Anesthetic Considerations[8]

Patients usually undergoing single lung ventilation for a variety of procedures have underlying pulmonary disease. Patients should be evaluated comprehensively for their primary disease prior to performing the surgical procedure. Echocardiography may be useful in patients with cor pulmonale and may provide information about baseline cardiac function and reserve. 

A review of the relevant radiological anatomy on a case to case basis may help plan anesthetic management for single lung ventilation. This review will also allow proper preparation for patients who require specialized airway management. Presence of decreased baseline function due to large effusions, consolidations and atelectasis predispose patients to hypoxemia during the procedure, which may obviate the need to use higher fractions of inspired oxygen during the procedure. Presence of any bullae on the non-operative lung may provide clues to patients more likely to develop a pneumothorax in the perioperative period. Tumors need to be evaluated for the presence of any paraneoplastic syndromes as their presence may guide anesthetic management. 

Special considerations need to be placed on patients age as it is an independent risk factor which decides complication rates in patients undergoing pulmonary resection using single lung ventilation. Elderly patients have been found to have higher morbidity and mortality from pulmonary resections. Patients undergoing lung resections need additional testing to predict the risks involved in lung resection besides age. The most common tests used for such an assessment are FEV1 (forced expiratory volume-one second) and DLCO (diffusing capacity of the lungs for carbon monoxide).

FEV1 is a predictor of postoperative complications including death that may arise from undergoing pulmonary resection. A reduced preoperative FEV1 (less than 60 percent predicted) was found to be the strongest predictor of postoperative complications by multiple authors.[9][10]

DLCO has been studied as a factor that decides postoperative morbidity as well. DLCO measured as a percent of the predicted value and predicted postoperative DLCO is considered the most valuable predictors of mortality & postoperative complications in pulmonary resections.[11] The current ACCP guidelines do not provide numerical cutoffs for DLCO below which pulmonary resections should not be performed on patients. Instead, they give importance in determining the predicted postoperative (PPO) values. Assessment of the postoperative predicted values is the deciding factor in such cases and predicts the success of single lung ventilation. The interpretation of postoperative values are as follows:

• Patients who have both PPO FEV1 and PPO DLCO are greater than 60 percent do not need any further testing to undergo pulmonary resection. 
• Patients who have either PPO FEV1 or PPO DLCO less than 60 percent, however, have both values greater than 30 percent need additional testing with stair climbing or a shuttle walk test.
• If both values are less than 30 percent, patients should undergo a cardiopulmonary exercise testing with additional measurement of the maximal oxygen consumption.

The cut-off for the stair climb test is 22 meters. Incremental shuttle walk test distance greater than 400 meters denotes a maximal oxygen uptake of (VO max) greater than or equal to 15 mL/kg per minute. Such information may help the physician interpret the procedural risks and better clinical outcomes for patients undergoing single lung ventilation.

The most commonly used DLT is the left-sided DLT irrespective of which side requires the isolation; this is because placing a left-sided DLT is less challenging than the right sided one. This comparative ease is in part due to the short take-off of the right upper bronchus which leads to higher chances of dislodgement and or impaired ventilation of the right upper bronchus.

DLT placement technique: After inducing the patient with general anesthesia and confirming complete neuromuscular blockade, the following steps are taken to place a Left sided DLT

• A direct laryngoscopy using a Macintosh blade is used for laryngoscopy as the DLT is a large tube and this technique provides the maximum space for its insertion.
• The double lumen tube is introduced with a rigid stylet with the endobronchial curvature facing anteriorly.
• The rigid stylet ensures passage through the vocal cords. After the DLT passes through the vocal cords, the stylet is removed.
• The tube is then rotated by a 90 degrees angle anticlockwise to the left until the blue bronchial lumen faces left and tracheal lumen faces right.
• The next step involves either advancing the tube further until we meet resistance or using a fibreoptic bronchoscope to guide further placement. At this moment the tracheal cuff may be inflated and the connector attached to start ventilation.
• The shape of the left-sided DLT facilitates the bronchial cuff to be positioned in the left bronchus when advanced, but the DLT position should be confirmed with a fibreoptic bronchoscope to make sure that the tracheal lumen opening is above the carina and bronchial lumen is in the left bronchus. The bronchial cuff can now be inflated with 1 to 2 ml of air.
• Bilateral ventilation confirmation is by auscultation. Air entry should be audible in bilateral lungs at this point.
• Next, lung isolation is confirmed with selective clamping of the tracheal and bronchial lumens.
• When ventilation through the bronchial lumen completes, only the left lung should be inflated. 
• When clamping the bronchial lumen and ventilating through the tracheal lumen, only the right lung should inflate. 

Inability to perform a direct laryngoscopy is a contraindication to use of a DLT. In such a situation a bronchial blocker may be a suitable alternative.

