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To Sedate or Not to Sedate: Key Principles of Pediatric Anesthesia Erin Rosenberg, MD Assistant Professor of Anesthesiology Emory University Children’s Healthcare of Atlanta • No financial disclosures Sedation outside of the Operating Room • Increased availability of short-acting sedatives • Accurate monitoring • Improved training programs Office Anesthesia Deaths OMSNIC 2000-2014 • Exposure • 641 IVS per OMS per year • 71%GA • 29% Moderate sedation • Mortality 121 deaths (office) • 1/353,657 procedures • 1/531 OMS per year • 1/18 OMS in a 30 year career Lecture Objectives • • • • • • • Pediatric Pre-op Assessment Premedication/sedatives Children with URIs Review key airway differences between children and adults Recognize the difficult airway Discuss the role of drugs in airway management Describe the management of the uncomplicated airway • Bag/mask or direct laryngoscopy • Become familiar with alternative techniques for the difficult airway • Syndromes that should make you sweat • Children with OSA- to sedate or not to sedate Goals of Sedation and Analgesia • • • • Maintain patient safety and welfare Minimize physical pain and discomfort Control Anxiety, minimize psychological trauma, maximize amnesia Control behavior and movement to allow safe performance of procedures Office Based Anesthesia • Advantages: • Patient convenience • Surgeon convenience • • • • Easier scheduling Staff consistency Efficiency Lower nosocomial infections rates • Cost containment when compared to hospital • Patient satisfaction (perceive greater attention and privacy) • Good patient for office based procedures • Ideally ASA I or II Office Based Anesthesia • Disadvantages • Safety • Office facility resources • Anesthetic technique • Regulation • Poor Candidates • • • • • • • Severe obesity Severe OSA Potentially difficult airway Aspiration risk MH risk Previous adverse outcomes with anesthesia Previous adverse events with common sedation medications Relative Contraindications • No absolute contraindications Why does sedation fail? • Observational study of 606 pediatric patients who underwent deep sedation by experienced practitioners • 83 failed sedations • • • • • Presence of URI History of sleep apnea or snoring ASA 3 Older age Obesity Pre-operative evaluation of child • Medical history • • • • • Review of organ systems Medications Previous surgical and hospital experiences Last oral intake Pregnancy testing • Family History • MH history, pseudocholinesterse deficiency, muscular dystrophy, sickle cell disease, bleeding tendencies, drug addiction Pre-operative evaluation of child • Preoperative Fasting Recommendations • • • • • Clear liquids-2 hours Breast milk- 4 hours Infant formula- 6 hours Solids (fatty or fried foods)- 8 hours Chewing gum: no delay if discarded and not swallowed • If aspiration does occur, morbidity and mortality are rare • 0-0.2:10,000 • Most ASA 1 or 2 patients who aspirate clear gastric contents generally have minimal or no sequelae • Clinical signs usually apparent within 2 hours of regurgitation Premedication • Objectives • • • • • • • Allay anxiety Block vagal reflexes Reduce airway secretions Produce amnesia Provide prophylaxis against pulmonary aspiration of gastric contents Facilitate induction of anesthesia Provide analgesia Premedication • Route of administration • Oral, nasal, rectal, buccal, IV, IM • Unless a large volume is ingested, oral premed does not increase risk of aspiration • Children report receiving a needle puncture was their worst experience in the hospital Medications • Commonly used premeds • • • • • Benzodiazepines Ketamine Alpha2 adrenergic agonist Opioids Antihistamines Benzodiazepines • Midazolam • Anxiolysis, anterograde amnesia, sedation • Short acting • Elimination half-life of about 2 hours • Can be administered orally, IV, IM, intranasally, rectally • 0.025-0.1 mg/kg IV • 0.1-0.2 mg/kg IM • 0.25-0.75 mg/kg orally • 0.2 mg/kg nasally • Can decrease propofol requirements by up to 33% • Time to discharge was delayed • Memory impaired within 10 minutes, anxiolytic effects apparent after 15 minutes • Adverse behavioral changes/agitation can be seen • Can cause hiccups-unknown etiology • Diazepam/Lorazepam • Primarily used to sedate older children • Slower onset of action and longer duration of action Opioids • Useful in children who have pain