Perioperative Care in Remote Locations


S

Suction

Suction device with child-sized suction catheters

O

Oxygen

Availability of adequate oxygen delivery

A

Airway

Age-appropriate airway equipment

P

Pharmacy

Sedation and emergency drugs

M

Monitors

Standard monitors for vital parameters (SaO2, EKG, NiBP, EtCO2)

E

Equipment

Special equipment in child size



Children who have to undergo the procedures should be evaluated concerning their physical and behavioral status (just as for anesthesia in the operating room), and the correlated suitability for sedation should be investigated. The history should include comorbidities and previous hospitalization, sedation or general anesthesia, current therapies, relevant familiar history, and possible allergies. Particular attention should be dedicated to the risk of obstructive sleep apnea, for obese or snoring children [7]. Physical examination should include auscultation of the heart and lungs and evaluation of the neck and airways. Evidence specific for children regarding identification and management of difficult airways is limited [8]. Nevertheless, a systematic approach for children can be developed from experience with adults in the operating room using the acronym LEMON (Table 6.2).


Table 6.2
LEMON mnemonic acronym



























L

Look at him

Look for external indicators for difficult airways

E

Evaluation

Evaluate mouth opening, thyromental distance, mandibular space

M

Mallampati

Mallampati score

O

Obstruction

Signs of airway obstruction or OSAS

N

Neck

Neck mobility

Certain patient factors have been associated with failed sedations, like the presence of upper respiratory infection (URI) that mainly causes cancellation and rescheduling of the procedure. URIs are responsible of higher incidence of complications, but serious events are rare in literature [9]. Whether infectious secretions are present, the operation should be postponed at least for 2 weeks.

During pre-anesthesiological assessment, provider must present the sedation/anesthesia plan to parents and child (depending on the age) describing the benefits (minimizing pain, anxiety, and physiological trauma) and the possible risks often agent specific but commonly including potential for airway compromise, hypoxia, and vomiting. An informed consent has to be signed by both parents.

The patient fasting status is a key consideration when assessing the risk index. The American Society of Anesthesiologists (ASA) suggestions for fasting in children undergoing sedation for elective procedures are universal and are showed in Table 6.3. However, the degree of fasting for urgent/emergent procedures is controversial, and disparate recommendations have been proposed by the ASA and the American College of Emergency Physicians [10, 11].


Table 6.3
Fasting rules by ASA [71]


















2 h

Clear liquids

4 h

Breast milk

6 h

Infant formula and light meal

8 h

Fatty food or meat

Evidence regarding the optimum duration of fasting required to reduce risk of aspiration during sedation is limited [12]. No relationship has been proved between the duration of fasting prior to procedural sedation and the amount of content found in the stomach [1317]. Furthermore, there are some evidences that the more is the fasting, the more is the residual gastric volume [18].

Approach to fasting time needs some flexibility when facing with pathologies that modify children metabolism or digestive tract mobility. In some cases, as in concomitance of dumping syndrome [19], the provider should consider that the risk of hypoglycemia is more important than the risk of aspiration. On the other hand, a slow emptying, as in the case of achalasia or ileus, requires a longer fasting [20].

As reported by recent recommendations of the Italian Society of Pediatric and Neonatal Anesthesia, the systematic use of complementary tests in children, should be replaced by a selective prescription, based on the preoperative evaluation [21].



6.2 Anesthesiological Management


Differently from inside the operating room, anesthesiological management cannot be based only on patient status and on the procedure, but it should be decided also on the actual environment.

Flexibility is a key factor in the good outcome of NORA. Most of the procedures are scheduled in remote locations, which often do not guarantee a wide space of action and cannot allow the use of some drugs or equipment. Anesthesiologists have to tailor an anesthesia service to the particular requirements imposed by the actual context. For example, procedures performed directly in neonatal intensive care unit often do not allow the use of halogenated vapors for the absence of adequate anesthesia machines, vaporizers, and scavenger systems so that only intravenous drugs can be utilized; MRI and many radiologic exams do not allow to remain close to the patient, reducing the direct control on his ventilation and other vital signs; dentistry and endoscopy oblige the anesthesiologist to share airways with the co-workers (more challenging when outside the operating room); some electrophysiological retinal exams require a dark room without possibility to look at the child, etc. In these challenges, a right choice of drugs and an efficient and reliable monitoring is essential for a safe outcome.

