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Decortication

Decortication is a surgical procedure that involves the excision of a restrictive fibrous layer, membrane, or peel from the surface of an organ, most commonly the visceral pleura surrounding the lung, to facilitate re-expansion and restore normal function. First described and performed by French surgeon Delorme in 1895 to treat chronic empyema, the technique has evolved into a cornerstone of thoracic surgery for addressing conditions that trap the lung and impair respiration. Primarily indicated for fibrothorax resulting from unresolved pleural infections, such as empyema caused by bacteria like Streptococcus pneumoniae, or from hemothorax, trauma, or inflammatory diseases like rheumatoid arthritis, decortication is performed when less invasive measures like chest tube drainage fail to resolve symptoms. In cases of malignant pleural mesothelioma, a variant known as pleurectomy-decortication removes tumor-involved pleural tissue while preserving the lung. The procedure can be conducted via open thoracotomy, which remains the gold standard for complete peel removal through a posterolateral incision below the sixth , or through minimally invasive approaches like (VATS) or robotic-assisted methods, involving small incisions and specialized instruments for piecemeal excision. Key intraoperative steps include evacuating any accumulated fluid or pus, meticulously dissecting the thickened pleura from the parenchyma while minimizing bleeding and air leaks, and placing postoperative chest drains to re-expand the and prevent recurrence. Success depends on the underlying condition, with optimal outcomes in younger patients without extensive parenchymal damage, often leading to improved forced (FVC) and forced expiratory volume in one second (FEV1). While thoracic decortication predominates in clinical practice, the term also applies in orthopedics to freshen non-union sites by removing sclerotic bone ends to promote , and in broader contexts to denote the removal of outer coverings from or fibers in . Potential complications include hemorrhage, , prolonged air leaks, and to adjacent structures like the or major vessels, necessitating careful patient selection and preoperative optimization of and control. Recovery typically involves intensive care monitoring, management for at least 48 hours, and pain control via epidural or nerve blocks, with most patients experiencing enhanced respiratory function post-recovery.

Overview

Definition

Decortication is a surgical that involves the excision of the thick fibrinous or fibrous peel from the visceral and parietal pleural surfaces, thereby enabling the underlying to re-expand and restoring ventilatory capacity. This intervention targets the restrictive layer of fibrous tissue that overlies the , chest wall, and , which can impair normal respiratory mechanics by preventing full inflation. The primary goal is to alleviate the mechanical constraint on expansion, improving overall pulmonary function without necessitating the removal of healthy tissue. In its primary application within thoracic surgery, decortication addresses scenarios of pleural fibrosis where a constricting peel has formed, such as in chronic inflammatory or infectious processes leading to trapped . The procedure is particularly valued for its ability to restore chest wall and facilitate rapid symptomatic relief, allowing patients to regain near-normal lung mechanics postoperatively. The term "decortication" derives from Latin roots "de-" (indicating removal) and "" (meaning bark or outer layer), originally describing the act of stripping away external coverings, as seen in botanical or agricultural contexts like removing husks from grains. In medical usage, this etymology aptly reflects the peeling away of pathological outer layers to uncover and rehabilitate the affected . Unlike pleurectomy, which entails the systematic removal of the pleural lining itself (parietal and visceral layers) to manage pleural diseases, decortication focuses on excising only the adherent, restrictive fibrous peel to preserve intact tissue and minimize postoperative complications. This distinction underscores decortication's emphasis on targeted peel removal for functional restoration rather than comprehensive pleural excision.

Historical Background

Decortication was initially described in the late for the treatment of , with independent reports by surgeons George Ryerson Fowler and Edmond around 1893–1895, focusing on the surgical removal of fibrous pleural peel to facilitate re-expansion in chronic cases. The technique gained prominence in the early 20th century specifically for tuberculous , a common complication of pulmonary before effective antitubercular drugs, as surgeons recognized its potential to address trapped lungs due to organized pleural effusions. A pivotal advancement occurred through the efforts of Evarts A. Graham, who in 1923 presented influential ideas on empyema management at the Clinical Congress of the , advocating for aggressive surgical intervention in chronic empyema, including decortication, to improve outcomes beyond simple . Graham's earlier leadership of the U.S. Army Empyema Commission during (1917–1918) had already transformed acute empyema care by emphasizing closed to avoid , reducing mortality from over 30% to 4.3% in streptococcal cases and establishing principles that informed chronic surgical strategies. Throughout the 1920s to , decortication primarily involved open approaches, with surgeons like Carl Eggers reporting in 1923 on 99 cases of chronic treated at Hospital, where approximately two-thirds achieved successful healing and lung re-expansion. This period saw the procedure's refinement for tuberculous and post-infectious , though high operative risks limited its adoption until better and antibiotics emerged. The experiences of , where clotted from penetrating chest injuries affected thousands of soldiers, dramatically accelerated decortication's use; military surgeons performed early evacuations and decortications to prevent chronic , leading to formalized protocols by the that standardized timing and indications for thoracic trauma-related cases. The evolution continued into the late 20th century with the advent of minimally invasive techniques. Video-assisted thoracoscopic surgery (VATS) for decortication was introduced in the 1990s, enabling smaller incisions and earlier intervention for organized empyema, which significantly shortened hospital stays and reduced postoperative pain compared to traditional open methods.

