Abstract
Obesity is a worldwide epidemic. It is associated with increased comorbidities and increased maternal, fetal, and neonatal complications. The risk of cesarean delivery is also increased in obese parturients. Anesthetic management of the obese parturient is challenging and requires adequate planning. Therefore, those patients should be referred to antenatal anesthetic consultation. Anesthesia-related complications and maternal mortality are increased in this patient population. The risk of difficult intubation is increased in obese patients. Neuraxial techniques are the preferred anesthetic techniques for cesarean delivery in obese parturients but can be technically challenging. An existing labor epidural catheter can be topped up for cesarean delivery. In patients who do not have a well-functioning labor epidural, a combined spinal epidural technique might be preferred over a single-shot spinal technique since it is technically easier in obese parturients and allows for extending the duration of the block as required. A continuous spinal technique can also be considered. Studies suggest that there is no need to reduce the dose of spinal bupivacaine in the obese parturient, but there is little data about spinal dosing in super obese parturients. Intraoperatively, patients should be placed in a ramped position, with close monitoring of ventilation and hemodynamic status. Adequate postoperative analgesia is crucial to allow for early mobilization. This can be achieved using a multimodal regimen incorporating neuraxial morphine (with appropriate observations) with scheduled nonsteroidal anti-inflammatory drugs and acetaminophen. Thromboprophylaxis is also important in this patient population due to the increased risk of thromboembolic complications. These patients should be monitored carefully in the postoperative period, since there is increased risk of postoperative complications in the morbidly obese parturients.
Keywords: obesity, neuraxial techniques, cesarean delivery
Introduction
Obesity is a global epidemic. It is estimated that over 50% of pregnant woman in the United States are overweight or obese.1 The World Health Organization, and the National Heart, Lung and Blood Institute use body mass index (BMI) to define normal weight as BMI 18.9–24.9 kg/m2, overweight as BMI 25–29.9 kg/m2, and obese as BMI >30 kg/m2.2 Although any BMI >30 kg/m2 is obese, three further classes can be described: BMI 30–34.9 kg/m2 (obesity class 1), BMI 35–39.9 kg/m2 (obesity class II), and BMI >40 kg/m2 (obesity class III).3 Other nomenclature may be found in the literature including morbid obesity (BMI >40 kg/m2) and super obesity (BMI >50 kg/m2). There is no definition of obesity specific to pregnancy, and BMI classifications have limitations in certain populations such as those with advanced age, athletes, and in pregnancy. Therefore, in 2009, the Institute of Medicine updated their recommendations for managing obesity in pregnancy. It is now recommended that obstetricians evaluate gestational weight gain based on prepregnancy BMI and gestational age.4
Although there are no racial, social, or economic boundaries that obesity does not cross, obesity is most prevalent among those with low socioeconomic status, low education status, and minority women.5 It is a multisystem disease with several associated comorbidities (Table 1). In addition to these comorbidities, obesity is associated with prolonged labor6 and with significant maternal, fetal, and neonatal complications (Table 2). The risk of cesarean delivery is increased in obese parturients, which is most relevant to this article. In a study involving 121,092 nulliparous women stratified by prepregnancy BMI, Tabet et al7 reported that the odds ratio (95% confidence interval) for cesarean delivery among overweight and obese women was 1.50 (1.41, 1.59) and 2.06 (1.91, 2.21) respectively.7 Similar findings were reported in other large cohorts.8,9
Table 1.
Comorbidity | Odds ratio (95% confidence interval) |
---|---|
Type 2 diabetes | 12.41 (9.03, 17.06) |
Hypertension | 2.42 (1.59, 3.67) |
Coronary artery disease | 3.1 (2.81, 3.43) |
Congestive heart failure | 1.78 (1.07, 2.95) |
Pulmonary embolism | 3.51 (2.61, 4.73) |
Stroke | 1.49 (1.27, 1.74) |
Asthma | 1.78 (1.36, 2.32) |
Gallbladder disease | 2.32 (1.17, 4.57) |
Chronic back pain | 2.81 (2.27, 3.48) |
Note: Data from a previous study.110
Table 2.
Obstetric complication | Odds ratio (95% confidence interval) |
---|---|
Gestational diabetes111 | 2.4 (2.2, 2.7) |
Hypertensive disorders111 | 3.3 (2.7, 3.9) |
Venous thromboembolism112 | 9.7 (3.1, 30.8) |
Induction of labor113 | 1.84 (1.53, 2.21) |
Total cesarean delivery113 | 2.42 (2.02, 2.91) |
Emergency cesarean delivery113 | 2.15 (1.78, 2.58) |
Postpartum hemorrhage111 | 2.3 (2.1, 2.6) |
Wound infection114 | 2.24 (1.91, 2.64) |
Macrosomia113 | 3.39 (2.78, 4.18) |
Shoulder dystocia 115 | 2.9 (1.4, 5.8) |
Prematurity111 | 1.2 (1.1, 1.4) |
Still birth116 | 2.1 (1.5, 2.7) |
Neonatal death117 | 2.6 (1.2, 5.8) |
The fact that obesity is associated with an increased risk of death during pregnancy is most concerning. In a review of all pregnancy-related deaths in Wisconsin between 2006 and 2010, Schellpfeffer et al10 found that 76% of women who died were overweight or obese.10 Additionally, Main et al11 reviewed maternal-related deaths in California from 2002 to 2005 and found that women who died were more likely to be obese or morbidly obese, particularly women who died from thromboembolic events and cardiovascular disease.11 In the United Kingdom, the Confidential Enquiry into Maternal Deaths found that in the last three reports covering the years 2003–2013, 49%–52% of women who died were overweight or obese.12–14
Obesity is also a risk factor for anesthesia-related maternal mortality. Mhyre et al15 reviewed anesthesia-related deaths in Michigan between 1985 and 2003 and reported that six of eight women who died were obese.15 Similarly, the Confidential Enquiries into Maternal Deaths in the United Kingdom found that out of the 17 deaths directly attributed to anesthesia in the last three reports, six occurred in obese parturients.12–14
The following sections discuss the preoperative, intraoperative, and postoperative management of cesarean delivery in the obese parturient.