Although respiratory adverse events are the most common [2, 22], a basic hemodynamic monitoring (EKG, NiBP) is recommended in every patient, independent from procedure, location, and clinical status. If deep sedation is performed, or if a patient has significant underlying illness, vital signs should be measured at least every 5 min.

Experience and evidence suggest that respiratory complications are the most reported and are likely to occur within 5–10 min after administration of intravenous medications and immediately after the procedure when the painful stimuli are removed.

Provided that continuous visual observation of the face, mouth, and chest wall movements is not reliable, adequate respiratory monitoring is recommended throughout the procedure [23, 24]. The use of SaO2 is mandatory but does not give a value in real time. EtCO2 monitoring, on the contrary, better by Microstream Sensor particularly in neonates, is strongly recommended [25]. Microstream monitors have a sampling chamber of 15 mcl and work well even with low flow of 50 ml.

EtCO2 monitoring is increasingly available in many settings for non-intubated patients and may be helpful to assess ventilation during sedation and analgesia. Increases in EtCO2 may be detected in children undergoing respiratory depression before hypoxemia is noted, particularly in those who are receiving supplemental oxygen. Different approaches to preoxygenation and to the use of continuous supplemental oxygen during procedural sedation are reported in literature [26]. A FiO2 higher than 0.21 can allow to maximize O2 lung storage [27] and a longer maintenance of a good level of PaO2 during occurrence of apnea. However, continuous supplemental oxygen can delay desaturation and apnea detection unless capnographic monitoring is available [28]. Furthermore, there is no evidence that preoxygenation or increasing FiO2 is associated with improved safety in NORA [29].

An additional monitoring is represented by the cerebral activity monitoring. The most utilized technology is the bispectral index (BIS). It is able to quantify the level of consciousness ranging from 0 (no brain activity) to 100 (alert), obtained by continuous EEG monitoring through probes placed on the forehead. It has shown good sensitivity in children older than 6 months, and it can be useful to guide adequate drug administration and to avoid overdosage [30] that could delay awakening. It should be considered that BIS index is not sensitive to drugs that have site effect out of the cerebral cortex, as ketamine, dexmedetomidine, remifentanil, and N2O [31].

Other brain activity monitoring devices, as entropy [32] and cerebral state index [33], are under validation for pediatric age, but results are even controversial.

Various drugs and techniques can be chosen: clinicians who administer sedation must understand the pharmacology of the drugs used. Because sedation is a continuum in which responses to medications vary greatly upon developmental, behavioral, and clinical status, type of procedure, need to cover painful maneuvers or only immobility, clinicians must identify the appropriate level of sedation/analgesia for the single child (Table 6.4). Careful titration of the chosen medication is often necessary to safely achieve the desired depth of sedation. A wide range of short-acting sedative-hypnotic and analgesic medications are available [24, 34, 35], and many of these agents have multiple routes of administration (Table 6.5). Procedures that are not painful and require only immobility can usually be performed with sedation alone. Children undergoing painful procedures require also analgesia. It has to be underlined that every performer must be able to deal with possible complications, and competence in emergency airway management is mandatory [5, 24, 36].


Table 6.4
Definitions to describe the depth of sedation


















Minimal sedation

The patient responds normally to verbal commands. Cognitive function and coordination may be impaired, but ventilatory and cardiovascular function is unaffected

Moderate sedation/analgesia

The patient has depression of consciousness but can respond purposefully to verbal commands either alone or accompanied by light touch. Maintains airways and adequate ventilation without intervention. Cardiovascular function is maintained

Deep sedation

The patient cannot be easily aroused but responds purposefully to noxious stimulation. May require assistance to maintain airway and adequate ventilation. Cardiovascular function is usually maintained

General anesthesia

The patient cannot be aroused. May require airway assistance and ventilation. Cardiovascular function may be impaired



Table 6.5
Principal routes of administration



























Inhalation

Halogenated, N2O

Intravenous

All opiates, propofol, midazolam, ketamine, flumazenil, naloxone

Intramuscular

Ketamine, benzodiazepine

Rectal

Ketamine, benzodiazepine

Intranasal

Midazolam, flumazenil, dexmedetomidine, fentanyl, ketamine

Buccal

Midazolam, ketamine, sufentanil, dexmedetomidine

Transmucosal

Fentanyl


6.3 Inhalation Techniques


Historically, children have been anesthetized in operating rooms by halogenated vapors. The increasing demand of procedures in NORA has transferred this technique even outside of the operating room. The recent attention to the environmental pollution and to the occupational safety has restricted the use of inhalation anesthesia inside the locations equipped by specific scavenger systems.

