Electrical and Lightning Injuries

Current and Voltage

Joule’s law , which describes the amount of thermal energy applied to tissues from electricity, is described by the formula

where P is thermal energy, I the current, R the resistance, and T is the duration (time) that the electricity is applied. Current is the flow of electrons down an electrical gradient and is measured in units of amperage. Current is the most important factor in determining the degree of energy transmitted, but it is rarely known in a given exposure. Instead, voltage is used as a proxy for current. According to Ohm’s law , current (I) is directly proportional to the voltage (V) of the source and inversely proportional to the resistance (R) of the material through which it flows (I = V/R).

Injuries are conventionally classified as being caused by high- or low-voltage sources, with 1000 V as the dividing line. In North America, household sources are low voltage, typically 120 or 240 V. High-voltage injuries, such as those caused by electrical power lines or occupational accidents, are characterized by partial to full-thickness skin burns, deep tissue destruction, and potential cardiac or respiratory arrest. High-voltage injuries are associated with higher rates of death, and more associated traumatic injuries, such as extremity fractures, blunt head injuries, and spinal cord injuries. ^, Low-voltage exposure causes less surface damage, but may be equally lethal, particularly in cases in which skin resistance is low, such as when immersed or exposed to water.

Current Type

Electrical sources create current that flows in one direction ( direct current, DC ) or alternates direction cyclically at varying frequencies ( alternating current, AC ). The few systems in the United States that use DC include batteries, automobile electronics, and railroad tracks. Exposure to DC most frequently causes a single, strong, muscular contraction. This may throw the victim back from the source in a way that limits duration of exposure but can result in other traumatic injuries. AC is more commonly used (e.g., household currents) because it conveniently allows for an increase or decrease of power at transformers. It is more dangerous than DC of similar voltage because amperage above the so-called “let-go” current will cause muscular tetanic contractions. Because the flexor muscles of the upper extremities are stronger than extensor muscles, these contractions pull the victim closer to the source resulting in prolonged exposure. Box 130.1 shows the physical effects of different amperage levels at a common 60-Hz AC exposure.

Capacitors store electric charge in circuits, and discharge from these devices may result in sudden bursts of very large amounts of electrical energy. Injury from a capacitor may occur even when the electrical device is not energized or plugged in into an electrical source.

Resistance of Tissue Affected

Resistance is the degree to which a substance resists the flow of current; when resistance goes down, current increases. Resistance varies among body tissues. Neurovascular tissues are good conductors of electricity, whereas skin, tendons, fat, and bone are relatively poor conductors ( Box 130.2 ). Current that is initially unable to pass through skin will create thermal energy and cause significant burns. As the skin blisters and deteriorates, its resistance decreases. Once current is through the skin, it can pass easily along lower resistance structures, causing deep tissue injury which may not be immediately evident. As a result, the degree of burns seen on the surface of the skin typically underestimates the damage occurring below the surface. As current strength increases, the relative resistance of tissues ceases to determine the pathway of current, and the entire body functions as a conductor. Current may also jump across skin surfaces in a behavior termed arcing , resulting in prominent burns across flexor surfaces.

Within a given tissue, resistance differs based on the fluid and electrolyte content of cells. Dry skin offers the largest resistance, up to 100,000 ohm (Ω) in thick, calloused skin, but dermal resistance decreases to as little as 1000 Ω when wet. This explains why electrical injuries are generally worse in the setting of water.

Path Taken by Current Through the Body

The pathway followed by electrical current determines morbidity and mortality. The entrance and exit sites of the electrical current typically demonstrate greater evidence of skin damage, with full-thickness burns commonly encountered. These sites are properly referred to as the source and ground contact points . A patient may have one or multiple source and ground contact points. The most common points of source contact are the hands, wrists, and arms, but children also present with burns from oral contact with electric cords or sockets. The most common ground contact points are the heels of the feet.

Electrical current passing through a limb causes greater local tissue damage than current passing through the trunk because the smaller cross-sectional area limits the ability to dissipate heat. However, current passing through the trunk results in greater mortality due to the involvement of more vital cardiothoracic organs. Transthoracic pathways (arm to arm) are more likely to generate dysrhythmias and have higher mortality rates than vertical currents (leg to arm) or straddle pathways (leg to leg).

Duration of Contact

The degree of tissue damage is directly proportional to the duration of exposure for all voltage levels. Exposure times greater than the length of one cardiac cycle tend to generate dysrhythmias, likely in a manner analogous to the R-on-T phenomenon.