Anesthesia consultation and preoperative assessment
Because of the significant risk of complications associated with obesity in pregnancy, both the American College of Obstetricians and Gynecologists (ACOG)16 and the Royal College of Obstetricians and Gynaecologists (RCOG) in conjunction with the Centre for Maternal and Child Enquiries17 published guidelines recommending a multidisciplinary team approach when caring for the obese parturients. These include 1) preconception counseling, 2) assessing BMI for all parturients to screen for obesity, 3) monitoring BMI, 4) providing strict guidelines for prenatal weight gain, and 5) an anesthesia consultation in the third trimester for woman with a BMI >40 kg/m2. During this consultation, a comprehensive history and physical examination should be performed, with emphasis on the evaluation of the airway, as well as the cardiovascular and pulmonary systems. A frank discussion of the risks and benefits of different types of anesthesia should take place with the patients, including an explanation of the importance of neuraxial analgesia and anesthesia and the fact that neuraxial techniques might be technically difficult and time consuming; therefore, patients should be encouraged to request neuraxial analgesia early in labor. This consultation also provides an opportunity to order any further investigations that might be needed to optimize safety of the mother and baby and discuss delivery planning with the patient.
Obesity is a risk factor for obstructive sleep apnea (OSA), which is characterized by repeated episodes of upper airway collapse, leading to hypoxemia and hypercarbia. OSA is associated with increased risk for hypertension, myocardial infarction, stroke, diabetes, and metabolic syndrome.18,19 Louis et al20 found a fivefold increase of in-hospital death in parturients with OSA compared with those without OSA, even when adjusting for serious cardiovascular, renal, and metabolic conditions. The same authors previously reported an increased risk of hypertensive disorders of pregnancy, gestational diabetes, and preeclampsia in parturients with OSA.21 Although it is well known that OSA is a serious problem in pregnancy, there are currently no validated tools to screen parturients for OSA. A recent study found that none of the commonly used screening tools was predictive for OSA in the pregnant patient population; however, individual items within those tools such as BMI >35 kg/m2, falling asleep when speaking with someone, and a history of hypertension were significant predictors of OSA.22 Women who are deemed at risk for sleep apnea should be referred for a sleep study, and if OSA is diagnosed, treatment with continuous positive airway pressure (CPAP) should be initiated.
Cardiovascular disease is the leading cause of maternal death in the United States, and obesity is a risk factor for pregnancy-related cardiovascular mortality.23 A BMI >30 kg/m2 is associated with a threefold higher risk of hypertension during pregnancy.24 Women with chronic or gestational hypertension should be medically optimized throughout pregnancy according to ACOG guidelines.25 During the anesthesia consultation, adequacy of blood pressure control should be ensured. Morbidly obese parturients are noted to have increased left atrial size, left ventricular thickness, interventricular septal thickness, and left ventricular mass.26 Any new onset of shortness of breath, decrease in exercise tolerance greater than expected for pregnancy, or new syncope or chest pain may warrant referral for a third-trimester echocardiogram to identify patients with poor ventricular function who may not tolerate the autotransfusion in the peripartum period.
