EMS Pediatric Transport Safety and Secondary Transport

Kyle Fratta; Jennifer Fishe

Introduction

Prehospital triage should match patient needs with hospital service availability. For emergency medical services (EMS), hospital destination choices are guided by patient conditions, transport times, jurisdictional resources, local hospital capabilities, and patient or family preference. Evidence-based guidelines (EBG) have been developed to aid EMS destination choices for adult patients suffering from trauma, myocardial infarction, and stroke. However, analogous guidelines do not exist for any pediatric condition other than trauma.

Regionalization of care has concentrated on pediatric specialty or critical care services, magnifying the consequences of the destination decisions of EMS and increasing rates of interfacility transport (IFT) and secondary transport. Studies have identified several specific medical conditions that frequently necessitate secondary or interfacility transport. Preventable patient harms due to secondary and interfacility transport have also been identified. To avoid such harms and better serve the definitive care needs of the estimated 1.8 million children transported by EMS annually in the United State, EBG development should be explored for pediatric conditions beyond trauma.[1][2][3][4]

Issues of Concern

Specific Conditions

The most salient literature attempts to identify the circumstances and medical conditions that justify direct transport by EMS to pediatric specialty or critical care centers. That literature identifies a wide variety of circumstances and conditions:

Apparent Life-Threatening Events

Apparent Life-Threatening Events (ALTE) with 3 significant risk factors were predictive of the need for specialty or critical care: facial and body cyanosis, more than one ALTE in 24 hours, or a history of resuscitation attempts.

Seizures or Convulsions

Seizures, particularly in younger children or infants, with three significant risk factors, were identified as significant risk factors for specialty or critical care needs: a history of developmental delay, active seizures at the time of EMS arrival, or EMS administration of midazolam.

Isolated Orthopedic Injury

Patients with isolated orthopedic injuries that necessitated secondary transport frequently had an obvious deformity on EMS’s initial assessment and were more likely to be younger. Specific anatomic injury sites that likely required secondary transport included humeral supracondylar fractures, humeral condyle fractures, or elbow dislocations. Secondary transport for isolated orthopedic injuries is dependent upon regional variation in general orthopedic capability and pediatric orthopedic availability.

Asthma or Respiratory Distress

Patients with respiratory distress with 2 significant risk factors were at increased likelihood of requiring specialty care: EMS provider administration of oxygen regardless of the patient’s oxygen saturation level and EMS administration of a combination of albuterol and ipratropium bromide nebulizer treatments, as opposed to albuterol alone. Prehospital oxygen administration in the absence of hypoxia suggests oxygen administration was administered for work of breathing rather than hypoxia. The decreased likelihood of secondary transport for patients receiving albuterol-only nebulizer treatments further suggests prehospital providers may be able to identify asthma or respiratory distress patients who do not require a higher level of care.

Children with Special Health Care Needs

Children with Special Health Care Needs are noted to have disproportionately high rates of EMS usage and IFT, suggesting higher incidences of secondary transport.

The Dangers of Secondary and Interfacility Transport

Secondary transport and IFT patients are exposed to a multitude of risks. Both forms of transport are associated with delays in definitive care and the inherent risk of motor vehicle collisions while en route to the final destination. Studies also associate IFT with other patient harms, such as suboptimal care or undertreatment of pediatric illness at local hospitals before IFT. Other studies identify increased morbidity in pediatric intensive care unit (PICU) patients who underwent IFT, including higher mechanical ventilation rates and longer length-of-stay. Part of the excess morbidity was attributed to adverse events during the actual transport. Additionally, children cared for at two emergency departments may undergo repeat laboratory and radiographic tests, increasing exposure to ionizing radiation.

Prehospital and Hospital Predictive Scoring Tools

Researchers have tested specific variables and predictive models to avert those harms and determine which pediatric patients require specialty and critical care or IFT. Surprisingly, vital signs, physiologic markers, and scoring systems derived from those data do not function as accurate or reliable predictors. For example, a meta-analysis examining capillary refill time found it was a specific but not a sensitive marker for critical illness. Scoring systems such as the Pediatric Risk of Admission Score (PRISA) and Transport Risk Assessment in Pediatrics (TRAP) had only fair predictive value for hospital or PICU admission, respectively. Furthermore, PRISA and modified transport pediatric early warning scores (TPEWS) showed poor interrater reliability between the transport team and referring hospital scores, suggesting potentially inconsistent application in the prehospital setting.