preoperatively • Beware of the side effects: nausea/vomiting, respiratory depression, sedation and dysphoria • Should be monitored continuously after administration • Morphine, Meperidine, Fentanyl • Codeine • Undergo demethylation in liver to produce morphine • 5-10% of children lack the cytochrome isoenzyme required for conversion Ketamine • Phencyclidine derivative • Produces sedation and analgesia while preserving upper airway muscular tone and respiratory drive • May be administered IV, IM, orally, nasally and rectal • IM dose: 2mg/kg • Oral dose: 5-7 mg/kg • Nasal dose: 6 mg/kg (need preservative free) • Disadvantages • • • • Increased secretions Nystagmus Increased incidence of postop emesis Hallucinations, nightmares, delirium Less Commonly used • Clonidine • • • • • Alpha2 agonist Dose-related sedation No respiratory depression Shown to reduce MAC of sevoflurane Analgesic properties • Antihistamines • Hydroxyzine, diphenhydramine • Sedative effects are variable ASA Classifications • • • • • • ASA I: healthy, no disease outside surgical process ASA II: mild to moderate systemic disease, medically well controlled ASA III: severe systemic disease that results in functional limitation ASA IV: severe incapacitating disease process that is a constant threat to life ASA V: moribund patient not expected to survive 24 hours ASA VI: brain dead patient being maintained for harvesting of organs Upper Respiratory Infections • 20-30% of all children have a runny nose during a significant part of the year • Must rely on H&P and physical exam • Complications: • Bronchospasm • Laryngospasm • Desaturation event • Predictors of adverse anesthetic events • • • • • • Airway manipulation Parent states the child has a “cold” Nasal congestion Passive smoking Sputum production/copious secretions Hx of reactive airway diseasae • Best evidence available suggests that a child with a mild URI that is not of acute onset may be safely anesthetized for minor surgical procedures • If endotracheal intubation is required, then risk of respiratory events increase URI • When to postpone? • • • • • • • • • Fever (>38.5) Recent onset of purulent nasal discharge “wet” cough Lethargic or ill-appearing Wheezing or rales Child <1 year, or preemie Major operation Endotracheal tube required History of asthma or reactive airway disease • How long to wait to reschedule? • Risk for respiratory complications can last 4-6 weeks • Most anesthesiologists wait 3-4 weeks Case- Laryngospasm • A 6 year old boy (20 kg body weight) was taken to the operating room, without premedication, for urgent surgery of an abscessed tooth with subsequent facial cellulitis. • Past medical history was unremarkable except for an episode of upper respiratory tract infection 4 weeks ago. The mother volunteered that he was exposed to passive smoking in the home. He had been fasting for the past 6 h. • Preoperative evaluation: SBP 85/50 mmHg, heart rate 115 beats/min, pulse oximetry [SpO2] 99% on room air). • The procedure was expected to be very short, and general anesthesia with inhalational induction and maintenance, but without tracheal intubation, was planned. Anesthesia was induced by a resident under the direct supervision of a senior anesthesiologist with inhaled sevoflurane in a 50/50% (5 l/min) mixture of oxygen and nitrous oxide. Two min after loss of eyelash reflex, a first episode of airway obstruction with inspiratory stridor and suprasternal retraction was successfully managed by jaw thrust and manual positive pressure ventilation. An IV line was obtained at 11:15 PM, while the child was manually ventilated. Anesthesia was then maintained by facemask with 2.0% expired sevoflurane in a mixture of oxygen and nitrous oxide 50/50%. 11:23 PM, an inspiratory stridulous noise was noted again. • Manual facemask ventilation became difficult with an increased resistance to insufflation and SpO2dropped rapidly from 98% to 78%, associated with a decrease in heart rate from 115 to 65 beats/min. • A new episode of laryngospasm was immediately suspected. Despite a jaw thrust maneuver, positive pressure ventilation with 100% O2, and administration of two bolus doses (5 mg) of IV propofol (0.6 mg/kg), the obstruction was not relieved and SpO2decreased to 52%. A 0.2-mg IV bolus dose of atropine was injected and IV succinylcholine was given at a dose of 16 mg, followed by tracheal intubation. Thereafter, surgery