Eley et al27 investigated the impact of an anesthesia consultation on anxiety, decisional conflict, and risk perception of chronic disease in obese parturients. The same questions were asked before and after the anesthesia consultation, and interestingly, the authors found significantly decreased decisional conflict scores and reduced anxiety after consultation. However, the consultation and discussion with the anesthesia provider did not increase the parturients’ awareness of the risks of obesity in pregnancy.27
Anesthetic technique for cesarean delivery
Unless there is a contraindication, neuraxial anesthesia is the anesthetic technique of choice for cesarean delivery in all parturients in general, and in the obese parturient in particular. Both pregnancy and obesity are risk factors for a difficult airway and anesthesia-related maternal mortality. In the United States, Hawkins et al28 reported that pregnancy-related mortality ratio for deaths related to anesthesia was 1.2 per million live births for the period 1991–2002, which represents a decrease of 59% in the deaths for the period 1979–1990. Between 1985 and 1990, the relative risk (95% confidence interval) of general anesthesia compared with neuraxial anesthesia for cesarean delivery was 16.7 (12.9, 21.8). This decreased to 6.7 (3.0, 14.9) in 1991–1996 and further to 1.7 (0.6, 4.6) in 1997–2002. The estimated case fatality rate of general anesthesia during cesarean delivery decreased from 16.8 deaths per million general anesthetics for 1991–1996 to 6.5 deaths per million general anesthetics for 1997–2002. In contrast, the estimated case fatality rate of regional anesthesia during cesarean delivery increased slightly from 2.5 deaths per million regional anesthetics to 3.8 deaths per million regional anesthetics. Approximately two-thirds of deaths due to general anesthesia are caused by intubation or other induction problems such as aspiration, and advances in airway management have undoubtedly contributed to the reduction in anesthetic deaths associated with general anesthesia. Another important factor to consider is that regional anesthesia has become preferred and more widely used overall and for many high-risk parturients in particular, including those with morbid obesity. For instance, Tonidandel et al reported that general anesthesia was used for cesarean delivery in 3% of cases in morbidly obese parturients in 2011–2012, compared with a rate of 24% in a previous study in the same institution in 1993.29,30
While the risk for difficult intubation is increased in the parturient compared with the general surgical population, obesity itself is associated with a further increase in risk.31–33 It is also associated with an increased difficultly in mask ventilation.34 This is related to the short neck, fat deposition in the neck and shoulders increasing the difficulty for optimal position for laryngoscopy, breast hypertrophy as well as enlarged tongue, and excessive palatal and pharyngeal soft tissues. Hood and Dewan30 reported an incidence of difficult intubation of 33% in morbidly obese parturients undergoing cesarean delivery who weighed >136 kg.30 Airway changes also occur during labor, with an increase in airway class from prelabor,35 further increasing the risk of confronting a difficult intubation in this patient population.
The following section focuses on neuraxial anesthetic techniques for cesarean delivery. The general principles of general anesthesia in the morbidly obese parturient are summarized in Table 3.
Table 3.
Preinduction |
Premedication |
Histamine-2 receptor antagonist |
Nonparticulate antacid |
Standard ASA monitors |
Pulse oximetry |
Noninvasive blood pressure cuff of appropriate size |
Electrocardiogram |
Capnography |
Temperature |
Difficult airway cart/presence of trained assistant |
Short handles and multiple blades |
Video laryngoscope |
Fiberoptic laryngoscope |
Laryngeal mask airways |
Large bore intravenous access |
Position |
Align oral, pharyngeal, and tracheal axes |
Neck in sniffing position |
Back ramped on folded blankets or padded ramp |
Left uterine displacement |
Preoxygenation |
100% oxygen for 3 minutes tidal volume breaths or eight deep breaths over 1 minute |
Induction and intubation |
Rapid sequence induction with cricoid pressure |
Propofol: 2–2.8 mg/kg based on LBW |
Etomidate: 0.2 mg/kg based on LBW |
Thiopentone: 4–5 mg/kg based on LBW |
Succinylcholine: 1 mg/kg based on total body weight |
Rocuronium: 1–1.2 mg/kg based on ideal body weight |
Maintenance |
Volatile agents: isoflurane, desflurane, or sevoflurane with or without nitrous oxide (higher inspired oxygen concentrations may be needed) |
Fentanyl: administered based on LBW |
Emergence |
Beware of risks of aspiration, hypoventilation, and airway obstruction |
Tracheal extubation with patient fully awake |
Full reversal of muscle relaxation |
Semi-sitting position |
Technical considerations
Monitoring equipment
An appropriate sized blood pressure cuff for noninvasive blood pressure measurements should be used. The American Heart Association recommendations for appropriate sizing of blood pressure cuffs specify that the width and length of the compression bladder should be equal to 40% and 80% of the upper arm circumference, respectively.36 Blood pressure measurement in the obese parturient presents challenges, not only because of the size of the upper arm, but also because of its conical shape, resulting in difficulties in fitting an appropriately sized blood pressure cuff, and therefore impacting the accuracy of the measurements obtained.37 For this reason, sometimes, a forearm blood pressure cuff is used. Although there is a good correlation between the upper arm and forearm blood pressure measurements, the latter exceed forearm measurements by an average of 10 mmHg.38 Recently, a conical blood pressure cuff for use on the forearm was developed to address the issues of proper sizing in obese patients and was reported to provide good agreement with arterial blood pressure measurements.39 In some morbidly obese parturients undergoing cesarean delivery such as those with cardiac disease, those at risk for bleeding or when there are significant difficulties in obtaining noninvasive blood pressure readings, invasive blood pressure monitoring might be appropriate.
Spinal and epidural needles
The distance to the epidural space is greater with increased BMI.40 Therefore, longer than standard spinal and epidural needles might be needed and should be available. However, in the majority of obese patients, neuraxial blocks can be performed successfully with standard length needles.41 Since the standard length needles are easier to manipulate and provide the anesthesiologist with better control compared with the longer ones, we recommend starting with the standard length needle and switching to the longer needle only if the epidural/intrathecal space could not be reached with the standard length needle. Performance of a pre-block ultrasound might also help estimate the distance to the epidural space.
