group of noxious agents and produce severe irritation of respiratory tract mucous membranes.⁹⁵ Clinical presentation of the patient from a confined-space accident often depends upon the type of asphyxiant and severity of exposure.

Simple Asphyxiants (Manure Pits, Grain Bins)

All mammalian life requires oxygen. Normal air is approximately 21% oxygen, 78% nitrogen, and 0.03% carbon dioxide. The human response to lower levels of oxygen includes increased breathing and pulse rate, mild muscular incoordination (12% to 16% oxygen); emotional upset, abnormal fatigue upon exertion, disturbed respiration (10% to 14%); nausea and vomiting, inability to move freely, loss of consciousness, collapse and inability to move or cry out (6% to 10%); seizures, and severe respiratory distress leading to full cardiopulmonary arrest (below 6%).¹⁰¹

Fatalities occur due to asphyxiation or poisoning associated with confined-space manure storage facilities. Manure pits and other confined-space storage structures are characterized by limited openings and ventilation, allowing for buildup of poisonous gases and placing workers at risk for asphyxiation. In one case series of 91 fatalities and 21 severe injuries resulting from livestock manure–related incidents, with over 50% at dairy operations, 21% involved persons under the age of 16 years, with more than one-half occurring to persons conducting repair/maintenance activities on manure-handling equipment or attempting to rescue another person.¹⁵

Silos

A silo is a storage structure that holds harvested crops with a moisture content of 50% to 65% for the purpose of fermentation and future use as feed (Figure 104-3, online). Usually the entire plant has been harvested and chopped into segments a few to several inches long before being placed in the storage structure to ferment. The two basic types of silos are upright and trench. Upright, or tower, silos are cylindric structures 20 to 30 feet in diameter and up to 80 feet tall. Forage is unloaded and blown into the silo by specialized equipment. The silage is later unloaded from the silo with another machine that removes the top layer from the silo and blows it down into a wagon or conveyor for delivery to livestock (Figure 104-4, online).

FIGURE 104-3 Grain silos.

(Courtesy Mark Brandenburg, MD.)

FIGURE 104-4 Silo involved in a fatal explosion incident.

(Courtesy Centers for Disease Control and Prevention.)

Oxygen-limiting, or airtight/sealed, silos are intended to provide an oxygen-deficient environment to enhance fermentation and allow convenient unloading of silage as it sloughs from the bottom of the feed column and then is removed by conveyor. There is little need for the farmer to enter an oxygen-limiting silo, except for maintenance and repair; nonetheless, oxygen-limiting silos have been responsible for the asphyxiation deaths of many farmers as well as responding medical/fire rescue personnel.

Oxygen-limiting silos can explode during a fire, especially upon initiation of firefighting activities. This is due to sudden entry of outside ambient oxygen into a carbon monoxide–rich environment, which creates a high-density, flammable, and gaseous fuel. No person other than members of expert fire and EMS rescue crews should be anywhere near a silo fire. A variety of silo types and emergency situations require specialized training by rescue personnel.

Pulmonary Irritants (Manure Pits, Silos, Grain Bins)

A broad array of irritant gases, such as nitrogen dioxide (silos) and hydrogen sulfide (manure pits), is produced on farms and ranches. The clinical presentation of pulmonary irritant toxicity depends in part on the water solubility of the agent, which reacts with water to form a highly caustic acid (usually nitric or sulfuric acid). The more water soluble the agent, the quicker and more proximally in the body it will react with respiratory tract mucus and lacrimal moisture to incite symptoms of irritation (e.g., eyes, nasal mucosal, oral mucosal, pharyngeal, and upper respiratory tract) in the patient.