was quickly completed, while tracheal extubation and postoperative recovery were uneventful. Laryngospasm • Sustained closure of the vocal cords by constriction of the intrinsic muscles of the larynx • Children are more prone than adults (17.4/1,000 vs 8.7/1,000) • Risk Factors • • • • • Age URI Smoke exposure Procedure- highest incidence in procedures involving the pharynx and larynx Insufficient depth of anesthesia • Signs • Inspiratory stridor or airway obstruction • Increased respiratory effort/retractions • Paradoxical chest and abdominal movements Laryngospasm • Treatment • • • • • Recognition 100% oxygen Deepen the anesthesia (propofol) Positive pressure ventilation Neuromuscular blocking agents • Succinylcholine- 0.2-2 mg/kg IV or 4-5 mg/kg IM • Rocuronium- 0.7-1 mg/kg IV or 1-2 mg/kg IM • Morbidity • • • • Hypoxia Bradycardia Negative pressure pulmonary edema Cardiac arrest Case Scenario: Perianesthetic Management of Laryngospasm in Children Anesthesiology. 2012;116(2):458-471. doi:10.1097/ALN.0b013e318242aae9 Bronchospasm • May appear as an entity in its own right or be a component of another problem such as anaphylaxis • Majority take place during induction and maintenance of anesthesia • Suspect Bronchospasm • Wheezing on auscultation • Slow or incomplete expiration on inspection • Change in end tidal carbon dioxide waveform • • Upsloping waveform Decreased or absent waveform • Decreased tidal volume • High inspiratory pressures • Decreasing oxygen saturation • Management • • • • • • Administration of 100% Deepen the anesthesia Beta2 agonist (albuterol) via MDI Volatile anesthetics Epinephrine NMBAs Respiratory Failure • The primary diagnosis in almost 50% of admissions to pediatric intensive care unit • Almost all of pediatric codes are due to respiratory origin • 80% of pediatric cardiopulmonary arrest are primarily due to respiratory distress • Majority of cardiopulmonary arrest occur at <1 year old • In a retrospective review of 11,219 pediatric procedures, the risk of difficult laryngoscopy was estimated as 1.35%. The risk was found to be higher in neonates and infants, children who are underweight, ASA physical status III and IV, or have Mallampati score III and IV.[1] However, the reliability of the Mallampati score in predicting difficult airway management in the pediatric population has been questioned Airway Management • Provide airway management without knowing the full extent injuries or medical conditions • I.e. Full stomach, shock, elevated ICP, cardiovascular disease • Little advanced warning…limited opportunity to mobilize specialized personnel and equipment • Must choose strategies that are likely to succeed with limited complications What can you do to promote optimal outcomes?…Stay Out of Trouble! • Understand key differences between children and adults • • • • Anatomic Physiologic Pharmacodynamic Autonomic differences • Good preparation • Difficult airway recognition • Familiarity with the back-plans Key Anatomic Differences Intants/Children vs. Adults • Proportionally larger head and occiput • Pushes head into a flexed position causing airway obstruction when child on his back • Overcome by placing towel under shoulders • Relatively large tongue and small nares • Hypertrophied lymph tissue • Short trachea • Greater potential for endobronchial intubation Key Anatomic Differences Intants/Children vs. Adults • Long floppy epiglottis • Larynx appears more anterior and cephalad • higher in the neck C4 vs. C6 • Cricoid ring is narrowest part of airway (vs. glottis in adults) • Airway narrower • Increasing airway resistance • Dalal, Etal. Pediatric Laryngeal Dimensions: An Age-Based Analysis • Looked at 135 children aged 6mos-13 yrs • video bronchoscopic technique • measured laryngeal dimensions, • cross- sectional area, anteroposterior and transverse diameters at the level of the glottis and the cricoid Key Respiratory Differences Infants/Children vs. Adults • Incomplete alveolar development • Increased chest wall compliance • Decreased lung elastic recoil (lower lung compliance) • Horizontal angulation of the ribs inefficient inspiration • Diaphragm (major muscle of ventilation) • 25% of slow twitch/fatigue resistant type I fibers (vs. 55% in the adult) • Predisposes to fatigue • Bulky abdominal contents hinders diaphragmatic excursion Oxygen Consumption and Metabolic Rate • Increased VO2 • Low