Protective lung ventilation strategy

Treatment of PGD is supportive. Low tidal volume and high positive end-expiratory pressure (PEEP) levels may help improve oxygenation—these strategies are similar to the treatment of acute respiratory distress syndrome, as discussed below in the section on ventilator management.

Pulmonary vasodilators

The incidence of PGD is correlated with a marked decline in endogenous nitric oxide and cyclic guanosine monophosphate levels. Therefore, the administration of inhaled nitric oxide (iNO) during lung transplantation has been proposed as a possible therapeutic treatment to prevent or attenuate PGD pathogenesis. There is evidence that iNO administration during PGD can improve oxygenation and reduce pulmonary hypertension without altering systemic vascular resistance. There are currently no randomized controlled studies that demonstrate a reduction in morbidity [time to extubation, length of intensive care unit (ICU) or hospital stay] or mortality. Thus, it is difficult to recommend the routine use of prophylactic iNO in lung transplant surgery . Iloprost has also been used as a selective pulmonary vasodilator .

Extra-corporeal membrane oxygenation

Early institution of extra-corporeal membrane oxygenation (ECMO) has been shown to improve the overall outcome in some cohorts .

Veno-venous (VV) ECMO is an option for patients experiencing severe PGD when lung protective strategies cannot fully support the patient’s ventilator needs. This strategy allows for low tidal volume ventilation and minimal sedation . VV ECMO decreases the patient’s reliance on the lungs for gas exchange as oxygen delivery and carbon dioxide extraction occur in the ECMO circuit. The combination of VV ECMO and ultra-protective ventilation (3 cc/kg tidal volume) may limit ventilator-induced lung injury (VILI) and increase the number of ventilator-free days in lung transplant recipients with severe PGD. This concept has been studied in the ARDS population with encouraging results . Oxygen supply by the pulmonary arteries to the graft is crucial as bronchial arteries are lacking. Low saturation of the venous admixture may result in pulmonary and systemic hypoxia.

Veno-arterial (VA) ECMO is indicated in the case of hemodynamic instability or severe post-transplant pulmonary hypertension to protect the new lung from hyperperfusion resulting in pulmonary edema aggravated by the absence of lymphatic drainage, which hampers the clearance of the lung interstitium. A downside of VA ECMO therapy is that it shunts blood away from the lungs and can potentially decrease perfusion to the allograft itself. The resultant potential for graft hypoxia is of serious concern and can lead to PGD and possibly graft failure.

VVA ECMO is a combination of the two techniques that allows the possibility to regulate the amount of blood flow through the lungs and systemic oxygenation.

Retransplantation

Retransplantation raises many of the same considerations as the initial transplantation, with higher incidence of complications such as PGD, rejection, and infection . The most common reasons for retransplantation are bronchiolitis obliterans syndrome (BOS, 63%), PGD (15%), and acute rejection (4%) .

Atrial arrhythmias

Atrial arrhythmias (AAs) are a common occurrence after thoracic noncardiac surgery, with an incidence of 20–40% . The incidence of AAs is higher after lung transplant than after heart transplant, in part because of cardiac autonomic denervation and because of surgical manipulation of the pulmonary veins and left atrium .

AAs are not a benign finding. A recent meta-analysis examining the relationship between postoperative AAs and mortality in lung transplant recipients found that patients who had postoperative AAs had significantly higher perioperative mortality, longer hospital length of stay, more frequent requirement for tracheostomy, and higher mortality in years 1–6 .

Considering the possible adverse effect of AAs, aggressive treatment is warranted. The 2014 American Association for Thoracic Surgery guidelines suggest management that includes avoidance of postoperative beta blocker withdrawal, potential prophylaxis with calcium channel blockers or amiodarone in high-risk patients, an individualized approach to rate versus rhythm control, and anticoagulation for postoperative AAs >48 h in duration . Of note, Orrego et al. found increased mortality in patients whose postoperative AAs were treated with antiarrhythmics . This may reflect the association between amiodarone and increased mortality and LOS after lung transplantation.

Gastroesophageal reflux

There is a high prevalence of gastroesophageal reflux (GER) after lung transplantation . In the acute postoperative period, the concern with GER is that it may lead to THE aspiration of gastric contents and provoke damage in the lung allograft. The increased prevalence of GER in the advanced lung disease patient population appears to be associated with the presence of esophageal dysmotility along with a hypotensive lower esophageal sphincter in almost 80% of patients and associated with delayed gastric emptying in 44% of patients .

