Fact-checked by Grok 2 weeks ago

Pediatric advanced life support

![Performing chest compressions on an infant]float-right Pediatric Advanced Life Support () constitutes a standardized training curriculum and protocol suite promulgated by the for healthcare practitioners managing critically ill or injured and children up to 18 years of age, targeting conditions such as , profound , severe arrhythmias, , and . Originating in 1988 through collaboration with the , it extends principles with sophisticated techniques including pharmacologic interventions, advanced airway support, and to mitigate the high mortality associated with pediatric cardiopulmonary collapse, where etiologies often stem from rather than primary cardiac events. Central to PALS is a structured evaluative —encompassing airway patency, breathing adequacy, circulatory stability, neurologic status, and full exposure—coupled with algorithms for rhythm-specific therapies and high-quality calibrated to pediatric anatomy and physiology. The framework's iterative refinements, as embodied in the 2025 guidelines, incorporate empirical advancements in epinephrine dosing, strategies, and post-arrest care to enhance cerebral and myocardial amid persistently suboptimal outcomes, with out-of-hospital pediatric yielding roughly 11 percent discharge rates.

History

Origins and Early Development

The recognition of distinct physiological and etiological differences in pediatric cardiac arrests—predominantly respiratory-driven rather than primary cardiac events as in adults—prompted the () to address gaps in existing adult-oriented protocols during the early . In , the convened its first national conference on pediatric , aimed at formulating specific guidelines for () and emergency cardiovascular care (ECC) tailored to infants, children, and neonates. This initiative stemmed from empirical observations that unmodified adult techniques yielded suboptimal outcomes in younger patients, necessitating age-adjusted algorithms for , compressions, and pharmacological interventions. Building on this foundation, the formalized Pediatric Advanced Life Support () as a structured training program and guideline set, with the inaugural PALS manual published in 1988 and initial courses launched that same year. The program integrated advanced elements such as vascular access, , and synchronized , adapted for pediatric and , while emphasizing team coordination in hospital settings. Early PALS protocols prioritized rapid identification of , arrhythmias, and , drawing from conference-derived evidence that timely escalation beyond improved survival rates in controlled studies. Subsequent refinements in the late and early focused on standardizing instructor and simulation-based learning to enhance provider competency, reflecting initial feedback that inconsistent application hindered efficacy. By 1994, recommendations further refined reporting standards for pediatric outcomes, underscoring the program's evolution toward evidence-based metrics amid growing adoption in departments. These developments established PALS as a cornerstone of pediatric care, distinct from contemporaneous adult frameworks.

Evolution and Major Guideline Updates

The Pediatric Advanced Life Support () framework originated in the mid-1980s as a response to the recognition that pediatric cardiac arrests differ fundamentally from adult cases, with and accounting for the majority of events rather than primary cardiac arrhythmias. In 1983, the (AHA) identified the need for child-specific resuscitation training, leading to the development of dedicated pediatric protocols. The first PALS course was launched in through AHA collaboration with the , establishing standardized algorithms for managing , , , and in infants and children, including emphasis on , vascular access, and age-appropriate dosing of epinephrine and other agents. Early iterations focused on adapting adult principles to pediatric physiology, prioritizing rapid identification of reversible causes like and . Major revisions began shortly after inception, with significant updates in 1994 incorporating evidence-based refinements to thresholds and antiarrhythmic use, such as amiodarone for pulseless . By the early 2000s, guidelines integrated and communication, reflecting data from studies showing improved outcomes with structured . The AHA's update cycle, typically every five years and informed by systematic reviews through the International Liaison Committee on Resuscitation (ILCOR), ensured evolution based on accumulating data, registries like the AHA's Get With The Guidelines-Resuscitation, and pediatric-specific registries. The 2010 guidelines shifted emphasis toward high-quality chest compressions with a depth of at least one-third the anteroposterior chest diameter and rates of 100-120 per minute, supported by manikin and demonstrating better coronary . Ventilation rates were adjusted to avoid and , which can exacerbate brain injury, based on evidence from neonatal and pediatric arrest models. In 2015, post-cardiac arrest care gained prominence, including and protocols derived from randomized trials showing reduced morbidity. The 2020 updates reaffirmed core CPR elements—adequate compression depth, recoil allowing, and minimal interruptions—while introducing opioid-associated arrest algorithms and interim adaptations prioritizing and limiting rescuers. Epinephrine dosing intervals were scrutinized, with supporting early in non-shockable rhythms to improve short-term rates from approximately 10-20% in out-of-hospital settings. Breath during advanced airway use was increased from 10 per minute to align with asynchronous techniques, aiming to reduce intrathoracic pressure interference with circulation. The 2025 AHA guidelines, released on October 21, 2025, maintain focus on early recognition in children up to age 18 and prompt activation, incorporating expanded data on CPR for refractory cases and refined shock management with fluid boluses of 10-20 mL/kg guided by to prevent overload. These updates draw from over 300 new studies reviewed since 2020, prioritizing causal links between interventions and neurologically intact survival, reported at 5-15% for in-hospital pediatric arrests depending on initial rhythm.

Definition and Principles

Core Objectives and Systematic Approach

The core objectives of Pediatric Advanced Life Support (PALS) center on rapidly recognizing and stabilizing children with , circulatory compromise, or to avert irreversible organ damage and improve survival rates. These objectives prioritize early intervention in , hypoperfusion, and arrhythmias, which are the predominant causes of pediatric , unlike the primary coronary events in adults. According to the (AHA) guidelines, PALS aims to enhance outcomes by integrating high-quality (CPR), , vascular access, and pharmacologic support, with evidence showing that structured protocols reduce mortality by up to 20-30% in hospitalized pediatric patients experiencing deterioration. The systematic approach in PALS follows a structured to evaluate and manage critically ill children, beginning with an initial rapid of airway (A), (B), and circulation (C) to identify severe compromise. If compromise is present, providers support ABCs by administering supplemental oxygen, attaching monitors for and , and obtaining vascular access while preparing for advanced interventions like or . This approach emphasizes team dynamics, with a designated directing simultaneous tasks to minimize delays; for instance, one provider assesses while another initiates compressions if pulselessness is detected, aligning with data indicating that delays beyond 1 minute in rhythm analysis worsen neurologically intact survival rates to below 10%. For stable patients without immediate ABC threats, the algorithm proceeds to a primary assessment evaluating level of consciousness, vital signs (including age-specific heart rate, respiratory rate, and blood pressure), and oxygenation, followed by a secondary assessment incorporating history, physical exam, and point-of-care diagnostics. Interventions are titrated based on identified shock types (e.g., hypovolemic, distributive, or cardiogenic), with fluid boluses of 20 mL/kg isotonic crystalloid for non-cardiogenic shock and inotropes like epinephrine for refractory cases, supported by randomized trials demonstrating hemodynamic stabilization in 70-80% of septic shock cases when initiated early. The 2025 AHA updates reinforce this framework by incorporating real-time feedback devices for CPR quality and enhanced emphasis on post-arrest targeted temperature management to optimize cerebral perfusion, reflecting meta-analyses of over 1,000 pediatric cases showing improved outcomes with these refinements.

Differences from Adult Advanced Life Support

![Alternate way to perform compressions on an infant][float-right] Pediatric advanced life support (PALS) differs from adult advanced cardiovascular life support (ACLS) primarily due to variations in the underlying of . In children, arrests are predominantly hypoxic-ischemic, stemming from or shock, whereas adult arrests are more often primary arrhythmic, such as or pulseless . This distinction necessitates a greater emphasis in PALS on early and to address , following a compressions-airway-breathing (CAB) sequence, in contrast to ACLS's prioritization of rapid for shockable rhythms. Chest techniques are adapted for pediatric . For infants, the two-thumb encircling hands or two-finger method is recommended to achieve adequate depth of one-third the anteroposterior chest , while older children may use one- or two-handed ; adults typically employ two-handed compressions targeting 5-6 cm depth. rates remain 100-120 per minute across both, but pediatric protocols minimizing interruptions and ensuring full to optimize coronary in smaller vascular beds. Bag-mask is often sufficient initially in due to higher and lower airways, reducing the need for immediate advanced compared to adults. Defibrillation energies in start at 2-4 J/kg for the initial , escalating to 4 J/kg or higher for subsequent attempts, reflecting the smaller myocardial and lower requirements in children the fixed 120-200 J biphasic doses in ACLS. Pharmacologic interventions are weight-based in —epinephrine at 0.01 mg/kg every 3-5 minutes for nonshockable rhythms—while adult doses are standardized, such as 1 mg every 3-5 minutes. Vascular access prioritizes intraosseous () routes in PALS for rapid administration when intravenous access fails, given the technical challenges of pediatric veins. Post-resuscitation care in PALS incorporates (TTM) at 32-36°C to mitigate neurological , with evidence from pediatric trials showing equivalence between mild and normothermia. Continuous EEG monitoring and targeted (94-99%) are recommended to detect subclinical seizures and avoid , tailored to the immature pediatric brain's vulnerability, differing from adult-focused hemodynamic stabilization. For arrhythmias like , PALS favors vagal maneuvers and (0.1 mg/kg), with extracorporeal considered for refractory cases linked to congenital defects.

Target Population and Applicability

Pediatric Advanced Life Support (PALS) primarily targets infants and children experiencing cardiopulmonary arrest, severe respiratory compromise, or hemodynamic instability. According to American Heart Association (AHA) guidelines, infants are defined as those younger than approximately 1 year of age, while children encompass individuals from about 1 year through puberty, typically up to 8 years or when secondary sexual characteristics develop. These age delineations account for physiological differences in airway anatomy, vascular access challenges, and drug dosing requirements compared to adults. PALS protocols are tailored to these groups to optimize outcomes in settings equipped for advanced interventions, such as hospitals or pre-hospital environments with trained personnel. Applicability extends to scenarios involving (hypotensive or normotensive), arrhythmias ( or with poor ), or post-cardiac care, where alone is insufficient. Guidelines emphasize a systematic approach for healthcare providers, including rapid , vascular , and pharmacologic support, applicable in both in-hospital and out-of-hospital contexts. For neonates beyond the immediate —such as those older than 30 days or post-hospital discharge— may be adapted if (NRP) principles do not fully address the emergency, though NRP remains the standard for delivery room or initial stabilization. PALS is not intended for healthy pediatric populations or minor illnesses; its use is reserved for life-threatening events where empirical data show high mortality without intervention, such as with survival rates historically below 10% out-of-hospital. Exclusions include primary adult protocols, which apply to post-pubertal adolescents resembling adults in size and physiology, and immediate , where asphyxia-related causes predominate over the cardiac etiologies more common in older children. Training and application prioritize in pediatric emergency departments, intensive care units, or transport services to mitigate biases toward under-recognition of deterioration in this vulnerable group.

Foundational Components

Integration with Pediatric Basic Life Support

High-quality (CPR), as established in (PBLS), forms the cornerstone of Pediatric Advanced Life Support (PALS), with PALS extending these measures through coordinated advanced interventions to optimize outcomes in pediatric . The integration emphasizes uninterrupted CPR during transitions, where advanced providers verify effective compressions (rate of 100-120 per minute, depth of at least one-third the anterior-posterior chest diameter, full recoil, and minimal pauses) before layering on procedures such as vascular access, epinephrine administration (0.01 mg/kg IV/IO every 3-5 minutes for nonshockable rhythms), or for shockable rhythms (initial dose 2 J/kg). The PALS systematic approach begins by confirming PBLS initiation, including the CAB sequence (compressions, airway, breathing), and proceeds via a team-based model that assigns roles to maintain CPR continuity—one provider sustains compressions while others secure advanced airways (e.g., cuffed endotracheal tubes to minimize reintubation risks) or monitor end-tidal CO2 (target >10 mm Hg during CPR) and (≥25 mm Hg in infants, ≥30 mm Hg in children ≥1 year). This handover minimizes interruptions to less than 10 seconds, as prolonged pauses correlate with reduced survival rates, drawing from evidence in over 20,000 annual U.S. pediatric cardiac arrests. Post-return of spontaneous circulation (ROSC), continues with targeted post-arrest , targeting oxyhemoglobin of 94%-99%, normocapnia (PaCO2 35-45 mm Hg), and continuous EEG in encephalopathic patients to prevent secondary brain injury, all while sustaining PBLS-derived hemodynamic stability. The 2025 guidelines refine these elements from prior iterations, reaffirming high-quality CPR's primacy amid persistent data gaps in pediatric-specific efficacy.