Acid aspiration prophylaxis
Whether obese parturients have large gastric volume, low gastric pH, or change in gastric emptying compared with non-obese parturients is unclear.42 However, gastroesophageal reflux and hiatal hernia are more common in obese compared with nonobese patients.43 Given that obesity is associated with an increased risk for difficult intubation, it is likely that obese parturients are at higher risk for aspiration. Routine acid aspiration prophylaxis should therefore be administered to all obese parturients undergoing cesarean delivery. In a recent meta-analysis, Paranjothy et al44 reported a significant reduction in the risk of intragastric pH <2.5 with antacids, H2 antagonists, and proton pump inhibitors, when compared with placebo or no treatment. The combined use of antacids plus H2 antagonists was associated with a significant reduction in the risk of intragastric pH <2.5 when compared with placebo or with antacids alone. Addition of metoclopramide might confer additional protection,45 but evidence is limited.44 A meta-analysis involving both obstetric and nonobstetric studies suggested that premedication with ranitidine was more effective than proton pump inhibitors in reducing the volume of gastric secretions and increasing gastric pH.46 Ranitidine should be administered at least 60 minutes if given orally and 30 minutes if given intravenously, prior to cesarean delivery for optimum effect on gastric volume and pH.47 However, there are no data to examine the association between reduced gastric acidity and the frequency of pulmonary aspiration, vomiting, morbidity, or mortality in obstetric patients who aspirate gastric contents.48 Administration can be initiated the evening before surgery in elective cases. Recent studies have suggested that the use of bedside gastric ultrasonography can be useful in assessing gastric contents during labor49 and prior to elective cesarean delivery.50
Identification of the neuraxis: conventional approaches and ultrasonography
Adequate staffing is needed to ensure that the patient is properly positioned for neuraxial anesthesia, and careful attention should be made that the patient remains centered on the operating table. Even with optimal positioning, identifying the epidural space can still be a challenge. Although neuraxial anesthesia can be performed in either a sitting or a lateral position, the sitting position is preferred in the obese. The sitting flexed position brings the epidural space closer to the skin and therefore the distance from the skin to the epidural space is shorter in this position compared with the lateral position.40 Furthermore, the obese parturients may have lateral pads of fat that sag and obscure the midline in the lateral position. Tape can be used to retract the pads of fat to the shoulders in the seated position to better visualize landmarks. It is also often difficult to identify the midline or palpate spinous processes in this patient population.51 Stiffler et al52 reported difficulty in palpating landmarks in 68% of obese nonpregnant patients compared with only 5% of those with a normal BMI. An additional advantage of the sitting position is that the prominence of the seventh cervical vertebra and gluteal cleft can be observed allowing for easier identification of the midline compared with the lateral position.
Other techniques have also been suggested to assist the anesthesiologist in identifying the midline. The larger gauge needle used for skin infiltration of local anesthetic may be used to identify the spinous process and interspaces.53 Marroquin et al54 found that 77% of morbidly obese parturients provided useful information on the position of the needle during epidural placement and their input on laterality may be used for direction.
Ultrasonography can also be useful in identifying the midline, as well as estimating the depth to the epidural space. Balki et al55 found a strong correlation between the depth to the epidural space measured by the epidural needle and that estimated by ultrasound in obese parturients.55 However, there was a trend to underestimate the actual needle depth with ultrasound as the depth to the epidural space increased, likely due to increased soft tissue compression by the ultrasound probe in women with a high BMI. Sahin et al56 also found that prepuncture ultrasound reduced the number of attempts at spinal anesthesia in obese parturients undergoing cesarean delivery. Although image quality might not be optimal in the obese due to the thickness of the subcutaneous tissue,57 there is evidence that prepuncture ultrasound is useful to decrease the need for needle redirection during epidural placement and reduce replacement of failed catheters.55 A recent study suggested that the quality of imaging for prepuncture ultrasound might be better with the paramedian sagittal oblique plane compared with the transverse median plane in obese parturients.58
Antibiotic prophylaxis
ACOG recommends prophylactic antibiotics for all cesarean deliveries within 1 hour of skin incision.59 A Cochrane review found significant decrease in wound complications, endometritis, and infectious complications when prophylactic antibiotics were administered, regardless of the degree of urgency of the cesarean section.60 The optimum prophylactic antibiotic dosing in obese women is not clear. A study by Pevzner et al61 showed that a 2-g dose of cefazolin administered 30–60 minutes prior to cesarean delivery in obese (BMI 30–39.9 kg/m2) or morbidly obese (BMI ≥40 kg/m2) patients failed to achieve targeted minimum inhibitory concentrations in 20% and 33% of patients, respectively, at the time of skin incision and in 20% and 40% of patients at the time of incision closure.61 In fact, the Clinical Practice Guidelines for Antibiotic Prophylaxis in Surgery recommend a dose of 3 g of cefazolin before cesarean delivery in women weighing over 120 kg.62 However, a study evaluating 20 obese patients who were randomized to receive 2 or 4 g of cefazolin found higher blood and tissue levels with the 4 g dose, but all collected subcutaneous and myometrial tissue samples had antibiotic concentrations above the minimum inhibitory concentration, and no surgical site infections or endometritis were reported.63 A recent retrospective study compared surgical site infections in morbidly obese women undergoing cesarean delivery who received 2 or 3 g of cefazolin preoperatively and also found no difference in surgical site infections between the two regimens.64
Choice of neuraxial technique
Different neuraxial techniques to consider are a single-shot spinal, continuous spinal, epidural, or a combined spinal epidural (CSE) technique.