While the above-discussed quantitative criteria do not reliably predict the need for pediatric specialty or critical care, qualitative criteria have improved predictive value. The Pediatric Assessment Triangle (PAT) is an accurate "from the door" prehospital assessment tool that can predict subsequent hospital admission. The PAT was also accurately used by paramedics in the field with high interrater reliability between paramedics and hospital staff. For pneumonia patients, altered mental status and chest retractions significantly predict critical illness. Algorithms combining qualitative assessments with physiologic data accurately predict PICU admission for patients with respiratory distress. Any potential EBG for EMS destination choices must mind the practical constraints of the prehospital environment. In addition to the PAT, a triage scale combining vital signs and qualitative assessments demonstrated good interrater reliability between prehospital and emergency department personnel.

Clinical Significance

Numerous patient conditions have been identified that predispose patients to an increased risk of secondary and interfacility transport. These conditions include ALTEs, seizures, respiratory distress, isolated orthopedic injuries (particularly of the upper arm and elbow), as well as children with special health care needs. Significantly, all these conditions can be accurately assessed by prehospital providers. There are inherent risks to secondary transport and IFT relating to the transportation itself, suboptimal care or undertreatment before arriving at the site of definitive care, and a prolonged wait for definitive care. Numerous predictive models have been tested to predict which children need specialized or comprehensive care. However, the only model that is accurate and maintains interrater reliability is the Pediatric Assessment Triangle (PAT). To minimize the frequency of potentially harmful IFT or secondary transport, pediatric prehospital destination EBGs should be developed and prospectively validated, incorporating the PAT, high-risk conditions, and qualitative assessments.[5][6][7][8]

Details

References

[1]

Rinke ML, Dietrich E, Kodeck T, Westcoat K. Operation care: a pilot case management intervention for frequent emergency medical system users. The American journal of emergency medicine. 2012 Feb:30(2):352-7. doi: 10.1016/j.ajem.2010.12.012. Epub 2011 Jan 26 [PubMed PMID: 21269790]

Level 3 (low-level) evidence

[2]

Byrne JP, Mann NC, Dai M, Mason SA, Karanicolas P, Rizoli S, Nathens AB. Association Between Emergency Medical Service Response Time and Motor Vehicle Crash Mortality in the United States. JAMA surgery. 2019 Apr 1:154(4):286-293. doi: 10.1001/jamasurg.2018.5097. Epub [PubMed PMID: 30725080]

[3]

Albritton J, Maddox L, Dalto J, Ridout E, Minton S. The Effect Of A Newborn Telehealth Program On Transfers Avoided: A Multiple-Baseline Study. Health affairs (Project Hope). 2018 Dec:37(12):1990-1996. doi: 10.1377/hlthaff.2018.05133. Epub [PubMed PMID: 30633672]

[4]

Lumba R,Mally P,Espiritu M,Wachtel EV, Therapeutic hypothermia during neonatal transport at Regional Perinatal Centers: active vs. passive cooling. Journal of perinatal medicine. 2018 Dec 7; [PubMed PMID: 30530909]

[5]

Steffen KM, Noje C, Costabile PM, Henderson E, Hunt EA, Klein BL, McMillan KN. Pediatric Transport Triage: Development and Assessment of an Objective Tool to Guide Transport Planning. Pediatric emergency care. 2020 May:36(5):240-247. doi: 10.1097/PEC.0000000000001641. Epub [PubMed PMID: 30461668]

[6]

Hewes HA, Ely M, Richards R, Shah MI, Busch S, Pilkey D, Hert KD, Olson LM. Ready for Children: Assessing Pediatric Care Coordination and Psychomotor Skills Evaluation in the Prehospital Setting. Prehospital emergency care. 2019 Jul-Aug:23(4):510-518. doi: 10.1080/10903127.2018.1542472. Epub 2018 Dec 7 [PubMed PMID: 30380953]

[7]

Fidacaro GA Jr, Jones CW, Drago LA. Pediatric Transport Practices Among Prehospital Providers. Pediatric emergency care. 2020 Nov:36(11):e632-e635. doi: 10.1097/PEC.0000000000001564. Epub [PubMed PMID: 30106867]

[8]

VanGraafeiland B, Foronda C, Vanderwagen S, Allan L, Bernier M, Fishe J, Hunt EA, Jeffers JM. Improving the handover and transport of critically ill pediatric patients. Journal of clinical nursing. 2019 Jan:28(1-2):56-65. doi: 10.1111/jocn.14627. Epub 2018 Aug 14 [PubMed PMID: 30016565]