Team-Based Resuscitation Dynamics

Effective team-based resuscitation in pediatric advanced life support (PALS) relies on coordinated roles among trained healthcare providers to deliver high-quality interventions during or periarrest situations, as emphasized in () guidelines. The approach prioritizes parallel task execution to minimize delays, with evidence from simulation studies showing that defined roles reduce errors in compression quality and rhythm recognition compared to responses. Unlike , which may involve fewer personnel, PALS teams typically comprise 4-6 members, enabling simultaneous management of circulation, airway, and rhythm interventions. The team leader assumes overall responsibility, directing actions, integrating assessments, and making critical decisions such as escalating to extracorporeal membrane oxygenation (ECMO) in refractory cases, without performing hands-on tasks to maintain oversight. Chest compressors focus on uninterrupted, high-quality compressions at 100-120 per minute with depths of 4-6 cm in children, minimizing interruptions to less than 10 seconds. The airway manager secures the airway via bag-mask ventilation or advanced techniques like endotracheal intubation, targeting end-tidal CO2 of 10-20 mm Hg to confirm placement and avoid hyperventilation. Intravenous/intraosseous (IV/IO) access and medication providers establish rapid vascular access—preferring IO in emergencies—and administer drugs like epinephrine every 3-5 minutes in asystole or pulseless electrical activity. The monitor/defibrillator operator identifies rhythms, charges the defibrillator for shockable arrhythmias (e.g., 2-4 J/kg initial shock), and applies feedback devices to guide compression metrics. A recorder tracks time, doses, and vital signs, while an optional CPR coach, introduced in 2020 AHA updates, provides real-time feedback on compression artifacts to enhance performance without distracting the leader. These roles adapt to team size and setting, with smaller teams combining functions. Communication employs closed-loop techniques to confirm actions, such as the leader stating, "Administer epinephrine 0.01 mg/kg ," followed by the responder confirming, "Epinephrine 0.01 mg/kg pushing now," reducing misunderstandings documented in where lapses correlate with poorer outcomes. Mutual performance critique—team members intervening constructively, e.g., correcting rates—fosters high-performance dynamics, supported by International Liaison Committee on Resuscitation (ILCOR) evidence that structured training in these elements improves adherence to algorithms. Post-resuscitation , using tools to review dynamics like role clarity and response times, enhances future performance, with observational data indicating up to 20% improvement in CPR metrics after implementation. Pediatric-specific challenges, such as variable arrest etiologies (e.g., respiratory predominant), necessitate teams attuned to early recognition, with 2025 guidelines underscoring multidisciplinary coordination for conditions like where extracorporeal cardiopulmonary resuscitation yields 72-95% survival in select cases. Limited randomized trials exist due to ethical constraints, but simulation-based research affirms that teams exhibiting strong dynamics achieve higher rates of (ROSC), estimated at 25-40% in-hospital for nonshockable rhythms. Ongoing gaps in pediatric data prompt extrapolation from adult studies, prioritizing simulation for competency.

Prevention and Early Recognition

Pediatric Early Warning Scores

Pediatric Early Warning Scores (PEWS) are standardized, aggregate scoring tools designed to quantify the risk of clinical deterioration in hospitalized children by assigning points to deviations in , behavioral changes, and other observable parameters from age-specific norms. These systems aim to enable timely escalation of care, such as activation of rapid response teams, to avert progression to cardiopulmonary , aligning with the preventive focus of Pediatric Advanced Life Support (PALS) protocols. The (AHA) endorses their use for early detection of deterioration in pediatric patients, recommending integration into routine monitoring workflows to trigger interventions and reduce incidence. Common components of PEWS include assessments of respiratory effort (e.g., increased or oxygen requirement), cardiovascular status (e.g., , , ), neurologic function (e.g., scale for alertness), and behavior or abnormalities, with total scores typically ranging from 0 (low risk) to higher thresholds (e.g., ≥4 or ≥5) prompting notification or team response. Scores are calculated at regular intervals, often every 4 hours for low-risk patients, with escalating frequency for higher scores, and are age-stratified to account for physiological differences in infants, toddlers, and older children. Variations exist, such as the Bedside PEWS, which emphasizes subjective nurse assessments alongside vitals, or emergency department-specific versions like ED-PEWS, adapted for in resource-limited settings. The concept originated in the mid-2000s, with early formulations like the 2006 Pediatric Early Warning System score developed to predict urgent needs in hospitalized children based on aggregated illness severity indicators. Subsequent adaptations, including national implementations (e.g., PEWS in 2023), have refined parameters through expert consensus and validation studies, though no single universal tool predominates due to contextual differences in healthcare settings. Validation studies demonstrate moderate to good discriminatory ability for outcomes like (AUROC 0.73–0.91 in some tools), but positive predictive values remain low (2–6%), risking alert fatigue without reducing false alarms. Effectiveness evidence from systematic reviews is limited, primarily from observational before-after designs prone to ; a 2022 meta-analysis of over 580,000 admissions found PEWS linked to lower mortality (pooled RR 1.18 without PEWS, 95% CI 1.01–1.38) and unplanned code events (RR 1.73, 95% CI 1.01–2.96), but no significant impact on arrests or overall critical deterioration, with results sensitive to study quality and confounders like response integration. High-quality randomized data are scarce, underscoring the need for cautious implementation alongside robust response mechanisms rather than reliance as standalone predictors.

Rapid Response and Deterioration Prevention

Rapid response systems (RRS) in pediatric advanced life support encompass multidisciplinary teams, such as rapid response teams (RRTs) or teams (METs), designed to detect and treat early clinical deterioration in hospitalized children, thereby averting progression to cardiopulmonary arrest or unanticipated (ICU) admission. These systems integrate with pediatric early warning scores (PEWS) by triggering team activation when predefined thresholds for vital sign instability, behavioral changes, or staff concern are met, emphasizing proactive intervention over reactive . The American Heart Association's 2025 guidelines highlight that, given the predominance of respiratory compromise or as precursors to in-hospital (IHCA) in children—accounting for the majority of cases—RRS facilitate timely , fluid , and to higher care levels to interrupt causal pathways of . Activation of RRTs is typically initiated by any bedside caregiver based on objective criteria (e.g., sustained , , or oxygen desaturation) or subjective "worried" concerns, enabling rapid mobilization of expertise including intensivists, respiratory therapists, and pharmacists for bedside assessment and stabilization. Core interventions prioritize reversible causes, such as optimizing , administering vasoactive agents for , or transferring to monitored units, aligning with principles of systematic to restore and oxygenation before arrest ensues. Hospitals implementing such systems often standardize protocols to ensure 24/7 availability and post-event debriefs for quality improvement, reducing delays in recognition that observational data link to worse outcomes in pediatric IHCA. Observational studies and systematic reviews provide of , with one at a pediatric reporting a 38% reduction in non-ICU arrests and over 21% decrease in overall mortality following RRT introduction. Another analysis across multiple sites demonstrated lowered rates of preventable cardiac arrests and hospital deaths attributable to pediatric METs, particularly in averting respiratory arrests through early escalation. The 2025 AHA update endorses RRS alongside early warning tools for diminishing IHCA incidence, based on before-after showing consistent reductions in deterioration events, though randomized controlled trials remain limited, underscoring reliance on real-world causal associations from temporal trends and control comparisons. Despite these benefits, effectiveness varies by institutional factors like team composition and activation barriers, with some studies noting no isolated impact on overall mortality without concurrent PEWS refinement.

Assessment Protocols

Age-Specific Vital Signs and Normal Ranges

In pediatric advanced life support, evaluating against age-specific norms is fundamental to distinguishing normal physiological variation from signs of deterioration, as younger children have higher baseline heart and respiratory rates driven by elevated metabolic demands and less efficient . These ranges, derived from clinical guidelines and observational data, guide decisions, with deviations signaling potential respiratory or circulatory compromise. Blood pressure assessment incorporates both systolic values and age-adjusted thresholds for , while oxygen saturation targets exceed 94% in most cases to ensure adequate . Normal heart rates decrease progressively with age. For neonates under 28 days, the range is 100–205 beats per minute () when awake and 90–160 when asleep. Infants aged 1–12 months exhibit 100–180 awake and 75–160 asleep. Toddlers (1–3 years) range from 98–140 awake and 75–130 asleep, preschoolers (3–5 years) 80–120 awake and 65–100 asleep, school-age children (6–11 years) 75–118 awake and 58–100 asleep, and adolescents (>12 years) 60–100 both awake and asleep. Respiratory rates follow a similar age-related decline, reflecting maturing lung capacity and control. Neonates maintain 30–60 breaths per minute, infants 25–50, toddlers 20–30, preschoolers 20–25, school-age children 18–25, and adolescents 12–20. Blood pressure norms rise with growth due to increasing and . Systolic blood pressure averages 60–80 mmHg in neonates (diastolic 30–53 mmHg), 70–105 mmHg in infants, escalating to adult-like values (100–130 mmHg systolic) in adolescents. In PALS, hypotension is defined as systolic below 70 mmHg for children under 1 year, below 70 + (2 × age in years) mmHg for ages 1–10 years, and below 90 mmHg for those over 10 years, serving as critical thresholds for . Core body temperature typically spans 36.5–37.5°C across ages, with deviations indicating potential or environmental stress.

Primary and Initial Assessment

The primary and initial assessment in pediatric advanced life support () utilizes the , a rapid, non-invasive visual evaluation conducted within 5 to 10 seconds to detect immediate threats to airway, breathing, or circulation. The PAT examines three domains: (assessing mental status via tone, interactivity, consolability, gaze, and speech or cry), (evaluating effort through abnormal sounds, positioning, retractions, flaring, or grunting), and circulation to skin (checking color, mottling, and via , typically under 2 seconds in normovolemic children). Abnormalities in any domain—such as , increased respiratory effort, or —signal the need for urgent intervention, guiding prioritization in team-based . Following the PAT, the primary assessment applies the ABCDE sequence to systematically evaluate and stabilize the child, integrating monitoring devices like , , , and end-tidal (ETCO₂) as soon as feasible. Airway (A) focuses on patency: position the head neutrally for infants or in a sniffing position for older children, suction secretions, and consider advanced airways (e.g., endotracheal ) if bag-mask proves inadequate. Breathing (B) assesses adequacy via rate (e.g., 30–60 breaths/min for newborns, 20–30 for school-age children), effort, and oxygenation (target SpO₂ 94%–99%); provide supplemental oxygen or positive-pressure if or is evident, aiming for ETCO₂ 35–45 mmHg. Circulation (C) evaluates central pulses (e.g., brachial or femoral), (normal awake range: 100–160 for infants, 70–120 for children), perfusion ( <2 seconds, warm extremities), and blood pressure (hypotension defined as systolic <70 mmHg + [2 × age in years] for children 1–10 years); initiate fluid boluses (20 mL/kg crystalloid) for shock or compressions if bradycardia (<60 with poor perfusion) persists despite ventilation and oxygenation. Disability (D) gauges neurologic function using the AVPU scale (Alert, Voice, Pain, Unresponsive) or pediatric Glasgow Coma Scale, checks pupils and blood glucose (target >70 mg/dL), and addresses reversible causes like . Exposure (E) involves brief full-body inspection for , , or while minimizing heat loss through warming measures, as exacerbates outcomes. This integrated process, updated in the 2025 American Heart Association guidelines to include diastolic blood pressure targets (≥25 mmHg in infants, ≥30 mmHg in children ≥1 year) during resuscitation assessments, emphasizes simultaneous interventions by a coordinated team to optimize return of spontaneous circulation and survival rates, which remain low at approximately 10%–20% for in-hospital pediatric arrests. If cardiac arrest is identified at any step (e.g., absent pulses or gasping respirations), transition immediately to the pediatric cardiac arrest algorithm with high-quality CPR at 100–120 compressions per minute and minimal interruptions.