Indications

Primary Conditions Treated

Decortication is primarily indicated for chronic empyema, a condition characterized by a thick purulent collection in the pleural space following infections such as pneumonia or tuberculosis, which leads to a trapped lung due to the formation of a restrictive fibrous peel. In this pathology, the procedure involves the surgical removal of the purulent material and the adherent peel from the visceral and parietal pleura, allowing for lung re-expansion and effective drainage to alleviate respiratory compromise. Empyema accounts for approximately 95% of decortication procedures, with an incidence of complicated parapneumonic effusions progressing to empyema in 5-10% of hospitalized pneumonia cases, of which about 30% necessitate surgical intervention like decortication. Fibrothorax represents another key indication, involving post-inflammatory fibrosis that encases the and restricts its expansion, commonly arising from unresolved , , or prior . Decortication addresses this by meticulously peeling away the fibrous rind to restore lung volume and improve ventilatory mechanics, particularly in symptomatic patients with significant restriction. In malignant pleural , decortication is performed as part of pleurectomy/decortication (P/D), a that removes the tumor-involved parietal and visceral pleura while preserving the underlying to relieve symptoms like dyspnea and . This approach is favored over more radical procedures in select patients to achieve macroscopic complete resection and enhance . Additional conditions treated include post-traumatic , where organized clot and fibrinous adhesions trap the lung after thoracic injury, and decortication facilitates evacuation and re-expansion to prevent chronic restriction. Less commonly, it is applied in post-pneumonectomy syndrome with or iatrogenic featuring a restrictive peel, enabling drainage and functional recovery.

Patient Selection Criteria

Patient selection for decortication involves a thorough evaluation of clinical, diagnostic, and functional factors to ensure the procedure's benefits outweigh the risks, particularly in cases of or trapped where has failed. Ideal candidates demonstrate evidence of a restrictive pleural process on imaging, adequate pulmonary reserve, and absence of uncontrolled systemic issues, with decisions guided by evidence-based guidelines emphasizing timely to restore expansion. Imaging plays a central role in confirming suitability, beginning with chest X-ray for initial screening to identify , opacification, or volume loss suggestive of trapped . Contrast-enhanced computed tomography () is essential for detailed assessment, revealing trapped with visceral pleural peel thickness exceeding 1 cm, multiloculated effusions, or organized loculations that preclude full re-expansion despite drainage. These findings indicate stage III or chronic , where decortication can effectively remove the restricting peel. Functional assessment evaluates the patient's capacity to tolerate and postoperative recovery. Pulmonary function tests (PFTs) are required to assess ventilatory reserve. For patients with suspected malignancy such as , an FEV1 greater than 30% of predicted postoperative value may be considered. is performed to exclude significant cardiac dysfunction or that could exacerbate risks. For patients with suspected malignancy contributing to pleural disease, such as , staging includes positron emission tomography-computed tomography (PET-CT) to detect distant metastases and guide resectability. In infectious cases like , cultures from pleural fluid or are obtained preoperatively to identify pathogens and tailor antibiotics, ensuring control prior to surgery. A multidisciplinary approach is critical, involving review by a thoracic surgeon, pulmonologist, and infectious disease specialist to integrate , functional data, and clinical history for optimal decision-making. Recent evidence suggests that for organized (phase 3) , earlier decortication within 7.5 days of hospitalization may improve survival outcomes, though traditional guidelines recommend 4-6 weeks after the acute phase to allow peel maturation while avoiding excessive . Patients over 75 years or those with severe comorbidities, such as advanced (COPD), are generally poor candidates unless the potential for significant functional improvement clearly outweighs surgical risks, as assessed through comprehensive preoperative optimization.