FRC • Infants and Children are Predisposed to HYPOXIA Indications for Intubation • inability to maintain airway patency • inability to protect the airway against aspiration • ventilatory compromise • failure to adequately oxygenate pulmonary capillary blood • anticipation of a deteriorating course that will eventually lead to the inability to maintain airway patency or protection Incidence and predictors of difficult laryngoscopy • Heinrich, etal 2012: retrospective study • Overall incidence of difficult laryngoscopy was 1.3% • • • • <1 yr old incidence was higher (4.7 vs 0.7%) Higher mallampati class Lower BMI Oromaxillofacial surgery, cardiac surgery Recognizing the difficult airway Airway Examination • Evaluate the mouth • Assess opening, loose teeth?,protruding upper teeth, high arched palate, TMJ problems • Evaluate the tongue • Macroglossia- absolute or relative tongue enlargement • prominent feature of Downs and Beckwith-Wideman syndromes • Infiltration or crowding of the tongue and airway structures • Muccopolysaccharidosis, morbid obesity, cystic hygroma, edema, cellulitis • Neck examination • masses, mobility, and deviation of the trachea • Previous tracheostomy scar • identify cricothyroid membrane for possible use in unexpected airway loss Airway Examination • Mallampati Test • Thyromental distance • Extension at the Atlantoocciptal joint Oropharyngeal Examination Mallampati Classification • Class I = visualization of the soft palate, fauces, uvula, anterior and posterior pillars • Class II = visualization of the soft palate, fauces and uvula • Class III = visualization of the soft palate and the base of the uvula • Class IV = soft palate is not visible at all. Airway Examination Extension at the Atlantoocciptal joint • Inability to extend neck predictor of difficult intubation and ventilation • Trauma • Congenital cervical spine abnormalities • • • • • Trisomy 21 Goldenhar syndrome Klippel-Feil syndrome Juvenile rheumatoid arthritis Prior cervical spine fixation Airway Examination Thyromental Distance • Indicator of mandibular space • Distance from thyroid cartilage to the chin • > 1.5 cm infants • Short mandible must compress more tongue and oral structures into smaller space (Treacher Collins and Pierre Robin syndromes) • may predict difficulty with mask ventilation Factors to consider when deciding on an Airway Strategy • Degree of Airway abnormality • Prior history of airway difficulty • Ability of patient to physiologically tolerate proposed airway procedure Monitoring • • • • EKG Pulse ox Noninvasive blood pressure EtCO2 • Standard of care- detects esophageal intubation • False negative • Circulatory arrest • Severe bronchospasm • Mucus plug or kinking of the ETT Capnography January 1, 2014 the use of capnography was mandated by AAOMS for all anesthesia procedures from moderate sedation to general anesthesia Capnography • Refers to the noninvasive measurement of the partial pressure of carbon dioxide in exhaled breath expressed as the CO2 over time • Represented by waveform or capnogram • Four phases • • • • Phase 1: beginning of exhalation Phase 2: rise in CO2 in the breath stream as it reaches the upper airway Phase 3: Maximum CO2 concentration at the end of the tidal breath Phase 4: inspiratory cycle Capnography • Clinical Applications in the Intubated Patient • Verify ETT placement • Gauge the effectiveness of resuscitation and prognosis during cardiac arrest • Indicator of return of spontaneous circulation during chest compressions • When the heart restarts, dramatic increase in cardiac output and EtCO2 • Determining adequacy of ventilation • Titrate levels in patients with increased ICP Capnography Capnography • Clinical Applications for the Spontaneously Breathing Patient • Determining the adequacy of ventilation in patients that are undergoing sedation • Obtunded or unconscious • Performing rapid assessment of critically ill or seizing patient • Determining response to treatment in acute respiratory distress • Detecting hypoventilation and hyperventilation Preparing for intubation • M = Machine (i.e. Ventilator) • S = Suction • M = Monitors • A = Airway supplies (tubes, stylet, nasal trumpets, oral airways, LMAs, etc.) • I = IV • D = Drugs (non sedation and emergency) • E = Emergency supplies (bag, epi, atropine, etc.) • N = Narcotics (sedatives, etc.) • S = Stethoscope Intubation equipment • Laryngoscope