Secondary Assessment and History Taking

The secondary assessment in pediatric advanced life support (PALS) follows the primary assessment once immediate threats to airway, , circulation, , and have been addressed and the patient is temporarily stabilized, allowing for a more detailed evaluation to uncover underlying etiologies of deterioration. This phase prioritizes identifying reversible causes, such as the H's and T's (, , , hypo-/, , , , toxins, ), which are adapted for pediatric contexts including congenital anomalies or ingestions. It integrates with ongoing but defers non-urgent diagnostics until is confirmed, as delays in this step have been associated with worse outcomes in retrospective studies of pediatric emergencies. The focused history, obtained rapidly from caregivers, witnesses, or medical records, employs the SAMPLE mnemonic to structure inquiry: Signs/symptoms (e.g., onset of or ); Allergies (including to medications or foods); Medications (current prescriptions, over-the-counter drugs, or recent administrations); Pertinent (chronic conditions, recent illnesses, perinatal events for neonates, or immunizations); Last oral intake (timing and content, relevant for surgical risks or ); Events preceding the incident (, , or environmental exposures). In children, this often reveals non-cardiac causes predominant in , such as respiratory infections or , with studies showing that caregiver-reported events correlate strongly with confirmed diagnoses in 70-80% of cases when systematically elicited. Omission of family history for genetic conditions, like channelopathies, can miss up to 20% of sudden cardiac events in adolescents per registry data. The focused physical examination complements the history through a targeted head-to-toe survey, emphasizing systems suggested by the presenting complaint while reassessing vital signs (e.g., , temperature, ) for trends. Key elements include inspecting for or rashes, palpating for or pulses, auscultating lung fields and for asymmetry, and evaluating neurological status via scale or adaptations for age. Age-specific findings, such as bulging fontanelles in infants indicating increased , guide prioritization; empirical data from audits indicate this exam identifies occult in 15-25% of compensated cases missed by primary alone. Reassessment occurs continuously, as decompensation can recur rapidly in due to smaller physiologic reserves.

Respiratory Compromise

Recognition of Distress and Failure

Respiratory distress in pediatric patients represents a state of increased due to inadequate oxygenation or , often without immediate threat to life but requiring prompt intervention to prevent progression. It is characterized by compensatory mechanisms such as and retractions, which aim to maintain adequate . In contrast, occurs when these mechanisms fail, resulting in (SpO₂ <90% to 94%) or hypercapnia (PaCO₂ >45 mm Hg), leading to and potential . Early recognition hinges on assessing airway patency, breathing effort, and circulation, with progression from distress to failure marked by worsening clinical indicators. Key signs of respiratory distress include:
  • Tachypnea: Elevated respiratory rate beyond age-specific norms (e.g., >60 breaths/min in infants <2 months, >50 in 2-12 months).
  • Increased work of breathing: Nasal flaring, intercostal or subcostal retractions, grunting (especially in infants to maintain alveolar recruitment), and head bobbing.
  • Abnormal breath sounds: (upper airway obstruction), wheezing (lower airway issues like ), (lung parenchymal disease), or prolonged expiratory phase.
  • Circulatory compensation: and , reflecting sympathetic activation.
These signs indicate an open and maintainable airway with sufficient but labored air movement, often accompanied by anxiety or agitation. Infants are particularly vulnerable due to smaller airways, immature respiratory muscles, and reliance on , making subtle signs like grunting or retractions more ominous. Respiratory failure manifests when distress decompensates, evidenced by:
  • Hypoxemia and poor : (central or peripheral), mottling, or SpO₂ failing to improve with supplemental oxygen.
  • Decreased ventilatory effort: , apnea, or irregular breathing patterns, with diminished or absent breath sounds and poor chest rise.
  • Neurologic and circulatory deterioration: Altered mental status (, unresponsiveness), (late sign in children, often hypoxic-driven), and weak pulses.
Pulse oximetry can overestimate saturation in patients with darker skin tones, necessitating or gas for confirmation. In , over 20,000 annual U.S. cardiac arrests stem from respiratory causes, underscoring the causal link from untreated failure to cardiopulmonary collapse via hypoxia-induced myocardial dysfunction. The 2025 guidelines emphasize avoiding over-reliance on single metrics, integrating clinical observation with for timely escalation.

Initial Stabilization Techniques

Initial stabilization of pediatric respiratory compromise prioritizes securing airway patency to prevent progression to failure or arrest. Standard maneuvers include the head-tilt chin-lift for patients without suspected cervical spine injury, or jaw thrust to minimize spinal movement if is possible. Oropharyngeal or nasopharyngeal airways may be inserted as adjuncts in unconscious patients to maintain openness, provided no gag reflex is present. Suctioning of secretions or vomitus is performed if visible obstruction impairs , using gentle technique to avoid mucosal trauma, particularly in infants with smaller airways. Patient positioning optimizes respiratory effort; for example, infants may benefit from a neutral head position, while older children with lower airway issues can be placed semi-upright to reduce . Supplemental oxygen is administered immediately via , face mask, or high-flow devices to target oxyhemoglobin saturation of 94% to 99%, avoiding which risks free radical injury. guides titration, though limitations in accuracy for certain skin tones necessitate confirmatory gas if feasible. If spontaneous breathing is inadequate or absent, positive-pressure ventilation via bag-mask device is initiated at 20 to 30 breaths per minute, ensuring adequate chest rise without excessive pressure to prevent gastric or . Two-person technique enhances seal and efficacy in non-arrest scenarios. Continuous monitoring of , color, and effort guides escalation to advanced support. These interventions aim to restore adequate while addressing reversible causes like with nebulized bronchodilators if indicated.

Advanced Airway Management and Ventilation

Advanced airway management in pediatric advanced life support (PALS) is indicated when bag-mask ventilation fails to achieve adequate oxygenation and ventilation, particularly during or severe , though evidence shows no consistent survival benefit over bag-mask ventilation in out-of-hospital settings. In-hospital scenarios may warrant advanced airways if expertise and equipment allow without interrupting chest compressions, but bag-mask ventilation remains the initial preference to minimize pauses in CPR. Supraglottic airways or should only proceed if placement can be achieved rapidly by skilled providers, as delays or failures increase risks. Endotracheal intubation involves rapid techniques tailored to pediatric , using cuffed endotracheal tubes for children to ensure a secure seal, reduce reintubation needs (less than 1% rate for post-extubation in studies of over 2,900 cases), and improve reliability. Tube size is estimated by age-based formulas (e.g., 3.5 + (age/4) for uncuffed in infants, adjusted for cuffed), with video laryngoscopy recommended for difficult airways due to anatomical challenges like a relatively large and anterior . Supraglottic airways, such as laryngeal mask airways, serve as alternatives when fails, offering easier insertion but potential for suboptimal tidal volumes in . Cricoid pressure is not routinely advised, as it lacks evidence for preventing and may distort , hindering . Confirmation of advanced airway placement relies on end-tidal (ETCO2) detection via or colorimetric devices, which outperform clinical in detecting dislodgement or esophageal , especially in low-perfusion states common in . Persistent ETCO2 waveform confirms tracheal position, with initial readings potentially low during CPR; absent ETCO2 after 6-8 breaths suggests malposition. Chest rise, bilateral breath sounds, and absence of epigastric sounds provide adjunctive verification, but is essential for ongoing monitoring to avoid unrecognized displacement during transport or compressions. Ventilation with an advanced airway during CPR targets 25-30 breaths per minute for older children and at least 30 for infants to optimize without , which can reduce coronary . Asynchronous ventilations (uncoupled from compressions) allow continuous CPR, delivering 100% oxygen at tidal volumes of 6-8 mL/kg, adjusted to achieve visible chest rise and ETCO2 of 10-20 . Post-, target oxyhemoglobin saturation of 94-99% and normocapnia (PaCO2 35-45 ) to prevent cerebral or hypocapnia-induced . Complications of advanced airways include placement failure (first-attempt success 60-90% in experienced hands, lower prehospital at 50-70%), airway , , and interruptions exceeding 10 seconds, which correlate with worse outcomes. risks esophageal placement or right mainstem intubation more than supraglottic devices, though latter may inadequately protect against . Pediatric-specific issues, such as subglottic from overinflated cuffs, are minimized by maintaining cuff pressure below 25 H2O with a slight leak. Teams must prepare for failed attempts by reverting to bag-mask or using rescue devices, emphasizing simulation training for proficiency.

Shock States

Classification and Severity Assessment

Shock in pediatrics is classified into four primary categories based on underlying : , , , and . results from absolute or relative volume loss, such as hemorrhage or from . involves maldistribution of blood flow due to , commonly seen in or . stems from primary myocardial dysfunction, including pump failure from congenital heart disease or arrhythmias. arises from mechanical impedance to blood flow, as in or . Multiple shock types may coexist in a single patient, necessitating comprehensive evaluation. Severity assessment follows a continuum from compensated to decompensated states, emphasizing early recognition since —a hallmark of —manifests late in children due to robust compensatory mechanisms. Compensated maintains adequate through , increased systemic vascular resistance via , and , with normal but signs including prolonged (>2 seconds), cool extremities, weak peripheral pulses, and mild alterations in mental status. Decompensated occurs when these mechanisms fail, leading to (systolic below the 5th percentile for age and sex), profound or , cold clammy skin, diminished central pulses, , , and severe mental status changes indicating organ hypoperfusion. Clinical assessment relies on vital signs, physical examination, and laboratory data rather than isolated blood pressure measurements, as pediatric physiology allows prolonged compensation before hypotension. Key indicators include age-adjusted tachycardia and tachypnea exceeding normal ranges, mottled skin, decreased urine output (<1 mL/kg/h), and elevated lactate (>2 mmol/L suggesting tissue hypoperfusion). In septic shock, a subset of distributive shock, severity incorporates the Phoenix Sepsis Score (≥2 points for suspected sepsis) with cardiovascular dysfunction defined by persistent hypotension requiring vasopressors or fluid-refractory states. Hemodynamic monitoring, such as end-tidal CO2 (target ≥20 mm Hg during resuscitation) and targeted diastolic blood pressure (≥25 mm Hg in infants, ≥30 mm Hg in children ≥1 year), aids in gauging response and progression. Early intervention in compensated phases improves outcomes, as decompensation correlates with higher mortality risk.