Contraindications

Absolute Contraindications

Absolute contraindications to thoracic decortication represent clinical scenarios where the procedure carries an unacceptably high risk of futility, , or ethical violation, precluding its performance under any circumstances. These include conditions where re-expansion is impossible despite removal of the pleural peel and explicit barriers. Irreversible trapped lung due to severe underlying parenchymal destruction, such as advanced or bullous , constitutes an absolute because the cannot re-expand even after decortication, rendering the surgery ineffective and exposing the patient to unnecessary risks. This is typically confirmed preoperatively through or intraoperative trials showing failure to inflate the affected . Similarly, bronchial represents another absolute barrier, as it requires additional complex reconstruction beyond standard decortication, often necessitating instead. Finally, patient refusal or inability to provide represents an ethical absolute , rooted in the principle of , which mandates respecting competent patients' decisions to decline regardless of potential benefits. In scenarios of decisional incapacity without , proceeding violates legal and medical standards.

Relative Contraindications

Relative s to decortication encompass patient-specific factors that elevate risks, such as increased susceptibility to , , or prolonged recovery, but these may be mitigated through preoperative optimization, allowing to proceed if the potential benefits outweigh the hazards. Uncontrolled systemic infection, including active or untreated severe , is a relative due to the high likelihood of intraoperative dissemination of pathogens and exacerbation of multiorgan failure. Preoperative optimization to resolve is mandatory, and persistent instability may preclude proceeding. In cases of advanced with distant metastases (stage IV disease), decortication is a relative because it provides no meaningful survival benefit or local control in the context of widespread dissemination, focusing instead on palliative measures like or indwelling catheters for symptom relief. This applies particularly to metastatic or other primaries involving the pleura, where surgical morbidity may outweigh any potential gain. Severe hemodynamic instability, such as ongoing requirement for vasopressors or recent within the prior weeks, serves as a relative owing to the patient's potential inability to tolerate the physiologic stresses of general , one-lung , and potential fluid shifts during the procedure. Severe comorbidities, including uncontrolled , renal , or , heighten the likelihood of postoperative infections, complications, or delayed healing, though efforts to stabilize these conditions preoperatively—such as glycemic control or —can render the procedure feasible in select cases. Uncontrolled specifically correlates with higher 30-day mortality and wound infection rates following noncardiac surgeries like thoracic decortication, due to impaired and vascular integrity. Similarly, poor renal function independently predicts increased morbidity and mortality after decortication for parapneumonic , as it exacerbates fluid management challenges and multiorgan stress. further amplifies risks during the procedure, necessitating correction where possible. Advanced age or frailty, particularly in patients over 80 years with low (e.g., Eastern Cooperative Oncology Group score >2), represents a relative , as these individuals face prolonged recovery and higher complication rates from major thoracic surgery, yet outcomes can be favorable in carefully selected cases without making age an absolute barrier. Frailty screening in thoracic patients reveals diminished physiologic reserve, increasing vulnerability to postoperative , though multidisciplinary optimization may support proceeding with decortication. Bilateral pleural disease, involving contralateral involvement, raises cumulative operative risks and often necessitates staged procedures, serving as a relative that weighs against simultaneous intervention to avoid overwhelming pulmonary reserve. A recent acute event, such as within 2 weeks of or active , constitutes a relative due to heightened and instability, potentially warranting a delay to allow resolution and reduce intraoperative complications like excessive or incomplete expansion. Nutritional deficiency, evidenced by serum albumin levels below 2.5 g/dL, impairs and immune function, posing a relative that can be addressed through preoperative nutritional support, though it still elevates risks of dehiscence and in thoracic decortication. Low preoperative is associated with adverse outcomes in thoracic surgeries, underscoring the need for correction to thresholds around 3.5-4.0 g/dL for optimal . Additional relative contraindications include inability to tolerate single-lung ventilation, multiorgan failure, poor general status, and severe chest-wall , all of which increase morbidity but may be manageable with careful patient selection and preparation.