The most used vapor in this field is sevoflurane that guarantees a safe profile for maintenance of spontaneous breathing and stabile hemodynamic. It is also advantageous for its rapid onset and the possibility to find a venous access in not cooperating children. It can be used trough facial mask or even by nasal probes, very useful in procedures performed on the eyes or on the face where the mask could result cumbersome.

Other halogenated (as desflurane or isoflurane) are not indicated for this use, due to their irritating effect on the tracheobronchial system, when used in spontaneous ventilation.

Nitrous oxide (N2O) is an old gas which recently has been proposed again, in a new formulation. It is commercialized as a mixture with O2 50 % in portable tanks. It is delivered through a demand valve mask or continuous flow system [37]. Because the demand valve mask requires cooperation and may be difficult to be activated by smaller children, N2O is used primarily in patients older than 4 years of age. To prevent excessive exposure, dedicated facial masks connected with a scavenger system can be utilized. A continuous delivery system (a mask strapped over the nose and/or mouth) has been used in younger children with variable success. This system indeed is more frequently associated with emesis [38, 39]. N2O provides good analgesia, sedation, amnesia, and anxiolysis [40, 41], and it is a widely used analgesic for acute, short-term pain relief in a diverse range of clinical situations. Contraindications to nitrous oxide include nausea and vomiting and trapped gas within body cavities (e.g., bowel obstruction, pneumothorax, middle ear infection). Deeper sedation than anticipated can occur with prolonged inhalation and when N2O is combined with opioids or benzodiazepines [42]. It is reported that fasting is not mandatory using 50 % N2O/O2 mixture [43]. In the absence of a clear evidence, every physician should identify the best choice according to his experience or skill.


6.4 Intravenous Techniques


Children are usually afraid of needles, and often in NORA, there is no possibility to use inhalation induction, so the cooperation of the child for finding a venous access is important. Application of anesthetic transdermic cream 45 min earlier can be very useful, in association with administration of midazolam 0.4–0.5 mg/kg (for a maximum of 15 mg) by mouth or better through the more rapid nasal route, thanks to the high mucosal vascularization [44].

Over the last decade, intravenous techniques are developed even in pediatrics with successful outcome. The marketing of new short-acting drugs and the safer profile of pharmacodynamics allows to calibrate anesthesia in real time with respect to the procedure.

The development of pediatric pharmacokinetic models for target-controlled infusion (TCI), Paedfusor and Kataria, has been a further boost to better utilize propofol in children.

TCI technique is particularly advantageous in NORA, allowing to perform sedation in spontaneous breathing assuring a constant propofol plasma concentration [45]. When compared with manual controlled infusion or intermittent bolus, TCI provides reduced apnoeic events and shorter awakening time [46].

For these reasons, propofol currently is the commonest intravenous agent (alone or in combination) administered in NORA. Safety profile is very comfortable even in smaller children [47], despite propofol infusion syndrome has been described after longer or high-dose infusion [48]. However, high doses administered by mistake for short procedures have not shown fatal outcome, despite a transient alteration in the metabolic pattern [49].

Remifentanil shows a pharmacokinetic profile even more advantageous in general anesthesia due to the efficacy of plasmatic esterases, which seems already mature even in premature babies [50]. Among opiates, remifentanil is the most indicated for a rapid recovery and discharge, even if the apnoeic effect requires a strict capnographic monitoring when spontaneous breathing is performed.

Outside the operating room, other opioids have proven useful. Alfentanil has been utilized by bolus in association with propofol or midazolam in short painful procedures as bone marrow aspiration or lumbar puncture [51]. Opioids with longer half-life are less recommended, as unique sedation agent, due to the increased interindividual variability and difficult titration. Recently sufentanil has been experimented successfully in a preliminary study by nasal route in dentistry [52], but this technique still needs major validation.

Ketamine, which came back to our attention in the last years, provides sedation, analgesia, and immobilization while usually preserving upper airway muscle tone and spontaneous breathing [5355]. Its use in small doses in association with hypnotic agents is common, particularly for the possibility of administration by several routes.

Dexmedetomidine can be considered the future of sedation also in NORA. It causes minimal respiratory depression and, in healthy children, has been found generally safe and effective for nonpainful procedures [56], and in some sedation service, it is already the preferred agent for diagnostic imaging [57, 58].

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Sep 22, 2016 | Posted by in ANESTHESIA | Comments Off on Perioperative Care in Remote Locations

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