Single-shot spinal anesthesia
Single-shot spinal anesthesia provides a fast onset, reliable, and dense neuroblockade, providing excellent operative conditions and high level of patient comfort, therefore minimizing the need for supplemental analgesics, which has benefits in the morbidly obese parturients with OSA and potentially difficult airway.65 There are however two limitations to the use of single-shot spinal anesthesia in the morbidly obese parturients. The first limitation relates to the inability to extend the duration of the block with a single-shot spinal technique. Given the increased duration needed to position the morbidly obese parturient on the operative table and the often prolonged duration of surgery in this patient population,66 a continuous technique is preferred to confer the ability to extend the duration of the neuraxial block and avoid the need to induce general anesthesia with its associated risks if the duration of surgery outlasts the duration of the spinal block. The second issue relates to the ease of performing the neuraxial block. Most often, 25–27 gauge pencil point spinal needles are used in the obstetric population to decrease the risk of postdural puncture headache (PDPH).67 The use of those small gauge needles might however be technically challenging in the morbidly obese parturients with excessive adipose tissue in the lumbar region, since the introducer used will be relatively short in this situation. Identifying the epidural space with a larger gauge Tuohy needle is easier to perform in an obese patient. The larger Tuohy needle would then act as an ideal introducer for the small gauge spinal needle allowing for location of the intrathecal space as part of a needle through needle CSE technique. In fact, a recent study reported that fewer attempts were needed to establish spinal anesthesia in the morbidly obese parturients with a CSE technique compared with a single-shot spinal technique.68
Continuous neuraxial techniques
The available options for a continuous neuraxial technique include the use of epidural catheters, spinal catheters, a CSE technique, or a double catheter technique.
Epidural anesthesia
A well-functioning labor epidural catheter can be topped up to achieve surgical anesthesia for cesarean delivery. Epidural analgesia represents the optimal method for pain relief during labor and should be administered early to the morbidly obese parturient, given the increased risks for macrosomia, shoulder dystocia, and cesarean delivery. It is very important to regularly assess the analgesia provided by the epidural catheter during labor, since a poorly functioning labor epidural catheter requiring frequent top-up doses may fail to provide adequate surgical anesthesia69; therefore, such catheters should be replaced early to reduce the risk of failure to achieve adequate surgical anesthesia if a cesarean delivery is needed.
The density of an epidural neuraxial block is in general less than that following an intrathecal block; therefore, epidural catheters are not commonly used as a de novo technique for cesarean delivery except in situations where it is desired to achieve a slower sympathetic block by slow titration of the local anesthetic through the epidural catheter to establish the required surgical level. This may be critical in some patients requiring a stable systemic vascular tone, such as those with cardiac disease. Slow titration of the epidural also decreases the risk of a high neuraxial block that would require emergent intubation, which is a feared complication in the morbidly obese, and therefore might be preferred by some providers in this patient population. Lastly, an epidural catheter may be used postoperatively for pain control.
CSE anesthesia
CSE anesthesia offers many of the benefits of the epidural catheter and single-shot spinal technique in that it provides a dense spinal anesthetic with the flexibility of a continuous technique.66 In addition, as previously mentioned, a needle through needle CSE technique is easier to perform in this patient population compared with a single-shot spinal anesthesia and therefore, is the technique of choice for elective cesarean delivery in the obese and morbidly obese parturients. If there is concern about an excessive block causing severe hypotension or respiratory compromise in the morbidly obese parturient, a lower spinal dose may be given and the anesthetic level titrated up using epidural saline (epidural volume expansion technique) or local anesthetic through the epidural catheter. However, the technique of epidural volume expansion might be unpredictable70 and has not been specifically investigated in the morbidly obese parturient. One concern with the CSE technique relates to the fact that the epidural catheter is untested and might fail to provide adequate anesthesia if the spinal block wears off and there is a need to use the epidural catheter intraoperatively. However, most studies suggest that the failure rate of an epidural catheter inserted as part of a needle through needle CSE technique is lower than that placed as part of an epidural only technique, since obtaining cerebrospinal fluid (CSF) through the spinal needle indirectly confirms the correct positioning of the epidural needle.71,72
Continuous spinal anesthesia
Continuous spinal anesthesia allows slow titration of intrathecal local anesthetic to establish a dense block to the desired level while closely monitoring hemodynamics and respiratory status, thus decreasing the risk of a high spinal block, which can be disastrous in this patient population.73 The continuous technique also allows the provider to extend the duration of the block and provide adequate anesthesia for lengthy surgeries. This technique has been recommended by some to use in emergency situations in the obese parturient since it may be technically easier to identify the subarachnoid space with a large Tuohy needle than with a spinal needle and therefore perform the block quicker.41 Despite the advantages of this technique in the morbidly obese parturient, its routine use is limited by the risk of PDPH, since the block is performed with a large gauge Tuohy needle. However, some authors have suggested that obesity might have a protective effect against the development of PDPH.74 Possible explanations for the protective nature of obesity include the elevated intra-abdominal pressure secondary to a large pannus reducing CSF leak and the fact that engorged veins and epidural fat may decrease any pressure difference between the epidural and subarachnoid space.75 Additionally, a magnetic resonance imaging study reported that obese patients have less CSF volume compared with nonobese patients.76 While a recent retrospective study by Miu et al77 failed to show a difference in the incidence of PDPH between BMI <30 kg/m2 and BMI >30 kg/m2 groups, a larger study by Peralta et al78 suggests that obesity (BMI >31.5 kg/m2) may be protective against the development of PDPH. On the other hand, another recent retrospective analysis by Franz et al79 suggest that the risk of PDPH following dural puncture with a 17–18 gauge Tuohy needle is only reduced in those with BMI >50 kg/m2. While continuous spinal anesthesia for cesarean delivery can be established using a 22–24 gauge catheter over the needle technique to reduce the risk of PDPH, the risk of failure and need for supplemental analgesia has been reported to range from 9% to 24%.80,81 The technique has also not been specifically studied in morbidly obese patients.