Surgical Procedure

Preoperative Preparation

Preoperative preparation for decortication focuses on optimizing condition, mitigating risks, and ensuring procedural safety, particularly in cases of thoracic or . In infectious etiologies, such as , broad-spectrum intravenous are administered for 48-72 hours prior to to sterilize the pleural space and reduce bacterial load; common regimens include combined with piperacillin-tazobactam to cover gram-positive, gram-negative, and pathogens like species and anaerobes, which are prevalent in 48% and 20% of culture-positive cases, respectively. Over 90% of with infectious decortication receive at least one preoperative dose, with regimens tailored based on culture results when available. Anesthesia evaluation is essential and involves multidisciplinary clearance for general anesthesia, emphasizing one-lung ventilation to facilitate surgical access. A double-lumen endotracheal tube or bronchial blocker is routinely placed for lung isolation in approximately 68% of cases, allowing selective ventilation of the non-operative lung while collapsing the operative side; this setup requires preoperative assessment of pulmonary function, including spirometry and arterial blood gases, to confirm tolerance. Epidural analgesia is often established preoperatively for postoperative pain control, reducing reliance on systemic opioids and improving respiratory mechanics in thoracic procedures. Arterial line placement and central venous access are planned intraoperatively but evaluated preoperatively based on patient comorbidities, such as those in infectious cases where 11% require mechanical ventilation support beforehand. Informed consent is obtained after detailed discussion of procedural risks, including , recurrence, and prolonged (up to 20-30% incidence in complex cases), as well as alternatives such as (VATS) versus open . Patients are advised that VATS may convert to open approach if adhesions are extensive, with expected hospital stays ranging from 7-14 days depending on stage and approach; consent explicitly covers potential if VATS is inadequate for complete decortication.01909-7/fulltext) Nutritional and respiratory optimization begins 2-4 weeks preoperatively to enhance outcomes in malnourished or compromised patients, common in chronic . spirometry training is initiated to improve and reduce postoperative , while is mandated at least 4-6 weeks prior to minimize airway reactivity and optimize oxygenation, as 35% of patients may require supplemental oxygen preoperatively. Enteral feeding via nasogastric tube is implemented if albumin levels indicate (e.g., <3.0 g/dL), aiming to replete protein stores and reduce complication rates by 20-30% in thoracic surgery cohorts. Surgical planning integrates preoperative imaging review to guide approach selection and port/incision placement, ensuring minimal invasiveness and complete peel removal. Contrast-enhanced computed tomography (CT) is standard to evaluate pleural peel thickness, lung entrapment, and loculations, informing VATS port sites (typically 2-3 ports in anterior approach: 8-10 mm camera port at 7th intercostal space, working ports at 5th intercostal mid-axillary line). For open procedures, CT identifies optimal posterolateral thoracotomy incision (5th-7th intercostal space); bronchoscopy may be performed to rule out endobronchial pathology, and blood products are cross-matched due to potential intraoperative blood loss exceeding 500 mL.

Operative Techniques

Decortication is performed using either video-assisted thoracoscopic surgery (VATS) or open thoracotomy approaches, selected based on the extent of pleural involvement and surgeon expertise. The procedure typically involves a multidisciplinary team including a thoracic surgeon and anesthesiologist. Overall operative duration ranges from 2 to 6 hours, depending on the approach and adhesions encountered. In the VATS approach, the patient is positioned laterally under general anesthesia with double-lumen endotracheal intubation to facilitate single-lung ventilation and lung collapse. Three small ports (approximately 1 cm each) are inserted: a camera port in the 6th or 7th intercostal space anteriorly, a working port in the 5th intercostal space mid-axillary line, and an optional third port posteriorly for retraction. Entry into the pleural space allows initial evacuation of fluid or pus using suction, followed by finger dissection to break loculations. Camera-guided dissection then proceeds meticulously from the lung apex to the base, employing graspers, curved ring forceps, scissors, and a peanut dissector to peel the visceral pleura while avoiding parenchymal injury. The lung is freed circumferentially, including separation from the diaphragm and mediastinum if involved, with intermittent reinflation to assess expansion. Hemostasis is achieved using cautery on bleeding sites, and any bullae are managed with endostaplers while air leaks are sealed with fibrin sealants. This minimally invasive method typically lasts 2-4 hours, though conversion to open thoracotomy occurs in 10-20% of cases due to severe adhesions. The open thoracotomy approach is employed for extensive or chronic disease, beginning with a posterolateral incision in the 5th intercostal space. Ribs are spread using a retractor to expose the pleural cavity, followed by systematic entry and evacuation of purulent material. The visceral pleura is peeled starting laterally or at fissures, progressing to the apex, diaphragm, and mediastinum as needed, with careful sharp dissection to preserve lung tissue. Diaphragmatic and mediastinal decortication involves protecting underlying structures like the phrenic nerve and avoiding deep penetration. Hemostasis is secured with cautery, and tools such as dissectors and forceps facilitate removal of the fibrous peel. This technique generally requires 3-6 hours and provides superior access for complete debridement in advanced cases.