Hypovolemic and Distributive Shock Management

Hypovolemic shock in pediatrics arises from acute loss of intravascular volume, most frequently due to dehydration from gastroenteritis or hemorrhage from trauma, accounting for the majority of shock cases in children outside neonatal periods. Initial recognition involves signs of poor perfusion such as prolonged capillary refill (>2 seconds), tachycardia, weak pulses, and altered mental status, with hypotension as a late finding. Management prioritizes rapid volume replacement with isotonic crystalloid solutions, delivering 20 mL/kg boluses intravenously or intraosseously over 5-10 minutes, followed by immediate reassessment of perfusion and vital signs; up to 60 mL/kg may be administered in the first hour if response is inadequate, while monitoring for overload. Balanced crystalloids, such as lactated Ringer's, are preferred over 0.9% saline to minimize risks like hyperchloremic acidosis. For hemorrhagic causes, concurrent hemorrhage control via direct pressure, tourniquets, or surgical means is essential, with early transfusion of packed red blood cells (10-20 mL/kg) indicated if losses exceed 20% of blood volume or ongoing bleeding persists. Distributive shock, predominantly septic in origin among pediatric patients, features , relative , and capillary leak leading to maldistribution of despite normal or increased volume status. Clinical hallmarks include warm extremities early on (hyperdynamic phase), fever, , and evidence of source, progressing to with mottling and if untreated. Treatment commences with the same fluid strategy as —20 mL/kg boluses with reassessment—but emphasizes source control and empiric broad-spectrum antibiotics within the first hour of recognition, ideally after blood cultures. Fluid-refractory cases (persistent or poor after 40-60 mL/kg) necessitate vasoactive support, with epinephrine infusion (0.1-1 mcg/kg/min) favored for "" phenotypes common in infants, or norepinephrine for "warm" ; is de-emphasized due to lower efficacy. Corticosteroids may be considered for refractory unresponsive to fluids and inotropes, particularly in suspected . Both shock types require continuous monitoring of endpoints like normalization of capillary refill (<2 seconds), strong central pulses, urine output (>1 mL/kg/h), and lactate clearance, with escalation to advanced therapies if stabilization fails. In resource-limited settings, smaller initial boluses (10 mL/kg) may be trialed to mitigate overload risk in distributive shock.

Cardiogenic and Obstructive Shock Management

Cardiogenic shock in pediatric patients arises from primary myocardial dysfunction, resulting in reduced cardiac output and inadequate tissue perfusion despite normal or increased preload. Common etiologies include myocarditis, cardiomyopathy, arrhythmias, anomalous left coronary artery from the pulmonary artery, and complications from congenital heart disease or post-cardiac surgery. Recognition involves identifying signs such as marked tachycardia, hepatomegaly, gallop rhythm, prolonged capillary refill time greater than 3 seconds, diminished pulses, and evidence of pulmonary congestion like rales or radiographic cardiomegaly, distinguishing it from other shock types by the presence of cardiac failure indicators rather than volume depletion. Initial management prioritizes expert consultation with pediatric cardiology or intensivists due to high mortality rates exceeding 50% in severe cases, alongside supportive measures to optimize oxygen delivery and minimize myocardial oxygen demand through intubation, mechanical ventilation, normothermia maintenance, and sedation if needed. Fluid administration must be cautious to prevent , limited to small boluses of 5-10 mL/kg crystalloid over 10-20 minutes with frequent reassessment, as excessive volume can exacerbate congestion in hearts with impaired contractility. Vasoactive agents form the cornerstone of therapy to restore contractility and support ; epinephrine infusion at 0.1-1 mcg/kg/min intravenously is recommended as first-line for , titrated to effect, while at 5-20 mcg/kg/min may be used for inotropic support in select cases without profound . Refractory cases warrant consideration of mechanical circulatory support such as (ECMO), which has demonstrated survival rates up to 46% without transplantation in fulminant . management follows PALS tachycardia or algorithms, and continuous monitoring for , imbalances, and is essential. Obstructive shock occurs due to mechanical impedance of cardiac filling or output, leading to decreased venous return or arterial flow; pediatric causes include tension , , massive (rare), and ductal-dependent congenital heart defects with obstruction. Clinical signs encompass , muffled (in tamponade), tracheal deviation or absent breath sounds (in ), jugular venous distension, and greater than 10 mmHg, often with rapid progression to decompensated if untreated. Treatment demands rapid identification and reversal of the underlying obstruction as the definitive intervention: for tension , immediate needle thoracostomy decompression at the second midclavicular line followed by insertion; for pericardial , urgent guided by if available. Supportive measures include initial fluid boluses of 10-20 mL/kg crystalloid, though titrated conservatively similar to to avoid overload, combined with vasoactive support using epinephrine infusion if perfusion remains inadequate post-decompression. In trauma-related obstructive shock, such as or , surgical consultation for may be required in pulseless patients with penetrating injury, while management involves anticoagulation or only after stabilization. Early transfer to a facilitates advanced imaging and hemodynamic monitoring to confirm resolution and prevent recurrence.

Cardiac Arrest

Etiologies Predominant in Pediatrics

In pediatric patients, most often results from progressive respiratory or circulatory failure leading to and , rather than primary arrhythmic or ischemic events that predominate in adults. This distinction arises because children's smaller airways, higher oxygen consumption, and immature compensatory mechanisms render them vulnerable to rapid from insults like airway obstruction or . Out-of-hospital s in children are frequently asphyxial, with studies indicating that up to 70-80% involve initial respiratory compromise before cardiac involvement. Respiratory failure is the leading precipitant, often due to conditions such as , lower respiratory tract infections (e.g., or ), or upper airway obstruction from or , which cause hypoxemia, hypercarbia, and eventual or . Drowning, a common cause of asphyxial , accounts for approximately 10-20% of pediatric out-of-hospital arrests in some regions, with from submersion leading to cardiac standstill within minutes. In infants, (SIDS) represents a significant , linked to failures in mechanisms during , though exact incidence has declined with risk reduction campaigns; epidemiological data from 2012-2020 show SIDS comprising 20-30% of infant arrests under 1 year. Circulatory shock states, particularly hypovolemic from (e.g., due to or burns) or , and distributive from , frequently culminate in arrest. is predominant in children over 1 year, causing up to 25% of out-of-hospital cases through hemorrhage, tension , or disrupting autonomic control; for instance, accidents or falls lead to rapid in toddlers and school-age children. -induced distributive shock, often from bacterial infections like meningococcemia, triggers myocardial depression and , with pediatric in-hospital data showing it as a factor in 15-20% of arrests. Primary cardiac etiologies, such as congenital heart defects, cardiomyopathies, or channelopathies (e.g., ), are less common overall—accounting for 5-15% of cases—but increase in prevalence among adolescents and in-hospital settings. Congenital anomalies predominate in neonates (up to 84% of early cardiac-related arrests), while inherited arrhythmias cause 20-30% of sudden deaths in older children without structural disease. Metabolic derangements like or electrolyte imbalances (e.g., from renal failure) and toxins (e.g., ingestions of beta-blockers or opioids) also feature prominently as reversible triggers. Resuscitation protocols emphasize identifying and treating these reversible causes via the pediatric H's and T's mnemonic: Hypoxia, Hypovolemia, Hydrogen ion (), Hypo-/hyperkalemia, Hypoglycemia, Hypothermia; Toxins, Tamponade (cardiac), Tension , Trauma (or thrombosis in select cases). In children, , , and are prioritized due to their frequency, with interventions like fluid boluses (20 mL/kg crystalloid) for or needle decompression for directly addressing underlying to restore .

Recognition and Immediate Actions

Pediatric cardiac arrest is recognized by unresponsiveness, absence of normal breathing (including only gasping or agonal respirations), and lack of a detectable within 10 seconds of . In healthcare settings, providers should perform a check at central sites such as the carotid or while simultaneously evaluating breathing, as delays in recognition can critically impact outcomes. Precursors such as less than 60 beats per minute with signs of poor , , or warrant heightened vigilance, though arrest is confirmed only upon meeting the full criteria. Upon recognition, immediate actions prioritize activation of the emergency response system and initiation of high-quality (CPR). A provider should shout for help, delegate tasks such as retrieving an (AED) or calling for advanced support, and begin chest compressions at a rate of 100-120 per minute with adequate depth—approximately 5 cm (2 inches) for children and 4 cm (1.5 inches) for infants—allowing full chest recoil between compressions. should be provided at a of 30 compressions to 2 breaths, using bag-mask ventilation initially to minimize interruptions, with 100% oxygen if available during CPR. For trained healthcare providers in pediatric advanced life support, pulse checks should not exceed 10 seconds, and if doubt exists, CPR should commence presumptively to avoid pauses that reduce survival chances. Early attachment of a monitor or defibrillator pads is recommended to assess rhythm while CPR continues, facilitating transition to rhythm-specific interventions without delaying basic support. These steps align with 2025 guidelines emphasizing minimal interruptions and team coordination to optimize .

Resuscitation Algorithm and Rhythm Management

The Pediatric Cardiac Arrest Algorithm, as updated in the 2025 (AHA) guidelines, prioritizes high-quality (CPR) initiated immediately upon recognition of in children, with simultaneous efforts to identify and treat the underlying . High-quality CPR entails chest compressions at 100-120 compressions per minute, to a depth of at least one-third the anteroposterior of the chest (approximately 4-6 cm in infants and 5-6 cm in children), allowing complete chest recoil between compressions, minimizing pauses to less than 10 seconds, and avoiding excessive . Concurrently, rescuers establish intravenous or intraosseous (IV/IO) access, provide bag-mask with supplemental oxygen, and attach a cardiac or defibrillator to evaluate the without interrupting compressions. Rhythm assessment divides management into shockable (ventricular fibrillation [VF] or pulseless ventricular tachycardia [pVT]) and nonshockable ( or [PEA]) pathways, with early emphasized as a cornerstone for shockable rhythms to improve survival outcomes. For shockable rhythms, an initial unsynchronized dose of 2 J/kg is delivered, followed immediately by 2 minutes of CPR; subsequent shocks use 4 J/kg (or higher equivalent biphasic energy), with epinephrine administered at 0.01 mg/kg IV/IO every 3-5 minutes starting after the first shock if (ROSC) is not achieved. Antiarrhythmic therapy, such as (5 mg/kg IV/IO) or lidocaine (1 mg/kg IV/IO), is considered after the third shock in refractory VF/, alongside evaluation for reversible causes using the H's and T's mnemonic (, , hydrogen ion [], hypo-/hyperkalemia, , tension pneumothorax, , toxins, ). In nonshockable rhythms, CPR continues in 2-minute cycles with rhythm checks, and epinephrine is administered as soon as possible (0.01 mg/kg / every 3-5 minutes), reflecting 2025 guideline updates prioritizing rapid vasoactive support to enhance coronary and cerebral perfusion. may be pursued if bag-mask proves inadequate, but should not delay initial CPR or attempts; post-cycle assessments confirm ROSC or persistent arrest, with ongoing treatment of reversible etiologies. Throughout, teams coordinate to reduce preshock pauses and ensure sequential integration of interventions, as prolonged untreated shockable rhythms correlate with diminished neurologically intact survival rates in pediatric out-of-hospital and in-hospital arrests.

Arrhythmias

Bradydysrhythmias: Recognition and Treatment

Bradydysrhythmias in pediatric patients manifest as ventricular rates slower than age-appropriate norms, often , , or junctional escape rhythms, and are frequently secondary to , , , , , or toxic ingestions. Recognition prioritizes clinical signs of hemodynamic compromise over absolute rate thresholds, including altered mental status, (systolic below the 5th for age), poor peripheral (capillary refill exceeding 2 seconds, mottled skin, diminished pulses), and manifestations of , as children possess limited cardiac reserve and decompensate rapidly. confirms the dysrhythmia and guides etiology, with continuous monitoring essential to detect progression to pulseless arrest when falls below 60 beats per minute despite supportive measures. Treatment adheres to the 2025 Pediatric With a Pulse , emphasizing reversal of reversible causes while supporting cardiopulmonary function. Initial steps include securing a patent airway, administering supplemental oxygen to achieve saturation above 94%, and providing positive-pressure ventilation for or , as these address the most common precipitants like . If compromise persists with under 60 beats per minute, initiate high-quality chest compressions at a rate of 100-120 per minute with depth one-third the anteroposterior chest diameter, establish intravenous or intraosseous access, and deliver epinephrine 0.01 mg/kg (0.1 mL/kg of 1:10,000 concentration, maximum 1 mg per dose), repeatable every 3-5 minutes until response. Atropine 0.02 mg/kg intravenously or intraosseously (minimum 0.1 mg, maximum 0.5 mg for children under 5 years or 1 mg for adolescents, repeatable once after 5 minutes) targets excessive or high-degree but shows limited efficacy in hypoxic states. For refractory cases, particularly complete , transcutaneous pacing at rates ensuring above minimal thresholds may be employed, though evidence in remains limited. Reassess and every 2 minutes; absence of necessitates immediate transition to the pediatric algorithm. The 2025 guidelines reaffirm these interventions without substantive changes from 2020, underscoring the primacy of epinephrine over atropine in most scenarios due to superior data on hemodynamic support.