In addition to pre-existing GER, vagus nerve injury during surgery can cause delayed gastric emptying. As many as 90% of the post-lung transplant patients have experienced delayed gastric emptying . Cystic fibrosis patients have the highest prevalence of increased acid GER on monitoring (90%) . GER is less prevalent in patients with COPD and IPF (57% and 67%, respectively) .

The high prevalence of GER necessitates prophylactic therapy to limit gastric secretion. Commonly used agents are proton-pump inhibitors and H2 histamine receptor blockers. Prokinetic agents, such as macrolide antibiotics, may also play a role in inhibiting acid exposure to the allograft. In a cross-sectional study, patients receiving azithromycin experienced significantly fewer acid reflux events and had decreased esophageal acid exposure .

Preoperative fundoplication surgery prior to lung transplantation or in patients awaiting transplantation yielded no benefit in lung function .

Acute renal insufficiency

The risk factors for early postoperative acute renal failure following lung transplantation include the following :

• 1.
  

  Effective volume contraction.

  
  
• 2.
  

  Over-aggressive diuresis.

  
  
• 3.
  

  Ventricular dysfunction.

  
  
• 4.
  

  Acute tubular necrosis.

  
  
• 5.
  

  Acute interstitial nephritis.

  
  
• 6.
  

  Peri-operative sepsis.

  
  
• 7.
  

  Hypotension.

  
  
• 8.
  

  Radiographic contrast dye.

  
  
• 9.
  

  Nephrotoxic drugs (immunosuppressives, etc.).

  
  
• 10.
  

  Calcineurin inhibitors.

  
  
• 11.
  

  Atheroembolism.

Optimizing fluid management before and after transplantation has the advantage of preventing volume depletion and maintaining adequate levels of renal perfusion. Attention should be given to avoid all potentially nephrotoxic insults. There is no evidence that continuous dialysis has any advantage over intermittent dialysis in heart or lung transplantation . Renal insufficiency after lung transplantation increases the complexity of care and, not surprisingly, increases morbidity and mortality among lung transplant recipients .

Bleeding

Bleeding of >1 L overnight or 200 cc/h is considered excessive and will most likely result in re-exploration in the operating room. Blood transfusion has no effect on survival, but blood product administration can lead to transfusion-related acute lung injury . In addition, platelet administration may lead to thrombosis at vascular anastomoses, although no studies have shown an association between platelet administration and thrombosis in lung transplant patients. Interestingly, lung function at 6 months is significantly better for patients who were transfused with more blood products .

Thromboembolism

Because of absent collateral bronchial circulation and resultant risk of pulmonary infarct, pulmonary embolism can be a devastating complication to a lung transplant recipient. Thromboembolic complications occur at a rate of 12% during the first 3 years after lung transplantation. No studies have attempted to quantify the incidence of thromboembolic complications during the acute postoperative period, possible because the incidence is very low and DVT prophylaxis is standard. Subcutaneous heparin injections, 5000 U every 8 h, are an adequate dose for prophylaxis in most patients.

Surgical nerve injury

Phrenic nerve injury may result from stretching or direct instrumentation of the nerve during thoracic surgery. It typically manifests as hemidiaphragm paralysis. The incidence of phrenic nerve dysfunction following lung transplant varies from 8% to 30% . In a case series of 27 patients by Sheridan et al., the right phrenic nerve was most commonly injured (78%) and the incidence of injury was higher for bilateral lung transplantation. Phrenic nerve paralysis should be considered a cause of postoperative respiratory failure in the absence of graft failure or infection.

Sedation and pain considerations

Dexmedetomidine infusion can be started to ensure adequate comfort and avoid excessive sedation. Fentanyl at low doses (25–50 mcg/h) is added for pain control. This is done particularly in patients without a thoracic epidural for postoperative pain relief. The use of low-dose dexmedetomidine avoids emergence agitation and delirium and facilitates smooth tracheal extubation .

Postoperative pain control involves a multimodal approach. Ketamine, gabapentinoids, acetaminophen, and nonsteroidal anti-inflammatory medications have been shown to be effective.