When the acid-producing reaction occurs in the upper respiratory tract, there will generally be less alveolar injury but still possibly life-threatening laryngeal edema, or laryngeal spasm and bronchospasm. Agents with less water solubility travel a greater distance into the pulmonary tree before reacting with mucosal water molecules, resulting in delayed (2 to 24 hours) symptoms, and causing greater and more irreversible damage to the alveoli and lung parenchyma. In addition, victims may remain in the toxic environment with ongoing exposure to water-insoluble irritant gases for a longer duration (Figure 104-5).

FIGURE 104-5 In-ground manure pit.

(Courtesy National Pork Board.)

Manure Pits

Manure pits can produce hydrogen sulfide, a colorless, poisonous gas. In low concentrations, the smell of sulfur (similar to rotten eggs) is sometimes noted; in higher concentrations, hydrogen sulfide overwhelms the olfactory nerve such that the victim cannot smell the gas, and the gas can quickly kill nearby animals and humans. Detection of any animals dead, dying, or struggling in or around a manure pit should prompt all individuals to immediately evacuate the area.

Silo Filler’s Disease

Silo filler’s disease results from acute pulmonary exposure to nitrogen dioxide, a reddish-brown gas with an odor similar to that of household bleach. This toxic gas is produced by fermentation within hours of filling a farm silo with fresh, organic material, such as corn, grains, oats, alfalfa, and hay. Nitrogen dioxide is heavier than air and may concentrate along the top of the silage or the floor of the silo entrance. Silage is a high-moisture product usually made from grass crops, sorghum, or corn by using the entire green plant in the fermentation process via silo storage. Silage is then used to feed cattle or sheep. After a silo is stocked with silage (usually in September and October), nitrogen dioxide is released into the air, with maximum concentrations being reached in 1 to 2 days.

Grain Storage Bin Entrapment

Entrapment in bins containing loose agricultural material, usually corn or other grains, is a well-known cause of serious injury and fatality. More than 200 people have been killed and another 300 injured in the past 30 years because of grain suffocation. High-capacity augers are usually implicated in these accidents (Figure 104-6). Severe entrapment injuries and fatalities can occur when suspended materials or crusted surfaces of stored material suddenly break loose and collapse beneath the worker.⁹⁶ Crusting at the surface of stored grain is called bridging and is more likely to occur when moist grain is stored, typically in rainy harvest seasons. Moisture collects at the surface of the stacked grain and later dries, forming a crusty surface upon which workers are tempted to walk. Bridged grain is extremely hazardous because it prevents grain flow and hides underlying pockets of air, which allow the surface to collapse (Figure 104-7).

FIGURE 104-6 Auger inside a grain silo.

(Courtesy Mark Brandenburg, MD.)

FIGURE 104-7 Diagram: Sketch of silo involved in suffocation incident.

(Courtesy Centers for Disease Control and Prevention.)

Farm workers may also be buried by stored grain when it is emptied from the bottom of the bin. Flowing grain can very quickly pull an adult completely down and into the bin. Once an individual’s knees are covered by flowing grain, it is extremely difficult to get free without assistance.¹⁹

In a retrospective study, 16% of grain bin entrapment fatalities were children less than 16 years old, and 77% of fatalities involved the activity of unloading the bin at the time of injury.⁷² Children should never be allowed in or around a grain bin, even when operation has ceased. Entrance to the grain bin should always be locked securely to prevent children from entering. Injury prevention is key (Box 104-2).

Farmer’s Lung

Farmer’s lung is a hypersensitivity pneumonitis involving the terminal airways, triggered by exposure to organic dust. Thermophilic Actinomycetes and Aspergillus are the more common antigens responsible for this pulmonary reaction, also known as extrinsic allergic alveolitis.¹⁴⁵ Exposure to antigenic organisms in other agricultural occupations can also be responsible for farmer’s lung.

Contaminated hay, straw, and grain are the most common sources of antigen inhalation. When these crops are stored in moist environments, molds proliferate, allowing for easy aerosolization when the material is disturbed. The fine dust is easily inhaled into the lower respiratory system, where immune complexes damage distal bronchioles and alveoli. Dairy farmers and other cattle ranchers who handle large amounts of hay are at greatest risk in the winter months, when they are more likely to be around stored hay.