Tachyarrhythmias: Differential Diagnosis and Interventions

Tachyarrhythmias in pediatric patients are heart rates exceeding age-specific norms, typically greater than 220 beats per minute in infants or 180 in children, often requiring differentiation from via electrocardiogram (ECG) analysis for P waves, RR interval variability, and QRS duration. features normal P waves and variable RR intervals, while pathologic forms like (SVT) show absent or abnormal P waves with fixed RR intervals and abrupt onset. Wide-complex tachycardias (QRS >0.09 seconds) necessitate distinguishing (VT) from SVT with aberrancy, as VT carries higher risk of deterioration to pulseless arrest. Initial management prioritizes airway, breathing, circulation support, oxygen administration, and vascular access, with continuous ECG monitoring to guide therapy. For hemodynamically stable narrow-complex probable SVT, vagal maneuvers (e.g., ice to face in infants or Valsalva in older children) are attempted first, followed by at 0.1 mg/kg (maximum 6 mg), repeatable at 0.2 mg/kg (maximum 12 mg) if ineffective. In cases of cardiopulmonary compromise—manifesting as , altered mentation, or —immediate synchronized at 0.5–1 J/kg is indicated, escalating to 2 J/kg if needed, with if feasible without delay. Wide-complex tachycardias with adequate perfusion may receive diagnostic if regular and monomorphic, presuming possible SVT with aberrancy, but expert consultation is advised; (5 mg/kg IV over 20–60 minutes) or serve as alternatives for refractory cases. Unstable wide-complex rhythms or confirmed VT warrant urgent synchronized , with defibrillation doses of 2 J/kg initially for pulseless VT per the algorithm. The 2025 guidelines introduce intravenous for refractory SVT with compromise unresponsive to standard measures, particularly when expert input is unavailable, reflecting limited but emerging evidence for its efficacy in pediatric re-entrant tachycardias.
Rhythm TypeKey ECG FeaturesPrimary Interventions
Sinus TachycardiaNormal P waves, variable RRTreat underlying cause (e.g., fever, )
Narrow-Complex SVTAbsent/abnormal P waves, fixed RRVagal maneuvers, , cardioversion if unstable
Wide-Complex (Probable VT)Prolonged QRS, AV dissociation possible, if stable
Ongoing research highlights gaps in pediatric-specific data for pulseless VT and optimal antiarrhythmic sequencing, underscoring the need for etiology-directed beyond rhythm control, such as addressing congenital anomalies or imbalances.

Post-Resuscitation Care

Immediate Stabilization

Following (ROSC) in pediatric , immediate stabilization prioritizes optimizing oxygenation, ventilation, and circulation to prevent secondary organ injury and support hemodynamic stability. providers should confirm ROSC through palpable pulses, electrocardiographic activity, and end-tidal (ETCO2) greater than 10-20 mm . Airway patency must be ensured, with advanced airway management such as endotracheal considered if bag-mask is inadequate; cuffed endotracheal tubes are recommended to minimize air leak and reintubation risk while monitoring cuff pressure to prevent tracheal injury. should target a rate of 20-30 breaths per minute in intubated patients, avoiding , with arterial blood gas analysis guiding adjustments to maintain normocapnia (PaCO2 35-45 mm Hg). Oxygenation is titrated to achieve peripheral oxygen saturation (SpO2) of 94-99% using the lowest to prevent , which has been associated with worse outcomes in some studies; continuous and arterial blood gases every 10-15 minutes support this. For circulation, continuous invasive pressure monitoring is advised, targeting systolic above the 5th-10th for age and sex to avoid , with initial fluid boluses of 10-20 mL/kg administered cautiously to prevent fluid overload. If hypotension persists, vasopressors such as epinephrine or norepinephrine infusions are initiated to maintain between the 5th and 74th percentiles, correlated with favorable neurologic outcomes. Additional immediate measures include and correcting or , with blood glucose checked promptly, and preventing by targeting core temperature below 37.5°C through antipyretics or cooling methods, as fever post-ROSC worsens . confirms airway placement and guides , while continuous detects recurrent arrhythmias. These steps align with 2020 and 2025 guidelines, emphasizing individualized care based on continuous hemodynamic assessment.

Neuroprotective Strategies and Monitoring

In pediatric post-cardiac arrest care, neuroprotective strategies aim to mitigate secondary brain injury by optimizing cerebral , oxygenation, metabolism, and control, though high-quality evidence remains limited compared to adults. (TTM) at 32–36°C for 24–48 hours is considered reasonable for comatose children after (ROSC), but randomized trials such as the Therapeutic Hypothermia after Pediatric Cardiac Arrest (THAPCA) out-of-hospital (2015) and in-hospital (2017) studies demonstrated no significant improvement in survival with favorable neurological outcomes versus targeted normothermia (36–37.5°C). In THAPCA-OH (n=295), 20.0% in the hypothermia group versus 12.5% in the normothermia group achieved survival with Pediatric Cerebral Performance Category 1–2 at 1 year (adjusted 1.54, 95% 0.86–2.76; =0.14), while THAPCA-IH (n=329) showed 31.7% versus 30.7% (adjusted 1.02, 95% 0.62–1.65; =0.95), with no differences in adverse events like arrhythmias or bleeding. (AHA) guidelines reflect this equivocal evidence, recommending against routine below 32°C due to risks and lack of proven benefit. Hemodynamic optimization targets > fifth percentile for age to ensure , with vasopressors like epinephrine if needed, as post-ROSC (defined as systolic BP < fifth percentile) within 6 hours associates with lower survival to discharge (adjusted odds ratio 0.68, 95% CI 0.50–0.93 in THAPCA analysis). Ventilation strategies avoid hyperoxia (PaO2 >300 mmHg) and (PaCO2 <35 mmHg), targeting normocapnia (35–45 mmHg) and SpO2 94–99% to prevent reperfusion injury, supported by preclinical data showing reduced neuronal apoptosis. Glucose control maintains levels at 70–180 mg/dL, as both hypo- (<60 mg/dL) and hyperglycemia (>180 mg/dL) correlate with worse outcomes in observational pediatric cohorts. Prompt seizure treatment with or is prioritized, as subclinical seizures occur in up to 44% of comatose children post-arrest and independently predict poor neurodevelopment. Neurological monitoring employs multimodal approaches for early detection of injury and prognostication. Continuous (EEG) within 24 hours of ROSC identifies non-convulsive in 10–20% of cases, guiding and associating burst-suppression or malignant patterns with <10% favorable outcomes at 6 months. Near-infrared spectroscopy (NIRS) tracks regional cerebral oxygenation (rSO2), with values <50% post-ROSC predicting poor prognosis (sensitivity 89%, specificity 75% in small series). Serum biomarkers like neuron-specific enolase (NSE >100 μg/L at 48–72 hours) and S100B (>2 μg/L) risk stratification, though thresholds vary by assay and lack prospective validation in . , including MRI diffusion-weighted sequences at 3–7 days, detects hypoxic-ischemic lesions with 80–90% sensitivity for unfavorable outcomes, outperforming somatosensory evoked potentials (SSEPs) alone, which show bilateral absence predicting 0% good recovery. endorses deferring withdrawal of life-sustaining until at least 72 hours post-rewarming, integrating multiple modalities to avoid premature decisions influenced by single poor prognosticators.

Training and Implementation

Certification and Simulation-Based Learning

Pediatric Advanced Life Support () certification is administered by the () and targets healthcare providers managing critically ill or injured pediatric patients. The standard PALS Provider Course requires participants to complete precourse self-assessment and remediation, followed by approximately 14 hours of instructor-led training over two days, including didactic lectures, skill stations, and simulated clinical scenarios. Successful completion, demonstrated through written examinations and psychomotor skill assessments, awards a PALS provider card valid for two years, with renewal necessitating recertification. Prerequisites include current (BLS) certification for healthcare providers and familiarity with electrocardiogram interpretation and basic pharmacology. Alternative formats, such as HeartCode PALS, combine online eSimulation modules with in-person skills verification to accommodate flexible scheduling. Simulation-based learning forms the core of training, emphasizing hands-on in high-fidelity scenarios that replicate pediatric emergencies like respiratory distress, , and . The incorporates learning stations for respiratory emergencies, and , and cardiac issues, where teams apply algorithms through scenario-based simulations, followed by structured debriefings to reinforce and . These simulations use mannequins and audiovisual aids to mimic physiological responses, enabling learners to rapid assessment, sequencing, and communication under controlled conditions. Empirical evidence supports the efficacy of in , with studies demonstrating improved time to initiation among pediatric residents post-training. High-fidelity simulations enhance depth, theoretical , and skills compared to traditional didactic methods alone. For instance, simulation training has been shown to boost in mock resuscitations, addressing gaps in procedural and during actual events. However, retention of these skills requires periodic refreshers, as decay occurs without ongoing practice, underscoring the need for integrated in maintenance. Despite these benefits, implementation varies by institution, with resource-intensive simulations potentially limiting access in low-volume settings.

Skill Retention and Performance Challenges

Studies indicate that psychomotor skills acquired during Pediatric Advanced Life Support (PALS) training deteriorate rapidly among trainees, with pediatric interns demonstrating poor performance in simulated scenarios regardless of the interval since certification. In pediatric residents, skill retention proves inadequate even 1-3 months post-training, highlighting the limitations of standard certification courses in sustaining proficiency. This decay extends to experienced providers, such as paramedics, where knowledge of PALS principles declines over time, though a 2-year recertification interval may suffice for those with prior exposure. Temporal patterns of skill loss show initial declines within 8 months of , with continued deterioration thereafter, underscoring the need for retraining as early as 6 months to mitigate performance gaps. Pediatric-specific challenges exacerbate this issue, as cardiac arrests in children occur infrequently—far less often than in adults—resulting in minimal real-world and accelerated skill atrophy despite formal . High-stakes clinical environments further impair execution, where stress transforms routine procedures into complex tasks, often yielding suboptimal team coordination and adherence to algorithms. Disparities between cognitive mastery and hands-on execution represent a core performance hurdle; trainees frequently excel in theoretical assessments but falter in applying advanced interventions like vascular access or rhythm management during simulations. Even with refresher sessions, skills degrade over time, as evidenced by persistent deficiencies in high-quality compressions and in hospital-based pediatric teams. These patterns reflect underlying causal factors, including limited exposure and the physiological nuances of pediatric —such as age-specific dosing and —that demand repeated deliberate practice to counteract natural forgetting curves observed in procedural training.