If needed, pain control procedures such as placing neuraxial catheters (epidural, paravertebral catheters) may be performed postoperatively in the ICU. To safely place these catheters, the patient should be awake, oriented, and conversant. Thus, many believe that intravenous analgesics may be successfully continued as the procedural risk of placing these catheters may not be warranted.

Infection

VAP and ventilator-associated tracheobronchitis (VAT) are the most common types of infections, most dangerous to the allograft site, and temporally occurring as bacterial infection within the first several weeks after transplant . Specifically, gram-negative rods cause the majority of infections in the first month after surgery, followed by gram-positive cocci and then by viruses and fungi, causing infections most commonly between 100 and 400 days after surgery.

Interestingly, neither donor nor recipient colonization was significantly associated with a higher incidence of ventilator-associated respiratory infection. Even in studies of patients with cystic fibrosis, who are often colonized with multi-drug resistant organisms prior to surgery, there appears to be no association between preoperative colonization and postoperative respiratory infection. Patients who develop postoperative respiratory infections require longer mechanical ventilation (+43 days), longer ICU stay (+42.5 days), and longer hospital stay (+35 days) and experience higher in-hospital mortality .

Viral infections are uncommon in the immediate postoperative period, but the prevalence and impact of disease dictates the need to initiate prophylaxis in the early postoperative period. CMV infection and disease commonly occur in lung transplant patients and may play a crucial role in the short-term function of the allograft . CMV prophylaxis with valganciclovir or ganciclovir is typically instituted during the immediate postoperative period in patients who are susceptible to CMV infection depending on the donor and recipient CMV status.

Although bacterial and viral infections are more common, invasive fungal infections are associated with higher mortality . Risk factors for the development of fungal infection include IPF, older age, increased BMI, and increased lung allocation score.

Pneumocystis jirovecii prophylaxis with trimethoprim-sulfamethoxazole (TMP-SMX) is commonly instituted after all solid organ transplants because of the high incidence of pneumocystis pneumonia among immunocompromised patients . No consensus exists about the duration of prophylactic treatment, but prophylaxis should be started as soon as stable renal function is established in the immediate postoperative period—TMP-SMX is excreted through the kidney and can cause worsening renal function in the perioperative setting. Dapsone is a reasonable option if the patient is unable to tolerate TMP-SMX.

Antibiotic prophylaxis varies from center to center but typically consists of at least 72 h of gram-positive and gram-negative coverage commenced upon the induction of anesthesia .

Acute allograft rejection

The ISHLT reports that 34% of lung transplants encounter acute allograft rejection in the first year after transplant, with 89% of these episodes receiving some form of treatment . Graft rejection in the immediate postoperative period is believed to occur by one of two distinct mechanisms: acute cellular rejection (ACR) or antibody-mediated rejection (AMR). AMR is uncommon owing to cross-match screening. Acute rejection is rarely fatal, but it is a major risk factor for the development of BOS . Hyperacute rejection can still be seen in the first few hours of transplantation.

Patients may be asymptomatic; complain of dyspnea, cough, or sputum production; or experience acute respiratory failure. Findings of ground glass opacities, septal thickening, volume loss, and pleural effusions on high-resolution computed tomography (CT) scans suggest acute rejection . However, chest radiography and CT have low sensitivity and specificity for acute rejection . Bronchoscopy with biopsy is the most important diagnostic modality for acute allograft rejection .

Pulse steroids are used to treat ACR and AMR and have been shown to improve the clinical symptoms associated with acute rejection . In the setting of acute rejection, switching immunosuppression agents can be advisable. Several studies support switching from cyclosporine to a calcineurin inhibitor, typically tacrolimus . Alemtuzumab has been shown to be useful in patients who previously failed anti-thymoglobulin therapy .

AMR may be resistant to steroids, but in several cases, it responsive to plasmapheresis, suggesting an antibody-mediated process. Plasmapheresis is the best treatment for patients with pulmonary capillaritis unresponsive to steroids. Intravenous immunoglobulin (IVIG) may also be considered. IVIG causes B-cell apoptosis, reduces B-cell numbers, and may inhibit complement activation . Rituximab, an anti-CD20 monoclonal antibody that causes B-cell depletion, has been proven effective in the treatment of renal transplant recipients in conjunction with IVID . Rituximab plus IVIG can clear newly acquired antibodies, leading to freedom from BOS and better overall survival .