Double catheter technique
Because of a larger pannus, the surgeons might decide to perform the cesarean delivery via a high supraumbilical vertical midline incision. With this incision, the morbidly obese patients may have impaired ventilation in the postoperative period secondary to pain and diaphragmatic splinting. Two reports described the use of a double catheter technique in super obese parturients who had a cesarean delivery through a vertical supraumbilical incision. McDonnell and Paech82 described the use of a lumbar CSE technique for intraoperative anesthesia and a low thoracic epidural catheter for postoperative analgesia in a super obese parturient with a BMI of 76 kg/m2. More recently, Polin et al73 also reported using a double catheter technique in three super obese women (BMI 73–95 kg/m2) undergoing vertical midline incisions for elective cesarean sections. A low thoracic epidural catheter was placed at T10–T12 and subsequently, a second lumbar continuous spinal catheter was placed. The authors reported titrating the spinal catheter to safely achieve the desired block height without compromising hemodynamics or respiratory function. The thoracic epidural catheter was used for postoperative analgesia.73 Interestingly, in one of those cases, adequate anesthesia for the upper end of the skin incision could only be achieved intraoperatively after dosing the thoracic epidural catheter.
Transfer and positioning on the operating table
The weight limits of the operating table should be checked to ensure that it can accommodate morbidly obese parturients. The use of table extenders should also be considered as appropriate, and pressure areas should be adequately padded. Special equipment for moving the patients might be needed, such as air-assisted mattresses (eg, HoverMatt®, HoverTech International, Bethlehem, PA, USA), and staff should be trained in the use of such equipment.
Obese parturients should be positioned in a ramped position with left uterine displacement. This can be achieved by using folded blankets, pillows, a specifically designed padded ramp or by manipulating the operating room table. The aim should be to horizontally align the external auditory meatus and the sternal notch to optimize conditions for tracheal intubation if needed and to improve hemodynamic and respiratory parameters in the morbidly obese parturient.83 Care should be taken to secure the patients to the operating table first and to then initiate left uterine displacement promptly. Acute cardiovascular collapse has been previously reported in two obese patients after assuming the supine position.84
The obstetrician might ask to perform cephalad retraction of the large panniculus to allow for a Pfannenstiel incision. Such retraction however might compromise the patient’s ventilation and could result in hypotension. In fact, a case of intraoperative fetal death was reported in a morbidly obese parturient, who received epidural anesthesia, as a result of protracted hypotension following powerful cephalad retraction of the panniculus.85 Therefore, careful monitoring of ventilatory and circulatory status is crucial following retraction of the panniculus. Some perform vertical and cephalad suspension of the panniculus to reduce the risk of hypotension and hypoxemia.86 Commercially available devices are also used to retract the panniculus (eg, traxi™, Clinical Innovations, Murray, UT, USA), but there are no data evaluating those devices.