Evidence Base and Outcomes

Clinical Efficacy Data

Survival to hospital discharge following pediatric out-of-hospital cardiac arrest (OHCA) averages 11.4%, with age-specific rates of 4.9% for infants, 13.2% for children, and 17.1% for adolescents, based on data from the Cardiac Arrest Registry to Enhance Survival (CARES) and other registries analyzed in the 2020 (AHA) guidelines. In-hospital cardiac arrest (IHCA) demonstrates higher survival, at 41.1% overall and 38% for pulseless events, reflecting improved access to advanced interventions but still highlighting persistently low rates compared to adult counterparts. Temporal trends indicate progress, with IHCA survival rising from 19% in 2000 to 38% by 2018, correlated with enhanced , protocol adherence, and system-wide implementation of PALS elements like high-quality CPR and rapid defibrillation. Key PALS interventions show variable efficacy supported primarily by observational studies and registries, as randomized controlled trials (RCTs) remain limited due to event rarity. For shockable rhythms (ventricular fibrillation or pulseless ventricular tachycardia), early defibrillation—recommended at 2-4 J/kg initially, escalating to 4-10 J/kg—yields ROSC rates up to 50% and survival benefits when delivered within minutes, with automated external defibrillators (AEDs) deemed safe and effective even in infants when standard doses are exceeded. In non-shockable rhythms (asystole or pulseless electrical activity), epinephrine administration every 3-5 minutes improves ROSC, short-term survival, and discharge rates, with meta-analyses confirming that doses delivered earlier (e.g., within 5 minutes) double odds of survival compared to delayed dosing. However, routine high-dose epinephrine lacks superiority over standard dosing and may worsen neurological outcomes in some cohorts. Advanced airway management, including endotracheal or supraglottic devices, does not confer or favorable neurological outcome advantages over bag-mask in pediatric OHCA or IHCA, per systematic reviews and RCTs showing equivalent rates of intact (class 2b recommendation). (ECPR), a PALS-recommended for in select centers (e.g., cardiac patients), achieves 43.8-48% to in IHCA cohorts with congenital heart , outperforming conventional CPR in observational data but requiring specialized resources. Post-resuscitation care under emphasizes hemodynamic stability and , with evidence linking systolic above the 5th percentile in the first 6-12 hours to higher survival (up to 20-30% relative improvement) and better neurological function. (TTM) at 32-34°C versus normothermia (36-37.5°C) shows no difference in 1-year survival with favorable (12-13% in both arms) from two pediatric RCTs. Up to 47% of survivors achieve good neurological status at discharge, though long-term deficits in and executive function persist in many, underscoring that while optimizes chain-of-survival links, overall efficacy is constrained by arrest etiology (e.g., asphyxia-dominant in ) and pre-arrest factors.
Cardiac Arrest TypeSurvival to DischargeKey Influencing FactorsEvidence Level
(all ages)11.4%Initial rhythm, bystander CPR, ageObservational/registries (Class 2a)
IHCA (pulseless)38%Shockable rhythm, ECPR availabilityObservational/trends (Class 2b)
Shockable IHCA40-50% (with early )Time to shock <2 minRegistries/RCT analogs (Class 1)
Non-shockable IHCA10-20%Early epinephrineMeta-analysis (Class 2a)

Knowledge Gaps and Research Priorities

Despite advances in resuscitation science, pediatric advanced life support (PALS) guidelines continue to rely heavily on extrapolated adult data and limited pediatric evidence, with over 20,000 annual pediatric cardiac arrests in the United States highlighting the urgency for targeted research. Critical gaps include insufficient high-quality randomized controlled trials (RCTs) on core interventions, such as the optimal timing and dosing intervals for epinephrine in shockable rhythms like ventricular fibrillation (VF) or pulseless ventricular tachycardia (pVT), where its relationship to defibrillation success remains unestablished. Similarly, exact success rates for vagal maneuvers (e.g., ice water immersion or postural changes) in supraventricular tachycardia (SVT) are unknown, and comparative data on second-line agents like verapamil, β-blockers, or amiodarone for adenosine-refractory SVT are scarce. In post-resuscitation care, prospective data on targeting diastolic blood pressure during cardiopulmonary resuscitation (CPR) or using echocardiography to guide intra-arrest interventions are lacking, as are studies linking post-arrest hypotension treatments to survival or neurologic outcomes. (TTM) shows mixed results from trials like , with ongoing Bayesian analyses needed to clarify long-term neurologic benefits, while extracorporeal CPR (ECPR) outcomes, including transitions from conventional CPR and optimal post-arrest strategies, require comparative RCTs against standard CPR. Ventilation gaps persist regarding optimal rates, tidal volumes, and peak end-expiratory pressures during pediatric CPR, alongside associations between hypoxemia/hyperoxemia duration and post-arrest outcomes. For bradydysrhythmias, natural progression without CPR and comparative efficacy of interventions like epinephrine lack study, and pulse check accuracy via palpation versus ultrasound demands RCTs to minimize hands-off time. Neurological prognostication and seizure management represent further voids, with no pediatric studies on antiseizure medication efficacy for prophylaxis or treatment and their outcome associations, and limited validation of multimodal tools like biomarkers (e.g., neuron-specific enolase [NSE], S100B), electroencephalography (EEG), somatosensory evoked potentials (SSEPs), or neuroimaging thresholds (e.g., MRI apparent diffusion coefficient). Hyperkalemia-specific strategies, including potassium reduction timing and calcium's cardioprotective role in high-risk children (e.g., renal failure), also need elucidation. Research priorities emphasize pediatric-specific prospective studies and RCTs, including defibrillation energy doses' effects on myocardial damage, paddle/pad size optimization, blood pressure targets (e.g., systolic >10th percentile), and vasopressor side effects like epinephrine's long-term impacts. Priorities also include subgroup analyses for out-of-hospital (OHCA), single-ventricle , and cost-effectiveness of advanced (e.g., automated pupillometry, noninvasive cerebral oximetry), alongside of prognostication timing and definitions to enable reliable outcome . Addressing these through , as via ILCOR, is essential to reduce reliance on observational data and improve survival rates, which remain lower in than adults.

Criticisms and Limitations

Guideline Over-Reliance and Individualization Shortfalls

Criticisms of Pediatric Advanced Life Support (PALS) protocols highlight the risks of excessive dependence on standardized algorithms, which are derived from population-level evidence but may inadequately address the heterogeneity of pediatric patients, including variations in age, size, underlying , and . For instance, PALS algorithms primarily target children with structurally normal hearts, yet up to 15-20% of pediatric cardiac arrests occur in those with congenital heart disease, where standard compressions or sequences can exacerbate hemodynamic instability or fail to restore effectively. Rigid adherence in such cases has been associated with suboptimal outcomes, as it overlooks disease-specific factors like single-ventricle or post-operative complications, prompting calls for integrated specialist input over protocol-driven actions. Individualization shortfalls arise from the algorithmic emphasis on uniform interventions, such as fixed epinephrine dosing intervals or rates, which do not account for real-time physiologic feedback or patient-specific responses. A 2021 analysis from emphasized transitioning from "one-size-fits-all" CPR to tailored strategies incorporating metrics like coronary perfusion pressure and end-tidal CO2 waveforms to guide compression depth and rate adjustments, arguing that protocol rigidity contributes to persistent low survival rates (around 10-12% for out-of-hospital pediatric arrests). Simulations reveal frequent deviations from guidelines—up to 70% in some studies—often due to contextual demands like equipment limitations or atypical rhythms, with experienced providers demonstrating better judgment in adapting interventions, such as prioritizing volume resuscitation in over immediate . Even official updates acknowledge these limitations; the 2018 focused update on in pediatric arrest stressed that sequences must incorporate "individual patient and environment of care" considerations to avoid delays or inappropriate escalations. Over-reliance on tools like , mandated in for confirming , can lead to false negatives in low-output states common in prolonged pediatric arrests, resulting in unnecessary reattempts and treatment interruptions. Empirical data from registry studies indicate that while guideline concordance correlates with metrics, it does not consistently predict neurologically intact , underscoring the need for discretion informed by bedside over strict protocol fidelity. These shortfalls are compounded in resource-limited settings, where protocol deviations reflect practical necessities rather than errors, yet training emphasizes rote compliance, potentially eroding adaptive skills.

Implementation Barriers and Outcome Disparities

Several barriers hinder the effective implementation of () protocols, including low adherence to guideline bundles. For instance, complete compliance with the five-component bundle under PALS guidelines occurs in only 19% of cases. Diagnostic delays arise from challenges in recognizing early, exacerbated by age-variable vital sign norms, with such delays noted in 33% of fatal pediatric cases. Establishing intravenous access proves difficult in children with poor , impeding timely and delivery, which guidelines recommend within one hour. Provider-level obstacles include and deficits, particularly in resource-limited settings. In a study from , emergency physicians scored an average of 2.1 out of 11 on pre-training assessments of ACCM/ septic shock guidelines, with 86% uncomfortable titrating inotropes and 66% hesitant to intubate in the . Reluctance to initiate vasoactive agents early affects 38% of teams even after multiple fluid boluses, while systemic issues like staffing shortages and high workloads further reduce protocol fidelity. The rarity of pediatric arrests fosters decay, widening the gap between theoretical and performance during crises. Outcome disparities in pediatric resuscitation under frameworks manifest along sociodemographic lines, with pronounced effects in out-of-hospital cardiac arrest (OHCA). Black children experience OHCA at a rate over four times that of children (15.5 versus 3.8 per 100,000 population), accompanied by 26% lower adjusted odds of survival to discharge ( 0.74, 95% CI 0.59-0.92) and 36% lower odds of neurologically favorable survival ( 0.64, 95% CI 0.50-0.82). High-risk neighborhoods, indicative of low , show incidence rates of 11.6 per 100,000 and reduced survival odds compared to low-risk areas ( 1.45 for discharge survival favoring low-risk, 95% CI 1.12-1.87). In in-hospital (IHCA), racial and ethnic minorities face elevated mortality risks. Black children have 20% higher adjusted of death ( 1.20, 95% 1.08-1.34), while those treated at hospitals with over 30% populations encounter 50% increased mortality ( 1.50, 95% 1.17-1.92) relative to hospitals with fewer than 3% patients. children similarly show heightened mortality ( 1.16, 95% 1.04-1.30), though insurance payer type exhibits no significant association with IHCA outcomes ( 1.00 for public versus private). These inequities likely arise from differential access to equipped facilities, timely advanced interventions, and hospital-level resource variations rather than isolated protocol failures.

