To aid in the evaluation and treatment of shock, it is often useful for the physician and EMS personnel to categorize the etiology of the shock condition [4]. Most EMS providers are familiar with the “pump-fluid-pipes” model of the cardiovascular system, with the pump representing the heart, pipes representing the vascular system, and fluid representing the blood [5]. Thus, categorizing shock into four categories may help prehospital providers and EMS physicians organize their assessments and approaches (Table 7.1). Accurate physical assessment is vital for the EMS provider to determine the etiology of the shock state (Box 7.1).

Emergency medical services providers should look for the signs and symptoms of system-wide reduction in tissue perfusion, such as tachycardia, tachypnea, mental status changes, and cool, clammy skin (see Box 7.1). When available, adjunctive technologies can provide improved recognition and assessment of shock by demonstrating reductions in expired CO₂, hypovolemia, obstruction, or poor contractility on ultrasound, and elevated serum lactate levels.

Vital signs that fall outside of expected ranges must be correlated with the overall clinical presentation. Vital signs have a broad range of normal values and must be interpreted in the context of the individual patient. A petite 45 kg, 16-year-old female with lower abdominal pain with a reported blood pressure of 88 mmHg systolic by palpation may have a ruptured ectopic pregnancy, or may just be at her baseline blood pressure. An elderly patient with significant epistaxis may be hypertensive due to catecholamine release and vasoconstriction despite being relatively volume depleted. Consideration should be given to patient age, comorbid conditions, and medications that may affect the interpretation of vital signs.

In the noisy field environment, providers often measure blood pressure by palpation rather than auscultation. Blood pressure by palpation provides only an estimate of systolic pressure [7]. Without an auscultated diastolic pressure, the pulse pressure (difference between systolic and diastolic pressure) cannot be calculated. A pulse pressure less than 30 mmHg or 25% of the SBP may provide an early clue to the presence of hypovolemic or obstructive shock. Conversely, a wide pulse pressure may be indicative of distributive shock [3]. Dividing the pulse rate by the systolic pressure typically produces a ratio of approximately 0.5 to 0.8, which is called the “shock index.” When that ratio exceeds 1.0, then a shock state may be present [8].

Previously healthy victims of acute hypovolemic shock may maintain relatively normal vital signs with up to 25% blood volume loss [3]. Sympathetic nervous system stimulation with vasoconstriction and increased cardiac contractility may result in a normal blood pressure in the face of decreasing intravascular volume, especially in the pediatric population. In some patients with intraabdominal bleeding (e.g. ruptured abdominal aneurysm, ectopic pregnancy), the pulse may be relatively bradycardic despite significant blood loss [9].

Emergency medical services personnel may equate “normal” vital signs with normal cardiovascular status [5]. The field team may be lulled into a false sense of security initially if the early signs of shock are overlooked, only to be caught off guard when the patient’s condition dramatically worsens during transport. Following trends in the vital signs may also help identify shock before patients reach abnormal vital sign triggers. Early recognition and aggressive treatment of shock may prevent progression to the later stages of shock that can result in the death of potentially salvageable patients [10].

Prehospital hypotension may predict in-hospital morbidity and mortality in both trauma and medical patients [11–13]. Jones et al. noted a 30% higher mortality rate for medical patients with prehospital hypotension [11]. Other studies have shown similar findings in trauma patients with prehospital hypotension, even with subsequent normotension in the emergency department [12,13]. Therefore, hospital providers should consider any episode of prehospital hypotension as evidence of significant shock and the presence of a critical illness.

Despite their questionable value, orthostatic vital signs are often evaluated in the emergency department, and occasionally in the field. A positive orthostatic vital sign test for pulse rate would result in a pulse increase of 30 beats per minute after 1 minute of standing [14]. Symptoms of lightheadedness or dizziness are considered a positive test. Occasionally, orthostatic vital signs are performed serendipitously by the patient who refuses treatment while lying down, then stands up to leave the scene, and suffers a syncopal episode. This demonstration of orthostatic hypotension is often helpful in convincing the patient to allow treatment and transport. However, rescuers should not equate absence of orthostatic response with euvolemia.

Capillary refill, an easy test to perform in the field setting, is not a useful test for mild-to-moderate hypovolemia [15]. Moreover, environmental considerations, such as cold temperatures and adverse lighting conditions, also affect the accuracy of this technique for shock assessment. On-scene estimates of blood loss by EMS providers may influence therapeutic interventions, including fluid administration. However, studies suggest that providers are not accurate at estimating spilled blood volumes [16].

Hypoxia is a common manifestation of shock states. Patients in various stages of exsanguination may not have sufficient blood volume to adequately perfuse the body with oxygen. Unfortunately, pulse oximetry alone cannot detect the adequacy of oxygen delivery. Pulse oximetry may fail to detect a pulse when blood flow is reduced [17,18]. Like pulse oximetry, capnography may also serve as an important tool in the evaluation and treatment of shock in the prehospital setting [19–22]. Capnography is the measurement of the exhalation of carbon dioxide from the lungs. Exhaled end-tidal carbon dioxide (EtCO₂) levels vary inversely with minute ventilation, providing feedback regarding the effect of changes in ventilatory parameters [23,24]. Additionally, changes in EtCO₂ are virtually immediate when the airway is obstructed or the endotracheal tube becomes dislodged [25]. EtCO₂ concentration may be influenced by factors other than ventilation. For example, EtCO₂ levels are reduced when pulmonary perfusion decreases in shock, cardiac arrest, and pulmonary embolism [26–28]. EtCO₂ is most useful as an indicator of perfusion when minute ventilation is held constant (e.g. when mechanical ventilation is applied) [20,26]. Under these conditions, changes in EtCO₂ levels reliably indicate changes in pulmonary perfusion. In any patient suffering from a potential shock state, diminished EtCO₂ should be a warning of the critical nature of the patient’s problem.

General approach to shock

All treatment approaches to shock must include the following basic principles.

1. Perform the initial assessment.
   
2. Deal with issues identified in the initial assessment such as airway, breathing, and circulation issues, including active external bleeding.
   
3. Determine need for early definitive care.
   
   
   
   • Hemorrhage control and volume resuscitation
     
   • Needle thoracostomy
     
   • Electrical therapy for dysrhythmia
     
   • Invasive airway management
   
   
4. Maintain adequate oxygen saturation (SaO₂ > 94%).
   
5. Ensure adequate ventilation without hyperventilating.
   
6. Monitor vital signs, ECG, oxygen saturation, capnography, and lactate (if available).
   
7. Prevent additional injury or exacerbation of existing medical conditions.
   
8. Protect the patient from the environment.
   
9. Determine the etiology of the shock state, and treat accordingly.
   
10. Notify and transport to an appropriate facility.

Often the etiology of the patient’s shock state and the initial management options are clear from the history. For example, the out-of-hospital treatment of a young, previously healthy college student with hypotension secondary to severe vomiting and diarrhea includes IV fluids. The treatment of cardiogenic shock in an unresponsive elderly patient with ventricular tachycardia (VT) requires prompt cardioversion. Occasionally, the primary problem may be strongly suspected but not readily diagnosable or treatable in the field (e.g. pulmonary embolism). Less frequent, but most difficult to manage, is the patient in shock without an obvious cause. With the understanding of the limited treatment options in the out-of-hospital setting (primarily fluids, inotropic agents, and vasopressors), field treatment may be individualized for the four categories of shock: hypovolemic, distributive, obstructive, and cardiogenic.

Hypovolemic shock

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