blades of all sizes, styles • Endotracheal tubes of all sizes (cuffed and uncuffed) • CO2 detector • Different size facemasks • All sizes of naso and orophayrngeal airways • Suction Equipment and catheters • Self inflating resuscitation bags • Endotracheal tube guides • Semi-rigid intubating stylet Choosing an Endotracheal tube • Endotracheal Tubes • Variety of formulas • Most popular is Cole’s formula • 16+ Age (years) 4 • Can also use the child’s fifth finger to approximate tracheal diameter Choosing an Endotracheal Tube • Uncuffed vs. Cuffed ETTs • Advantages of cuffed ETT • Reduce risk of aspiration • Allow modern ventilators to monitor lung function more effectively by preventing air leak • Tidal volume • Lung compliance • Less often require tube exchange due to too small of a size • Reducing risk of procedural complications i.e.. Dental injury, laryngospasm, vocal cord injury, tracheal lacerations • Reduce environmental contamination with anesthetic gas Choosing an Endotracheal Tube • Arguments in favor of uncuffed ETTs • Unique laryngeal anatomy in children allows for adequate tube fit that prevents aspiration without a cuff • Cuffs increase external tube diameter and necessitate use of tubes with smaller internal diameter • Creates greater airway resistance • Cuff pressures must be carefully monitored to prevent overinflation injury • Cuff abrasion injury/ischemia of the airway mucosa may lead to tracheal injury and stenosis • Margin of safety for avoiding mainstem bronchus is greater for uncuffed than cuffed ETT • Due to cuff proximity to the distal end of the tube “DRUGS” • Attenuate reflex autonomic responses to airway manipulation • Render patient unconscious and amnesic • Neuromuscular blockade provides optimal laryngeal visualization and prevents coughing Premedication “LOAD” • Lidocaine • Suppresses reflex autonomic and airway responses to laryngoscopy and endotracheal intubation • Direct anesthetic properties on the CNS • Lessen increase in ICP and IOP • 1-2 mg/kg IV 2-3 minutes before laryngoscopy • Can be nebulized or sprayed onto airway structures or into the trachea • keep total dose below toxic limit 5 mg/kg Premedication “LOAD” • Opioids and Benzodiazepines • Opioids (fentanyl 1-2 mcg/kg) • Produce sedation and blunt response to noxious stimuli • Benzodiazepines (midazolam 0.05-0.1mg/kg) • Induce sedation and amnesia • • • • Adjunct therapies for amnesia and analgesia with other induction drugs Can be used for conscious sedation Synergistic respiratory depression results from concomitant administration Titrate slowly Premedication “LOAD” • Anticholinergics • Glycopyrrolate, scopolamine, atropine • Tachycardia, drying of oral secretions, amnesia (scopolamine) • Blunts neonatal bradycardic response to hypoxia, laryngoscopy, succinylcholine • Atropine • 0.02mg/kg iv (min dose 0.1mg) or 0.04mg/kg IM • Glycopyrrolate • To dry airway secretions 0.01mg/kg IM/IV 30 min prior to airway management Premedication “LOAD” • Defasiculating doses of non-depolarizing NMB drugs • “priming doses” • Attenuate fasiculations from succinylcholine • Can see muscle weakness/breathing difficulties from this small dose Neuromuscular Blockers • Provides muscle relaxation to facilitate endotracheal intubation • Two classes: depolarizing and nondepolarizing • Succinylcholine vs. Rocuronium • Drugs differ in their onset times, duration of action, side effect profile, routes of metabolism Succinylcholine • Depolarizing NMB produces reliable intubating conditions in shortest amount of time • Muscle fasiculations and increased salivation • Dose: 1-1.5 mg/kg iv (4-5mg/kg IM) produces intubating conditions in 30-45 seconds (4-6 min after IM dose) • Recovery: 5-7 minutes • Ideal for RSI and the difficult airway Succinylcholine “Relative” Contraindications • Hyperkalemia • Myopathy • History of malignant hyperthermia • Denervating injury or disease process (>2-3 d, lasting for 3-6 months or longer) • Recent burns (more than 24h and less than 6 mo since injury) • Crush injury • Abdominal abscesses • Arrhythmias • Increased intracranial pressure • Increased intraocular pressure • Myalgias • Increased intragastric pressure Rocuronium • Nondepolarizing NMB • Time of onset: 1-2 min • Dose: 0.6 to 1.2 mg/kg IV (can be administered IM) • Metabolism/Excretion: liver • SE: high does causes tachycardia • TOF returns in approx 20-35 minutes • Antagonism