References

  1. [1]
    Part 8: Pediatric Advanced Life Support: 2025 American Heart Association and American Academy of Pediatrics Guidelines for Cardiopulmonary Resuscitation and Emergency Cardiovascular Care | Circulation
    Below is a merged summary of the integration of Pediatric Advanced Life Support (PALS) with Pediatric Basic Life Support (PBLS)/Basic CPR, consolidating all information from the provided segments into a single, comprehensive response. To maximize detail and clarity, I’ve organized key information into a table where appropriate, followed by a narrative summary that integrates additional details not suited for tabular format.
  2. [2]
    History of CPR | American Heart Association CPR & First Aid
    1988. In co-sponsorship with The American Academy of Pediatrics, the AHA introduces the first pediatric courses: pediatric BLS, pediatric advanced life support ...aha original logo. 1950s · Resusci Anne through the... · Dr Leonard Cobb. 1970s
  3. [3]
    PALS systematic approach algorithm - ACLS-Algorithms.com
    The PALS algorithm uses an initial impression of consciousness, breathing, and color, then the Evaluate-Identify-Intervene sequence to manage a critically ill ...Missing: key protocol
  4. [4]
    Part 4: Pediatric Basic and Advanced Life Support: 2020 American ...
    Oct 21, 2020 · 2019 American Heart Association Focused Update on Pediatric Advanced Life Support: An Update to the American Heart Association Guidelines ...
  5. [5]
    The Who, How, And Why Of Pediatric Advanced Life Support (PALS)
    Nov 1, 2009 · The first PALS manual was published in 1988 by the AHA and the first course was introduced that same year.<|separator|>
  6. [6]
    Pediatric Advanced Life Support: A Review of the AHA ... - AAFP
    Oct 15, 1999 · The first edition of the PALS manual was published in 1988, and the first PALS courses began that year. The PALS program underwent major ...
  7. [7]
    Pediatric advanced life support: a review of the AHA ... - PubMed
    Oct 15, 1999 · In 1988, the American Heart Association implemented the pediatric advanced life support (PALS) program. Major revisions to the program were made ...
  8. [8]
    Evolution of the Pediatric Advanced Life Support course - PubMed
    The Pediatric Advanced Life Support course, first released by the American Heart Association in 1988, has seen substantial growth and change over the past few ...Missing: AHA | Show results with:AHA
  9. [9]
    Recommended Guidelines for Uniform Reporting of Pediatric ...
    This statement is the product of a task force meeting held June 8, 1994, in Washington, DC, in conjunction with the First International Conference on ...
  10. [10]
    Clinical progress note: AHA ACLS/PALS/NRP updates and cardiac ...
    Feb 26, 2022 · The most important update to PALS is an increase in the delivery rate of breaths during cardiac arrest with an advanced airway from 1 breath every 6 s (10/min).
  11. [11]
    [PDF] Highlights of the 2020 American Heart Association's Guidelines for ...
    The 2020 guidelines include enhanced algorithms, re-emphasized early CPR, early epinephrine, and new opioid-related algorithms. A "Recovery" link was added to ...Missing: 1986 | Show results with:1986
  12. [12]
    https://newsroom.heart.org/news/updated-cpr-guidelines-released-for-pediatric-and-neonatal-emergency-care-and-resuscitation
  13. [13]
    Considerations on the Use of Neonatal and Pediatric Resuscitation ...
    Dec 18, 2023 · A notable difference between the neonatal and pediatric guidelines is the sequence of steps taken during CPR. The pediatric guidelines recommend ...
  14. [14]
    Part 8: Pediatric Advanced Life Support
    The chapter follows the Chain of Survival, beginning with prevention and preparedness to resuscitate, proceeding to early identification of cardiac arrest, and ...
  15. [15]
    https://cpr.heart.org/en/-/media/CPR-Files/Course-FAQs/2020-Course-FAQs/2020-PALS-ILT-FAQ_102120.pdf
  16. [16]
    Teaching teamwork competencies for resuscitation: EIT 6415 TFSR
    Dec 4, 2023 · The Task Force suggests that teaching teamwork competencies be included in BLS and all kinds of advanced life support training.
  17. [17]
    [PDF] Team Dynamics Debriefing Tool
    Use the table below to guide your debriefing. • Observe and record elements of team dynamics. • Identify 2 or 3 elements of team dynamics to discuss per ...
  18. [18]
    Scoping Review of Pediatric Early Warning Systems (PEWS) in ...
    Pediatric Early Warning Systems (PEWS) aim to identify hospitalized children at increased risk of deterioration by assigning a score based on vital signs ...
  19. [19]
    Use of Evidence-Based Vital Signs in Pediatric Early Warning Score ...
    Apr 10, 2023 · Evidence-based vital signs can improve PEWS sensitivity to identify unplanned ICU transfers and identify patients requiring ICU-specific interventions.Missing: efficacy | Show results with:efficacy
  20. [20]
    Validity and effectiveness of paediatric early warning ... - BMJ Open
    Overall, there was limited evidence of paediatric early warning system interventions leading to reductions in deterioration.
  21. [21]
    The Pediatric Early Warning System score: a severity of ... - PubMed
    The score is to preemptively identify hospitalized children who are likely to require resuscitation to treat cardiopulmonary arrest.
  22. [22]
    Development of the national Dutch PEWS - BMC Pediatrics
    Aug 7, 2023 · PEWS generally consist of a predefined set of vital parameters, such as heart rate, respiratory rate, body temperature, blood pressure, and ...Study Protocol · Delphi Round 2 And Survey · Discussion<|separator|>
  23. [23]
    Do paediatric early warning systems reduce mortality and critical ...
    We conducted a systematic review and meta-analysis to answer the question: Does the implementation of Paediatric Early Warning Systems (PEWS) in the hospital ...Missing: efficacy | Show results with:efficacy
  24. [24]
    Rapid response systems for paediatrics: Suggestions for optimal ...
    Feb 15, 2018 · ... preventing patient deterioration may not ... paediatric medical emergency team improves hospital response to deteriorating patients.
  25. [25]
    [PDF] Pediatric Rapid Response Teams - Lurie Children's
    Who can activate the team? Any staff member that either identifies the patient is showing signs of deterioration as dictated by the established criteria or has ...Missing: prevention | Show results with:prevention
  26. [26]
    evolution of pediatric rapid response teams and situational ... - NIH
    Ultimately, the goal to proactively identify patients at risk of deterioration may allow for prevention of clinical decline via appropriate and timely ...
  27. [27]
    [PDF] Highlights of the 2025 American Heart Association Guidelines for ...
    Recommendations for pediatrics and adults on the use of early warning systems and rapid response or ... deterioration can be effective in reduc- ing cardiac ...<|separator|>
  28. [28]
    Pediatric Rapid Response Systems: Identification and Treatment of ...
    Jan 10, 2015 · Many before and after studies and two systematic reviews have demonstrated the utility of EWS and RRT to reduce cardiopulmonary arrest and ...
  29. [29]
    Association of Hospitalization-Level Characteristics With Pediatric ...
    Oct 8, 2025 · Many institutions have implemented rapid response teams (RRTs) to assess deteriorating patients. Acute deterioration events are often used ...
  30. [30]
    [PDF] PALS-Vital-Signs.pdf - ACLS-Algorithms.com
    Infant. 100-180. Toddler. 98-140. Preschool. 80-120. School-age. 75-118. Adolescent. 60-100. Age. Systolic BP (mm Hg). Diastolic BP (mm Hg). MAP (mm Hg). Mean ...
  31. [31]
    Pediatric Vital Signs Reference Chart - PedsCases
    Jul 10, 2018 · Normal ranges of heart rate and respiratory rate in children from birth to 18 years: a systematic review of observational studies. Lancet.
  32. [32]
    [PDF] Pediatric Vital Signs - SF.gov
    Apr 1, 2025 · Heart Rate (beats/min) 1. Respiratory rate (breaths/min) 1. Age. Awake. Asleep. Age. Normal. Neonate (<28 days). 100-205. 90-160. Infant ...
  33. [33]
    [PDF] PEDIATRIC VITAL SIGNS REFERENCE CHART - PedsCases
    Heart Rate (beats/min). Respiratory Rate (breaths/min). Age. Awake. Asleep. Age. Normal. Neonate (<28 d). 100-205. 90-160. Infant (<1 y).
  34. [34]
    Primary assessment algorithm / Initial emergency ... - ACLS.net
    Mar 15, 2022 · The initial assessment includes color, breathing, and consciousness. If the child is unresponsive with only gasping and no breathing, then the ...
  35. [35]
    What is Included in the Secondary Assessment of PALS?
    Components of the Secondary Assessment · 1. Focused History (SAMPLE) · 2. Focused Physical Examination · 3. Diagnostic Tests · 4. Monitoring · 5. Interventions.
  36. [36]
    PALS Secondary Assessment – SAMPLE - ACLS.com
    The secondary assessment's broken down, really, into three parts. You have your focused history, your focused exam, and ongoing reassessment of the patient.Missing: advanced support
  37. [37]
    [PDF] Recognizing Respiratory Problems Flowchart ALS
    PALS: Identifying respiratory problems by severity. Progression of respiratory distress to respiratory failure*. Respiratory distress: open and maintainable.
  38. [38]
    (PALS) Respiratory Distress and Failure - ACLS-Algorithms.com
    In the pediatric patient, heart rate, rhythm, and blood pressure can be early indicators of how your interventions are affecting the patient. Therefore, it is ...
  39. [39]
    Advanced Airway Interventions in Pediatric Cardiac Arrest: PLS P1 ...
    Dec 5, 2023 · This CoSTR is a draft version prepared by ILCOR, with the purpose to allow the public to comment and is labeled “Draft for Public Comment".
  40. [40]
    Pediatric airway management - PMC - NIH
    This review focuses on assessment and management of pediatric airway and highlights the unique challenges encountered in children.
  41. [41]
    Success and complications by team composition for prehospital ...
    Apr 15, 2020 · Physician teams had higher first-pass success rate (91%, 95% CI 86–95%) than non-physicians with (75%, 95% CI 69–81%) and without (55%, 95% CI ...
  42. [42]
    Effect of Out-of-Hospital Pediatric Endotracheal Intubation on ...
    Aijian et al reported a 50% rate of successful ETI in children younger than 1 year of age, and Losek et al reported a 54% rate of successful ETI in children 18 ...
  43. [43]
    Airway Complications in Intubated Versus Laryngeal Mask Airway ...
    However, intubation may be associated with complications including failure of placement, trauma to the oral or nasal anatomy, bronchospasm, obstruction, ...
  44. [44]
    Shock in Pediatrics: Background, Etiology, Pathophysiology
    Oct 2, 2025 · The clinical state of shock is diagnosed based on vital signs, physical examination, and laboratory data, although its recognition in pediatric ...Background · Etiology · PathophysiologyMissing: assessment | Show results with:assessment<|separator|>
  45. [45]
    Surviving Sepsis Campaign Pediatric Guidelines
    We suggest using balanced/buffered crystalloids, rather than 0.9% saline, for the initial resuscitation of children with septic shock or other sepsis-associated ...
  46. [46]
    (PALS Review) Cardiogenic Shock - ACLS-Algorithms.com
    This can be achieved by support with intubation and mechanical ventilation, maintenance of a normal temperature, and patient sedation. Pediatric cardiogenic ...
  47. [47]
    Experts' recommendations for the management of cardiogenic shock ...
    Feb 16, 2016 · Children with cardiogenic shock are vulnerable and should be followed regularly by intensivist cardiologists and pediatricians. The experts ...
  48. [48]
    Shock in Pediatrics Treatment & Management - Medscape Reference
    Oct 2, 2025 · Previous guidelines highlighted the use of early goal-directed therapy (EGDT) targeting rapid fluid resuscitation with up to 40-60 mL/kg ...Approach Considerations · Initial Resuscitation · Fluid Resuscitation
  49. [49]
    (PALS Review) Obstructive Shock - ACLS-Algorithms.com
    The definitive treatment for obstructive shock caused by tension pneumothorax is needle decompression and chest tube placement to the affected area. Cardiac ...
  50. [50]
    Cardiopulmonary Arrest in Children - StatPearls - NCBI Bookshelf
    Jun 21, 2025 · Common causative agents include tricyclic antidepressants, calcium channel blockers, β-blockers, and digoxin. Overdose of street drugs such as ...Etiology · Pathophysiology · Treatment / Management · Differential Diagnosis
  51. [51]
    Incidence, Causes, and Survival Trends From Cardiovascular ...
    Sep 11, 2012 · The most common causes of OHCA were congenital abnormalities in those 0 to 2 years of age (84.0%) and 3 to 13 years of age (21%), presumed ...
  52. [52]