Dosage of intrathecal local anesthetic
It is known that the dose of intrathecal bupivacaine is reduced in pregnant compared with nonpregnant patients,87 due to factors such as enhanced spread of intrathecal local anesthetic due to the mechanical effect of epidural venous engorgement or alteration of the permeability of neural tissue to local anesthetics as a result of the hormonal changes in pregnancy.88 It is debated whether the local anesthetic dose should be further reduced in the obese parturient. Magnetic resonance imaging studies have confirmed a reduced lumbar CSF volume in the obese as well as an inverse correlation between the lumbar CSF volume and the cephalad extent of the block.3,76 This decreased CSF volume in the obese parturient is thought to result from caval compression by the gravid uterus and abdominal panniculus causing engorgement of epidural veins and increased abdominal pressure displacing soft tissue through the intervertebral foramina. This led to concerns about exaggerated spread of the spinal block in the obese parturient if the spinal dose is not reduced with the risk of a high spinal requiring emergency endotracheal intubation in a parturient with a potentially difficult airway and a significant aspiration risk. In fact, some reviews suggest a spinal dose reduction in the morbidly obese parturient.41,89,90 Clinical studies however do not support these concerns. Two independent studies found no correlation between height, weight, or BMI and the extent of spinal anesthesia, when a standard dose of bupivacaine 12 mg was used for cesarean delivery in term parturients.91,92 However, the morbidly obese were not specifically studied in those trials. In a study estimating the dose requirements for bupivacaine in obese and nonobese parturients, Lee et al87 reported that the 95% effective dose (ED95) was similar in the two groups. Carvalho et al also found no difference in the ED50 and ED95 of hyperbaric spinal bupivacaine for cesarean delivery in morbidly obese parturients as compared with those estimated in a previous study using the same methodology in nonobese parturients.93,94 Therefore, current data do not support a reduction in the spinal dose of hyperbaric bupivacaine in the obese parturient. However, data on the spread of spinal block in the super obese parturient is limited. A retrospective study at our institution suggested that there was no risk of exaggerated spinal spread in the obese compared with the nonobese parturient except in those with BMI over 50 kg/m2.95
Postoperative care
Postoperative complications
There is an increased risk of complications postoperatively in the obese. These include urinary tract infection, wound infection, wound dehiscence, peripheral nerve injury, hemorrhage, deep vein thrombosis, pulmonary embolism, atelectasis, pneumonia, respiratory depression, myocardial infarction, and maternal death.41
Respiratory depression in particular is a feared complication in the morbidly obese. In a report on maternal mortality in Michigan, Mhyre et al15 found that all anesthesia-related maternal deaths from hypoventilation or airway obstruction occurred during emergence and postanesthesia care with obesity recognized as a risk factor for these complications.15 It is well known that obesity is a risk factor for OSA. The American Society of Anesthesiologists (ASA) has issued practice guidelines for perioperative management of patients with OSA. While those guidelines do not specifically apply to the parturient, they highlight the increased risk of a difficult airway, place emphasis on regional anesthetic techniques to eliminate the need for systemic opioids, as well as introduce recommendations on postoperative analgesia including the use of opioid sparing strategies and avoidance of a background infusion with the use of intravenous opioid patient-controlled analgesia for pain control.96
Analgesia
The importance of adequate postoperative analgesia in the morbidly obese cannot be overstated as early mobilization reduces the risk of thromboembolic and pulmonary complications. Neuraxial morphine has been shown to provide superior analgesia to intravenous or oral opioids after cesarean delivery, although it is associated with an increased incidence of pruritus and nausea.97,98 There is however a concern that obese parturients might be at a higher risk for neuraxial morphine-induced respiratory depression, but the data are limited. Studies in women undergoing cesarean delivery have reported an incidence ranging from 0% to 0.9% following neuraxial morphine administration.99 A large retrospective study performed at our institution of 5,036 women who received neuraxial morphine for postcesarean analgesia found no cases of respiratory depression defined as a need for naloxone administration or rapid response team involvement for the management of respiratory depression. The study population included 2,283 obese (class I and II) and 886 morbidly obese (class III) parturients.100 We therefore continue to use neuraxial morphine in this patient population with appropriate monitoring for 24 hours according to the newly released guidelines from the ASA and the American Society of Regional Anesthesia and Pain Medicine.101 Intravenous opioid patient-controlled analgesia can be given to patients who did not receive neuraxial morphine, but would likely be associated with more sedation and possibly an increased risk for respiratory depression.
A multimodal analgesic regimen including regular dosing of acetaminophen and nonsteroidal anti-inflammatory drugs can optimize postoperative analgesia and decrease opioid consumption and should be prescribed routinely unless contraindicated. Local anesthetic techniques might also be helpful in this patient population. Transversus abdominis plane block improves postoperative analgesia in patients who do not receive intrathecal morphine, but not in those who received intrathecal morphine.102 It therefore reduces pain scores and analgesic consumption in patients who received a general anesthetic and those who did not receive long-acting neuraxial opioids but provides minimal – if any – benefit in patients who have received neuraxial morphine. However, it must be remembered that this block provides analgesia only for incisional pain and not visceral pain, and therefore, the resultant analgesia is inferior to that of neuraxial morphine. Furthermore, it might be technically challenging in the morbidly obese parturient.42,103 It can also be used as a rescue analgesic modality for those who continue to experience severe incisional pain despite a multimodal analgesic regimen.104 Local anesthetic wound infiltration has also been found to be effective at reducing postoperative analgesic consumption in women undergoing cesarean delivery and might be helpful in the morbidly obese parturient, but data are limited about the efficacy of this technique in women receiving neuraxial morphine.105 Patient-controlled epidural analgesia could also be used for postoperative analgesia, but might delay patient mobilization.106
Considerations regarding postoperative analgesia for breast-feeding women
When considering the potential risk to the neonate from exposure to medications excreted in breast milk, it is important to assess the amount of medication excreted in breast milk and the therapeutic effect on the infant. The relative infant dose represents one of the most useful parameters for assessing lactation risk. It is the absolute infant drug dose expressed as a percentage of the maternal dose normalized by weight. A breast milk concentration <10% of the weight-normalized maternal dose has been considered arbitrarily as a safe level of exposure.107 The relative infant dose of commonly used analgesics in displayed in Table 4.
Table 4.