by neostigmine Basic Airway Management • Uncomplicated airway • Obviously difficult airway • Unanticipated difficult airway Single most valuable asset available to the clinician is proficiency at bag-mask ventilation Rapid Sequence Induction • Technique used to rapidly secure the airway to minimize risk of aspiration in the presence of a full stomach • Cricoid pressure (Sellick’s manuever) The problem with cricoid pressure • May displace esophagus laterally • May distort the anatomy of the upper airway • May decrease lower esophageal tone • Reflexive • Can cause airway occludement • Many caregivers aren’t aware of the magnitude of force required to occlude the lumen of the esophagus • Varies from pediatric vs. adult Management Oral Airways Management Nasal Trumpets l Distance from nares to angle of mandible approximates the proper length l Nasopharyngeal airway available in 12F to 36F sizes l Shortened endotracheal tube may be used in infants or small children l Avoid placement in cases of hypertrophied adenoids bleeding and trauma Management Options Intubating Stylets Advantage: Allow intubation of the trachea with minimal visualization of the vocal cords Disadvantages: May be incorrectly inserted into the esophagus. Allow only a blind technique if the larynx is not visible during laryngoscopy Examples of Use: patient with limited neck range of motion but in whom the posterior larynx and epiglottis can be visualized Management Options Airway Exchange Catheters Advantage: Relatively short learning time. Long enough to allow changing an endotracheal tube with the guide still in the trachea (for example in cases of ruptured endotracheal tube cuff). Disadvantages: Improper placement of the endotracheal tube may still occur with these devices if the guide is not placed completely in the trachea. Examples of Use: Endotracheal tube change or extubation in patients with a history of difficult intubation. Management Options Laryngeal Mask Airways Advantage: Relatively short learning time. Does not require visualization of the larynx. Disadvantages: Improper placement of the endotracheal tube may occur. Passage of the endotracheal tube may not be possible when tube engages the glottic structures,laryngospasm, aspiration Examples of Use: Elective intubation of patient with known difficult airway; unsuspected difficult airway if mask ventilation is possible. Management Options • Optical stylets • Combine lighted stylet and optics of a flexible fiberoptic bronchoscope • Shikani, Bonfils Management Options Video Laryngoscopes • Video/Optical Laryngoscopes • Glidescope, Storz, Airtraq • Limitations • Requires some mouth opening for insertion of device • Not ideal for nasotracheal intubations • Can have difficulty with ETT placement despite excellent view • Poor visualization with blood and secretions Management Options • Flexible scopes • Gold standard for the management of the difficult airway • Can be limited in size (smallest being 2.7 mm) Management Options • Non-Invasive Airway Devices • Retrograde Intubation • Transtracheal Jet Ventilation • Invasive Airway Devices • Cricothyrotomy Devices • Needle cricothyrotomy • Tracheostomy Management Options Needle Cricothyrotomy • Performed when anatomic injury prevents movement of gas from the upper airway into the trachea 1. 14g catheter introduced into the trachea in the region of the cricothyroid membrane 2. Aspirate air to confirm placement 3. Remove syringe and attach adapter from a 3.0 ETT which can then be used for positive pressure oxygenation • Advanced airway interventions are associated with significant complications • Have to potential to cause harm and benefit Assessing Endotracheal Tube Placement • Direct visualization • End tidal CO2 monitoring • Chest rise • Auscultation • ETT vapor • Less reliable • Chest X-ray Summary • Proper airway management requires • practice and judgment • An appreciation of autonomic, pharmacologic, and physiological differences between infants and children from adults • It is prudent to become proficient at several techniques for airway management • Bag-Mask Ventilation • Direct laryngoscopy • Difficult airway techniques Congenital disorders associated with difficult airways in children • Micrognathia- difficult intubation • Pierre Robin Sequence • Treacher Collins • Goldenhar syndrome (hemifacial macrosomia) • Midface Hypoplasia- difficult bag-mask ventilation • • • • Apert syndrome Crouzon syndrome Pfeiffer syndrome Saethre-Chotzen syndrome • Macroglossia- difficult bag-mask ventilation and difficult intubation • Hurler’s/Hunter’s syndrome (mucopolysaccharidoses) • Beckwith-Wiedemann syndrome • Down’s syndrome Acquired Disorders associated with Difficult Airways in Children • Chronic obstruction • • • • Tonsillar hypertrophy Glottic web Hemangioma Subglottic stenosis • Acute obstruction • Infections (epiglottitis, retropharyngeal abscess) • Foreign body aspiration • Trauma • Poor mouth opening or mobility of jaw, neck • • • • Temporomandibular joint disease Spinal fusion Burn contractures Measles Stomatitis Apert • Autosomal dominant • 15 in 1 million births • Bicoronal synostosis, syndactyly • Cardiac defects • maxillary hypoplasia (flat, recessed forehand and flat midface) • Associated with cleft palate in 1/3 and class 3 malocclusion is universal finding • Progressive calcification of hands, feet and cervical spine • Airway Problem • • Bag-mask ventilation Intubation usually straightforward (may require smaller ETT size) Crouzon • Autosomal dominant • Occurs 16/1 million live births • Tall, flattened forehead • Proptosis, beaked nose • Maxillary hypoplasia • Hypertelorism • Airway Problem • Difficult bag-mask ventilation • Intubation not usually difficult Down’s Syndrome • Trisomy 21 • Most frequent chromosomal aberration and most frequent form of intellectual disability • Occurs 1/800 living births • Anesthetic Concerns • • • • • • • • 40-60% are born with cardiac anomalies Large tongue, small mouth Commonly have adenotonsillar hypertrophy Atlanto-Axial instability Bradyarrythmias Higher incidence of subglottic stenosis and tracheomalacia/ narrow glottis Behavioral issues Potentially difficult IV access • Airway Problem • May be difficult bag mask ventilation from macroglossia • A-A instability- need to maintain in-line neck stabilization • Potential subglottic stenosis In-Line Neck Stabilization Beckwith Wiedeman • Prevalence 1 in 13,700 • Pediatric overgrowth disorder, predisposes to tumor development • Macrosomia • Macroglossia • Midface hypoplasia • Airway Problems • Difficult bag mask intubation and intubation Goldenhar • Aysmmetrical malar, maxillary and mandibular hypoplasia • Auricular and ocular defects • Cardiac defects • Ventricular septal defect or tetralogy of fallot • Airway Problem • Difficult mask ventilation and intubation Pierre-Robin Sequence • Affects 1 in 8,500 to 14,000 • Micrognathia • Glossoptosis • U-shaped Cleft palate • Associated cardiac abnormalitiespulmonary stenosis • Airway Problem • Difficult mask and intubation Treacher Collins • Autosomal dominant • 1 in 50,000 births • Micrognathia • Bilateral malar and mandibular hypoplasia associated with obstructive sleep apnea • Airway Problem • Difficult intubation Hurler’s and Hunter’s Mucopolysaccharidosis (lysosomal storage disease) Gargoylism Hurler’s is autosomal recessive (more severe), Hunter’s X-linked Incidence 1:100,000 Deficiency of alpha-L iduronidase Narrow nasal passages Large tongue Short, immobile neck High epiglottis, anterior larynx Hypoplastic mandible Macrosomia Coarse facial features Hypertelorism Cervical spine instability Stiff temporo-mandibular joints Airway Problem Difficult bag mask and intubation OSA • Approximately 10% of children snore regularly • 2-4% of the pediatric population has OSA (compared to 10-30% of US adults) • Generally discussed in a range of severity from mild “sleep disorder breathing” to severe OSA • Management depends on severity Differences between Pediatric and Adult OSA Pediatric OSA Adult Age Preschool (2-8 yrs old) 40s-60s Gender Equal Male > Female Etiology Adenoid/Tonsil Hypertrophy, Airway collapsibility Obesity Weight FFT, normal or obese Obese Behavioral Hyperactive Somnolent, excessive daytime sleepiness Sleep Architecture Normal Decreased delta & REM sleep Treatment Medical/Surgical T&A, steroids/antihistamines, CPAP (rare) UPPP/CPAP Obesity • Obesity has become of the of the most significant risk factors for OSA in children • Each 1kg/m2 increase in BMI above 50th percentile is associated with a 12% increase in risk of OSA • 45% of obese children will also have tonsillar hypertrophy which contributes to the airway pathology Pediatric OSA Type I Type II • Tonsillar and Adenoid Hypertrophy • Obese Obstructive Sleep Apnea • Recurrent partial or