Management of Hypoxemia[12]

During single lung ventilation, the ventilation to one of the lungs is interrupted. However, the perfusion is still present in the non-ventilated lung, which leads to an intrapulmonary shunt in the form of wasted perfusion to the non-ventilated lung. Protective mechanisms like hypoxic pulmonary vasoconstriction can counteract hypoxia to a certain degree. However, it is mandatory for the anesthesiologist to have measures in place for hypoxemia that may arise during single lung ventilation. Ventilation and perfusion (V- Q) matching plays a significant role in the management of oxygenation in patients on single lung ventilation. Some authors note that oxygenation is much better in the lateral decubitus position when compared to the supine position.

Classically, an inspired oxygen fraction (FiO2) of 1.0 has been advocated while performing one-lung ventilation. The rationale behind using a higher inspired fraction of oxygen is to have a safety margin. Higher Fio2 also leads to vasodilatation, and this may help increase the blood to the ventilated lung. Oxygenation at FiO2 of 1.0 can lead to atelectasis, so it is advisable to initiate with a Fio2 less than 1.0 and increase if needed.

If hypoxia develops during the performance of one lung ventilation the following step s must take place :

1. Check the position of double lumen tube/endobronchial tube/bronchial blocker. Changes in position may occur due to surgical manipulation. A repeat fiberoptic bronchoscopy through the tracheal lumen is useful in clinching the diagnosis. Additional steps involve suctioning the lumens of the tube to clear secretions which may also contribute to hypoxia.
2. FiO2 is increased to 1.0 to improve the amount of oxygen delivered.
3. Recruitment maneuvers are employed on the ventilated lung which is in the dependent position; this is done to overcome any atelectasis and thus help in oxygenation. PEEP may be applied to this lung to eliminate atelectasis, resulting in a decrease in the shunt thereby improving oxygenation
4. CPAP to the operative lung may be applied to decrease shunting and thus improve oxygenation. However, this does make the surgical procedure challenging to the surgeon, and should only be an option when other measures have not resulted in any improvement.
5. If the hypoxemia is severe and does not resolve with the abovementioned steps, the next best step is to revert to two lung ventilation. 
6. Severe hypoxemia should alert the anesthesiologist to look for causes like pneumothorax on the dependent lung. Chronic obstructive lung disease patients are more likely to experience such a complication. Intraoperative development of pneumothorax mandates aborting the surgical procedure and immediate insertion of a chest tube on the side of the pneumothorax. 

Body positions and ventilation

The lateral decubitus position: A change from the supine position to the lateral decubitus position brings about two physiological changes. Gravity increases blood flow in the dependent lung when compared to the nondependent lung. However, there is also an increase in the amount of ventilation to the dependent lung. This change arises from the more efficient contraction of the dependent hemidiaphragm as compared to the nondependent side. The dependent lung also lies in a more favorable part of the compliance curve. 

The lateral decubitus position under anesthesia: Under anesthesia, there is a decrease in functional residual capacity. The upper lobe moves under anesthesia to a more favorable portion of the compliance curve versus the lower lung which lies now on a less favorable portion of the compliance curve. Neuromuscular blockade contributes to abdominal contents pressing against the dependent hemidiaphragm thereby restricting ventilation. Open non-dependent lung leads to variation in the compliance and thus worsens ventilation-perfusion (V/Q) mismatch - thereby leading to hypoxemia.

Single lung ventilation leads to a right to left intrapulmonary shunt as the non-dependent lung continues to undergo perfusion with no ventilation, leading to a widened alveolar-to-arterial (A-a) oxygen gradient which may contribute further to hypoxemia. Factors leading to a decrease in blood flow to the ventilated lung additionally leads to hypoxemia. Such factors include:

• Low Fio2 leading to hypoxic pulmonary vasoconstriction in the dependent ventilated lung
• High mean airway pressures in the dependent ventilated lung
• Vasoconstrictor agents
• Intrinsic PEEP

Carbon dioxide elimination is usually unaffected in using one lung ventilation with adequate maintenance of minute ventilation. Both lungs may be affected independently by single lung ventilation.  The ventilated dependent lung is prone to ventilator-induced lung injury due to higher tidal volumes used. The non-dependent non ventilated lung is prone to injury by surgical trauma and ischemia-reperfusion injuries. Consideration of these physiological changes that occur in single lung ventilation is vital to the safe performance of the anesthetic technique and airway management.

Single lung ventilation aims at two separate goals - to maintain adequate oxygenation and to maintain lung isolation and lung protection. The challenges faced by an anesthesiologist in performing one lung ventilation arise from a combination of lateral decubitus positioning, open pneumothorax, and the anesthetic technique. The lateral decubitus position brings about physiological changes in the ventilation-perfusion matching, and this is subsequently altered under anesthesia by the effects of neuromuscular blockade, open thorax, hypoxic pulmonary vasoconstriction, surgical retraction, differential blood flow to the dependent and the non-dependent lungs.