Toxic Organic Dust Syndrome

TODS, also known as toxic alveolitis or pulmonary mycotoxicosis, is a common respiratory affliction in farmers, with an estimated incidence of 6% to 8%.¹⁰ Inhalation of organic dust laden with microorganisms, such as fungal spores, molds, bacteria, and endotoxins, and subsequent inflammation are believed to be the pathogenesis of this disease.¹⁴¹ Pig farmers, particularly those who use wood shavings as bedding in hog barns, are at particular risk.¹⁴⁰

All-Terrain Vehicles

All-terrain vehicles (ATVs) have become very popular in the United States over the past 30 years. These vehicles are marketed and advertised for off-road travel and used for recreation, competition racing, and as work tools on the ranch. The size, power, and ruggedness of these vehicles make them undeniably useful, but riding ATVs is a high-risk activity and deserves special attention to safety.^23,25 One study showed that 35% of ATV crashes occur on farms and ranches.²⁵ The impact force of these vehicles when they roll over leads to severe head, facial, and torso crush injuries, in addition to orthopedic injuries.

During the 1980s, researchers found ATVs to be quite dangerous to operators. In 1988, the U.S. Consumer Product Safety Commission and the ATV industry agreed to cease manufacturing three-wheeled ATVs, but not four-wheeled ATVs, in a consent decree negotiated in federal district court.^137,133 Since that time, only four-wheeled ATVs have been manufactured and sold to consumers; however, a small number of three-wheeled ATVs are still in operation. In the years during this consent decree, U.S. consumers continued to be at great risk for injury while riding ATVs.^63,77,80

In 1998, the consent decree expired, and ATV manufacturers began increasing the speed, power, and size of ATVs. In 1998, there were approximately 4 million ATVs in use in the United States,¹³⁴ and in 2003 there were approximately 7 million.¹¹⁹ Since 2003, the ATV industry has increased production of large-engine ATVs threefold; some ATVs can attain speeds of up to 55 mph and weigh 800 lb. Advertising for these vehicles increased markedly after 1997; concurrently, the Consumer Product Safety Commission reported a significant increase in ATV-related injuries.^119,136 The number of injuries and deaths caused by ATV incidents approximately doubled from 1997 to 2001 to over 500 deaths and 110,000 injuries, with children under the age of 16 years being disproportionately injured and killed.¹³⁶ During the last two decades, approximately 6500 persons have been killed in ATV incidents.⁶⁸

It is widely accepted among experts that children are in extreme danger when riding ATVs.* Although children less than 16 years of age represent only 14% of all ATV riders, they continue to account for up to 47% of ATV-related injuries.¹³⁵ The most common types of ATV-related injuries are soft tissue injuries, extremity fractures, and head injuries,²⁸ with 38% of children requiring surgery for their injuries in one study,⁷⁷ and 69% of children requiring either an orthopedic procedure (40%) or a general surgical procedure (29%).²⁸ Approximately 50% of ATV-injured patients suffer head injuries.³ In children, approximately 25% to 35% of ATV-related injuries involve brain injury and/or spinal cord injury.^42,81 In one study, during an 11-year period, 45% of ATV-related fatalities due to central nervous system injuries were in children under 16 years of age.²³ In response to these disturbing statistics, professional pediatric and orthopedic organizations have been urging parents not to let children operate four-wheeled ATVs.^2,4,5,6

Risk factors associated with ATV morbidity and mortality include lack of ATV safety training, inadequate driver experience, young age, vehicle characteristics, and lack of protective head gear.^64,110,111 The risk for ATV-related injury is greatest among children less than 16 years of age, males, riders of three-wheeled ATVs, and inexperienced riders; in addition, the risk for injury increases substantially as the ATV engine size increases (especially for three-wheeled ATVs).¹¹¹

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