Analgesic agent | Relative infant dose (%) |
---|---|
Acetaminophen | 8.81 |
Ibuprofen | 0.65 |
Naproxen | 3.3 |
Celecoxib | 0.3 |
Ketorolac | 0.2 |
Hydromorphone | <1 |
Hydrocodone | 2.4 |
Morphine | 9–35 |
Oxycodone | 3.5 |
Gabapentin | 6.5 |
Notes: Relative infant dose is calculated by dividing the infant’s dose via milk (in mg/kg/day) by the mother’s dose (in mg/kg/day). Data from a previous study.107
Thromboprophylaxis
Venous thromboembolism is a leading cause of maternal mortality.108,109 In the United Kingdom, a decline in maternal mortality from thromboembolism in the 2000s was attributed to better recognition of patients at risk and increased use of thromboprophylaxis.12 However, in the most recent confidential enquiries report covering the years 2011–2013, venous thromboembolism was again the leading cause of direct maternal death.14 Obesity is a risk factor and is well represented in cases of maternal mortality from thromboembolism. For instance, 53% of women who died from venous thromboembolism in the most recent report were overweight or obese. While numerous guidelines exist for thromboprophylaxis in pregnancy, significant differences in the recommendations for thromboprophylaxis following cesarean delivery exist between the RCOG, ACOG, and American College of Chest Physicians as seen in Table 5. The most aggressive guidelines, especially in regard to thromboprophylaxis in obese women, are those of the RCOG, where all obese women will receive low molecular weight heparin. According to the American College of Chest Physicians guidelines, obesity is a minor risk factor, but in cases of an emergency cesarean delivery, all obese women should receive pharmacologic thromboprophylaxis. The ACOG guidelines do not have recommendations specific for obese parturients. It is important that institutional protocols are developed to provide adequate thromboprophylaxis in this high-risk patient population.
Table 5.
American College of Chest Physicians119 |
Recommendation: Low molecular weight heparin for one major or ≥2 minor risk factors (mechanical prophylaxis if contraindications to pharmacologic prophylaxis) |
Major risk factors |
Cesarean delivery with ≥1,000 mL postpartum hemorrhage |
Immobility >7 days antepartum |
History of venous thromboembolism |
Medical comorbidities: sickle-cell disease, systemic lupus erythematosus, heart disease |
Thrombophilia: antithrombin deficiency, Factor V Leiden, prothrombin G20210A |
Preeclampsia with fetal growth restriction |
Blood transfusion |
Postpartum Infection |
Minor risk factors |
Multiple pregnancy |
Obesity BMI >30 kg/m2 |
Emergency cesarean section |
Smoking >10 cigarettes/day |
Fetal growth restriction |
Thrombophilia: protein C or protein S deficiency |
Preeclampsia |
Royal College of Obstetricians and Gynaecologists120 |
Recommendation: Assess risk factors to decide high, intermediate, or lower risk |
Risk factors |
High risk (low molecular weight heparin for at least 6 weeks) |
History of venous thromboembolism |
Antenatal anticoagulation |
High-risk thrombophilia |
Low-risk thrombophilia with a family history |
Intermediate risk (low molecular weight heparin for at least 10 days) |
Cesarean delivery in labor |
BMI ≥40 kg/m2 |
Readmission or prolonged admission (≥3 days) postpartum |
Any postpartum surgical procedure except for perineal repair |
High-risk medical comorbidities: Systemic lupus erythematosus, cancer, heart or lung disease, inflammatory conditions, sickle-cell disease, nephrotic syndrome, IV drug user |
Other risk factors (treat as intermediate risk if 2 or more, if <2 factors consider as lower risk, early mobilization and avoid dehydration) |
Obesity: BMI ≥30kg/m2 |
Gross varicose veins |
Elective cesarean delivery |
Family history of venous thromboembolism |
Advanced maternal age (>35 years) |
Immobility such as paraplegia |
Parity ≥3 |
Current smoking |
Preeclampsia |
Multiple pregnancy |
Cesarean delivery |
Postpartum hemorrhage >1,000 mL or blood transfusion |
Labor >24 hours |
Preterm delivery |
Stillbirth |
American College of Obstetricians and Gynecologists121 |
Recommendation 1: Perioperative mechanical thromboprophylaxis for all women undergoing cesarean delivery |
Recommendation 2: Low molecular weight heparin for any of the following |
History of venous thromboembolism |
Family history of venous thromboembolism and a thrombophilia |
High-risks thrombophilias |
Abbreviations: BMI, body mass index; IV, intravenous.
Summary
The prevalence of obesity is increasing, and it is associated with significant comorbidities and increased obstetric, neonatal, surgical, and postoperative complications
Antepartum anesthetic consultation should be performed to evaluate comorbidities, counsel patients, and plan for care
A continuous neuraxial technique is the anesthetic technique of choice for cesarean delivery in the morbidly obese parturients
Adequate postoperative analgesia and thromboprophylaxis are critical in the postoperative period
Morbidly obese parturients are at high risk for OSA; therefore, they should be carefully monitored for postoperative hypoxemia resulting from airway obstruction and/or respiratory depression in the postoperative period
Footnotes
Disclosure
The authors report no conflicts of interest in this work.
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