    Incidence, Causes, and Survival Trends From Cardiovascular ...
    Aug 10, 2012 · The most common causes of OHCA were congenital abnormalities in those 0 to 2 years of age (84.0%) and 3 to 13 years of age (21%), presumed ...
  53. [53]
    Pediatric advanced life support (PALS) algorithms - ACLS.net
    Nov 5, 2024 · View the PALS case algorithms and scenarios in graphic and text format, providing comprehensive guidance for pediatric advanced life ...Pediatric bradycardia algorithm · Pediatric tachycardia algorithm · Cardiac ArrestMissing: confirming | Show results with:confirming
  54. [54]
    Pediatric In-Hospital Cardiac Arrest and Cardiopulmonary ...
    Although IHCA occurrence is frequently associated with the progression of underlying disease processes, such as shock and respiratory failure, common causes of ...<|separator|>
  55. [55]
    Cardiac Arrest in Children and Young Adults | Circulation
    Primary electric disorders and cardiomyopathies, associated with the best survival, are the 2 most common cardiac causes. Additionally, cardiac arrest ...
  56. [56]
    Sudden Cardiac Arrest in the Paediatric Population - PMC - NIH
    The most common cause of sudden unexpected death (SUD) in those aged 1-35 years is arrhythmic syndromes. These conditions are largely heritable and include ...
  57. [57]
    Reversible causes of pediatric cardiac arrest | ACLS-Algorithms.com
    Learn to identify reversible causes of pediatric cardiac arrest by understanding progressive signs. symtoms and collecting illness history. (PALS Hs and Ts)
  58. [58]
    Part 6: Pediatric Basic Life Support: 2025 American Heart Association and American Academy of Pediatrics Guidelines for Cardiopulmonary Resuscitation and Emergency Cardiovascular Care | Circulation
    Summary of each segment:
  59. [59]
    2025 Algorithms | American Heart Association CPR & First Aid
    2025 American Heart Association Guidelines for Cardiopulmonary Resuscitation and Emergency Cardiovascular Care. Neonatal Resuscitation; Pediatric Basic Life ...Missing: components | Show results with:components
  60. [60]
    [PDF] Pediatric Cardiac Arrest Algorithm
    Push hard (≥ 1/3 chest depth). • Push fast: 100-120/min. • Allow full chest recoil. • Minimize interruptions in compressions.
  61. [61]
    https://publications.aap.org/aapnews/news/33628/Pediatric-life-support-resuscitation-guideline
  62. [62]
    [PDF] Pediatric Bradycardia With a Pulse Algorithm
    Pediatric Bradycardia With a Pulse Algorithm. Text in cascading boxes describes the actions that providers should perform in sequence when treating pediatric.<|control11|><|separator|>
  63. [63]
    https://cpr.heart.org/-/media/CPR-Files/CPR-Guidelines-Files/Algorithms/AlgorithmPALS_Tachycardia_200618.pdf
  64. [64]
    Pediatric Postresuscitation Management - StatPearls - NCBI Bookshelf
    Jun 5, 2023 · A post-arrest reevaluation includes assessing the adequacy of pulses, perfusion, blood pressure, and adequacy of oxygenation and ventilation.Missing: life | Show results with:life
  65. [65]
    Therapeutic Hypothermia after Out-of-Hospital Cardiac Arrest in ...
    Apr 25, 2015 · In observational studies, therapeutic hypothermia has not been associated with improved outcomes in children after cardiac arrest. Moreover, one ...
  66. [66]
    Therapeutic Hypothermia after In-Hospital Cardiac Arrest in Children
    Jan 26, 2017 · The THAPCA-IH trial evaluated the efficacy of therapeutic hypothermia (target temperature, 33.0°C) and therapeutic normothermia (target ...
  67. [67]
    Pediatric Post–Cardiac Arrest Care: A Scientific Statement From the ...
    Jun 27, 2019 · The 2010 AHA PALS guidelines recommended prompt arterial blood gas analysis as soon as possible after ROSC and within 10 to 15 minutes of ...
  68. [68]
    Association of Early Postresuscitation Hypotension With Survival to ...
    Dec 11, 2017 · In this secondary analysis of the THAPCA trial, 26.7% of participants had hypotension within 6 hours of the study intervention. Early post– ...
  69. [69]
    Neuromonitoring after Pediatric Cardiac Arrest: Cerebral Physiology ...
    We provide an in-depth review of the neuromonitoring modalities that measure cerebral perfusion, oxygenation, and function, as well as neuroimaging, serum ...
  70. [70]
    Neurological Prognostication in Children after Cardiac Arrest - PMC
    The AHA Pediatric Advanced Life Support 2015 guidelines state that EEG recordings done within 7 days after ROSC can be helpful in prognostication at time of ...
  71. [71]
    PALS Course Options | American Heart Association CPR & First Aid
    PALS is intended for healthcare professionals who respond to emergencies in infants and children and for personnel in emergency response, emergency medicine, ...Missing: definition | Show results with:definition<|separator|>
  72. [72]
    Pediatric Advanced Life Support (PALS) and Simulation
    PALS certification course requires participation in roughly14-hour course, typically divided into 2 days, and to pass written test and psychomotor skills test.Missing: structure | Show results with:structure
  73. [73]
    Pediatric Advanced Life Support (PALS) Course
    The AHA's Pediatric Advanced Life Support (PALS) course is a classroom, Instructor-led course which uses a series of videos and simulated pediatric emergencies.Missing: definition | Show results with:definition
  74. [74]
    AHA PALS Courses | American Heart Association - ShowMeCPR
    Students must hold a Current American Heart Association BLS for Healthcare Provider CPR card to take the course. If expired, you must complete the BLS for ...
  75. [75]
    [PDF] Pediatric Advanced Life Support - UNC Medical Center
    The PALS course includes three learning stations: Respiratory Emergencies, Shock and Fluid Resuscitation, and Cardiac Emergencies, using a scenario-based ...
  76. [76]
    [PDF] FAQ-PALS Classroom Course_8-31-16
    The PALS course is a classroom, video-based, instructor-led course using simulated pediatric emergencies to reinforce concepts of pediatric assessment and ...Missing: structure components
  77. [77]
    Impact of Simulation Training on Time to Initiation ... - PubMed Central
    A simulation-based educational intervention significantly reduced time to initiation of CPR for first-year pediatrics residents. Residents improved their time ...
  78. [78]
    Effectiveness of high-fidelity clinical simulation in cardiopulmonary ...
    High-fidelity simulation, compared to traditional training, shows significant improvements in depth of compressions and theoretical knowledge.
  79. [79]
    Study Details | NCT00562744 | Effect of Simulation on PALS Training
    Nov 22, 2007 · We hypothesize that mock resuscitation exercises performed by pediatric housestaff on a patient simulator will result in improved performance on ...
  80. [80]
    The role of simulation in teaching pediatric resuscitation
    Simulation-based training is an effective modality for teaching pediatric resuscitation concepts. Current literature has revealed some research gaps in ...
  81. [81]
    Educational efficacy of high-fidelity simulation in neonatal ...
    Aug 29, 2019 · The use of high-fidelity simulation for pediatric advanced life support (PALS) training was proven beneficial for improved skill performance at ...
  82. [82]
    Observational Study on the Effect of Duration from Pediatric ... - NIH
    PALS performance skills were poor in pediatric interns after PALS certification and was unchanged regardless of when training occurred.
  83. [83]
    1552: PROSPECTIVE STUDY OF PEDIATRIC RESIDENTS' PALS...
    Conclusions: In pediatric residents, PALS skill retention was poor even within a period of 1-3 months after traditional PALS training. Pediatric ...Missing: studies | Show results with:studies
  84. [84]
    Retention of Pediatric Advanced Life Support (PALS) course concepts
    The purpose of this study was to measure, in a population of experienced state-certified paramedics, the decline of Pediatric Advanced Life Support (PALS) ...
  85. [85]
    Is Pediatric Advanced Life Support Certification Every 2 Years ...
    Sep 16, 2019 · However, studies evaluating the effects of time on PALS knowledge retention are scarce. To our knowledge, ours is the only study to use AHA PALS ...
  86. [86]
    Longitudinal effect of high frequency training on CPR performance ...
    Pediatric cardiac arrest represents a combination of a high-stakes clinical event with infrequent occurrence, making skill maintenance a particular challenge.
  87. [87]
    Bridging the knowledge-resuscitation gap for children: Still a long ...
    The environment is extremely stressful. The stress of 'life and death' during resuscitation is unavoidable, and routine tasks can become more complex during an ...
  88. [88]
    Performance of Advanced Resuscitation Skills by Pediatric Housestaff
    To our knowledge, there have been no studies to evaluate performance of advanced pediatric cardiopulmonary resuscitation after formal and informal training.
  89. [89]
    Performance and skills retention in in-hospital trained pediatric ...
    Skills decayed over time despite two refresher sessions with feedback. Introduction. Delivering high-quality cardiopulmonary resuscitation (CPR) is an important ...<|separator|>
  90. [90]
    Retention of Critical Procedural Skills After Simulation Training: A ...
    Sep 25, 2020 · We hypothesized that there would be a substantial decay in skill performance as early as 3 months after simulation.<|separator|>
  91. [91]
    Trends in Survival After Pediatric In-Hospital Cardiac Arrest in the ...
    Sep 23, 2019 · For pulseless cardiac arrests, survival was 19% (95% CI, 11%–29%) in 2000 and 38% (95% CI, 34%–43%) in 2018, with an absolute change of 0.67% ( ...
  92. [92]
    Pediatric Life Support: 2025 International Liaison Committee on Resuscitation Consensus on Science With Treatment Recommendations | Circulation
    Summary of each segment:
  93. [93]
    Cardiopulmonary Resuscitation in Infants and Children With Cardiac ...
    Apr 23, 2018 · Pediatric basic life support and advanced life support guidelines focus on delivering high-quality resuscitation in children with normal hearts.
  94. [94]
    Cardiac Arrest Research Leading the Way to Individualized CPR
    Aug 4, 2021 · Children's Hospital of Philadelphia (CHOP) investigators are moving beyond the one-size-fits-all cardiopulmonary resuscitation (CPR) guidelines.Missing: adherence | Show results with:adherence
  95. [95]
    Adherence to guideline recommendations in the management of ...
    Pediatric cardiac arrest is a rare emergency with associated high mortality. Its management is challenging and deviations from guidelines can affect ...
  96. [96]
    Adherence to guideline recommendations in the management of ...
    Aug 1, 2022 · Deviations from guidelines, although measured by means of a nonvalidated tool, were frequent in the management of a pediatric cardiac arrest ...Missing: limitations rigid
  97. [97]
    2018 American Heart Association Focused Update on Pediatric ...
    Nov 5, 2018 · The sequence of interventions recommended in the current PALS algorithm should consider the individual patient and the environment of care.
  98. [98]
    Pitfalls of overreliance on capnography and disregard of visual ...
    Overreliance on capnography can lead to false negatives, unnecessary repeated intubations, and delays in treatment, as capnography is not infallible.
  99. [99]
    Adherence to PALS Sepsis Guidelines and Hospital Length of Stay
    Aug 1, 2012 · Eighty-eight patients (70%) received an antibiotic within 60 minutes. Perfect adherence to the algorithm bundle was observed for 19% of patients ...Missing: individual | Show results with:individual
  100. [100]
    Barriers and Proposed Solutions to a Successful Implementation of ...
    Nov 10, 2021 · Barriers are: absence of a written protocol, parental knowledge, early diagnosis by healthcare professionals, venous access, availability of antimicrobials and ...
  101. [101]
    GAP between knowledge and skills for the implementation of the ...
    In view of the lack of skills and suboptimal knowledge, the ACCM/PALS sepsis guidelines may be inappropriate in its current format in the Indian setting.
  102. [102]
    Abstract 12704: Racial, Ethnic, and Socioeconomic Disparities in ...
    Nov 6, 2023 · Black children have over four times the incidence of OHCA compared to White and Hispanic children and significantly worse survival outcomes.Missing: life | Show results with:life
  103. [103]
    Race, Ethnicity, Insurance Payer, and Pediatric Cardiac Arrest Survival
    Sep 10, 2025 · Children receiving CPR at hospitals treating the highest proportion of Black patients had 50% higher odds of in-hospital mortality than children ...Missing: advanced | Show results with:advanced