complete airway obstruction of the upper airway during sleep with resultant desaturation and hypercapnea, leading to increasing respiratory effort and subcortical or cortical arousals. Definitions Sleep-disordered breathing (SDB) refers to the clinical spectrum of repetitive episodes of complete or partial obstruction of the airway during sleep. • Primary Snoring (PS) • Snoring without obstructive apnea, frequent arousals from sleep, or gas exchange abnormalities. • Obstructive Hypoventilation Syndrome (OHS) • Persistent partial upper airway obstruction associated with gas exchange abnormalities, rather than discrete, cyclic apneas. • Obstructive Sleep Apnea (OSA) • • • Disorder of breathing during sleep characterized by prolonged partial upper airway obstruction and/or intermittent complete obstruction. Disrupts normal ventilation. Disrupts normal sleep patterns. • Central Sleep Apnea (CSA) • • • Sleep related disorder in which the effort to breathe is diminished or absent, typically for 10 to 30 seconds, either intermittently or in cycles . Often produces decreased oxygen saturation Related to decreased brain stem signaling often secondary to immaturity or neurologic disorder Anatomic Features • Adenotonsillar Hypertrophy • Retrognathia • Large or retro-positioned tongue Risk Factors for Post Operative Respiratory Complications in Children with OSA • Younger than 3 yrs of age • Severe OSA on polysomnography • Lowest O2 sat <80% • AHI > 24/h (kept inpatient) • Significant hypercapnea >60mmHg • Cardiac complications of OSA • Failure to thrive • Obesity • Craniofacial abnormalities • Neuromuscular disorders • Current or recent (<6wks) URI Anesthetic Management • Selective premedication • Avoid versed in potentially high risk patients • Use of non-opioid analgesic medications • Dexamethasone • Dexmedetomidine • Acetaminophen • Decrease opioid dosing by 50% as compared to non-OSA patients • Continuous monitoring • Longer observation times in event of apnea or desaturation • Admission of high risk patient to hospital Dexmedetomidine • Precedex • Alpha2 agonist • Benefits • Provides effective sedation with a very low potential for respiratory depression • Recovery agitation minimal • Adverse effects • Decrease in heart rate or blood pressure (can occur in up to 30% of children) • Profound bradycardia has been described in patients who have conduction system pathology or who are receiving AV nodal slowing medication (ie. Digoxin) • Dosing and Administration • Recommended IV (bolus of 0.5- 1 mcg/kg over 10 mins) (infusion 0.5-1 mcg/kg/hr) • Intranasal (1.5 mcg/kg) • Buccal (3-4 mcg/kg) Dexmedetomidine • • • Patients were randomized to receive either 0.1mg/kg morphine or 1mcg/kg DEX or both Both patient groups had similar rescue opioid requirements When combined there was an advantage of reduced need for additional rescue analgesia • • Patient were randomized to receive 2mcg/kg bolus + 0.7mcg/kg/hr DEX infusion vs. standard therapy DEX treated patients showed significant decrease in opioid requirements, decreased incidence of emergence agitation and pain • • Patient were randomized to 0.5 mcg/kg bolus DEX during emergence Rapid IV bolus of DEX in children improved their recovery profile by reducing the incidence of emergence agitation Ofirmev • IV infusions of acetaminophen result in rapid elevation in plasma concentrations and avoid first pass metabolism in the liver • The avoidance of first pass metabolism not only allows quicker onset of pain relief but more importantly decreases risk of hepatotoxicity Ofirmev • CSF concentrations reach therapeutic levels (2mcg/mL) more rapidly • IV formulation has longer duration of action and faster on set of analgesia Summary • Clinicians should use medical history, anesthesia history, aspiration risk, airway difficulty and nature of the procedure when deciding candidacy of patients for office based anesthesia • Appropriate monitoring should include visual observation, initial and repeated measurements of vital signs • Recommend patients receiving moderate or deep procedural sedation undergo monitoring with end-tidal CO2 detetection throughout procedure and during recovery when possible • Should continue monitoring child until meets criteria for safe discharge • Institutions should develop protocols that specify pre-sedation evaluation, plan, monitoring during and in recovery, discharge and follow-up