Complications

Intraoperative Complications

Intraoperative complications during decortication primarily arise from the challenging dissection of adherent pleural and fibrotic tissues, potentially leading to significant bleeding, structural injuries, and physiological instability. These risks are heightened in approaches due to limited visibility and access compared to open thoracotomy, though both techniques share common pitfalls such as vascular disruption during peel removal. Management strategies emphasize rapid hemostasis, immediate repair, and contingency planning, including conversion to open surgery when necessary. Hemorrhage is one of the most frequent intraoperative issues, often originating from intercostal vessels, raw lung parenchyma exposed during peel dissection, or apical structures like subclavian vessels. In a retrospective cohort of 192 patients undergoing thoracic decortication, 32% required blood transfusions intraoperatively or immediately postoperatively, with 13% needing three or more units, reflecting substantial blood loss in complex cases. Mean intraoperative blood loss has been reported as approximately 1,830 mL in procedures for late-stage empyema. Management involves meticulous hemostasis using diathermy, bipolar forceps, or packing, with conversion to thoracotomy if bleeding obscures the field; blood products are transfused as needed to maintain hemodynamic stability. Airway injury, particularly in the form of bronchopleural fistula (BPF), can occur from excessive traction on inflamed bronchial tissues during decortication, leading to air leaks or direct communication between the bronchus and pleural space. Minor air leaks are common during the procedure as the lung expands post-peel, but larger defects risk BPF formation if not addressed promptly. Immediate repair is achieved with sutures, sealants, or pledgeted techniques to seal the site and prevent tension pneumothorax; the anesthesiologist may assist by inflating the lung to identify leak locations. While most leaks resolve spontaneously, intraoperative intervention reduces the likelihood of persistent BPF. Cardiac events, including arrhythmias and hypotension, may arise from mediastinal manipulation disrupting cardiac rhythm or from acute blood loss causing hemodynamic compromise. Intraoperative dysrhythmias are not uncommon during extensive decortication procedures involving pleural peeling, as seen in related thoracic surgeries like pleurectomy/decortication for malignancy. Hypotension is frequently linked to hemorrhage, with 22% of patients in one series requiring vasopressor support perioperatively. Continuous monitoring, including electrocardiography and invasive hemodynamics, is essential; transesophageal echocardiography (TEE) can aid in detecting pericardial injury or effusion if dissection extends near the heart, though specific use in decortication is guided by patient risk factors. Conversion to open thoracotomy is a key contingency for uncontrolled complications, most often due to dense adhesions obscuring VATS visualization or uncontrollable bleeding. In VATS decortication series, conversion rates range from 4.5% to 32.4%, with a meta-analysis reporting a mean of 17.3% across studies, particularly in chronic empyema cases with thickened pleura. This is planned preoperatively, with the operating room prepared for rapid thoracotomy to ensure patient safety without delay. Anesthesia-related challenges center on one-lung ventilation (OLV), which is employed in 68% of decortication cases using double-lumen tubes or bronchial blockers to facilitate surgical access. In patients with stiff, trapped lungs from fibrosis, OLV can be difficult, leading to hypoxemia or hypercapnia due to poor compliance and ventilation-perfusion mismatch. Cardiopulmonary bypass (CPB) is rarely required (<1% of cases) for severe pulmonary hypertension or refractory hypoxemia during OLV, reserved for exceptional circumstances where conventional ventilation fails. Close collaboration between the anesthesiologist and surgeon mitigates these risks through adjusted tidal volumes and protective ventilation strategies.

Postoperative Complications

Postoperative complications following decortication for thoracic empyema can significantly impact recovery and may require additional interventions. Common adverse events include infections, respiratory issues, and thromboembolic disorders, with overall morbidity rates reported around 39% in large cohorts. Infection remains a primary concern, manifesting as wound infections or recurrence of empyema. Empyema recurrence after surgical decortication can occur, often linked to persistent pleural spaces or incomplete debridement. Wound infections occur at lower rates, around 0.2% in analyzed databases. Prevention involves continued broad-spectrum antibiotics postoperatively, guided by culture results, and meticulous management of sterile chest tube drainage systems to minimize contamination risks. Treatment of recurrence typically requires reintervention, such as repeat thoracotomy with decortication or thoracoplasty, alongside targeted antimicrobial therapy. Prolonged air leak, defined as lasting more than 5 days, arises from tears in the during peel removal and has an incidence of 3.5-7.5% in patients undergoing . In specific populations, such as those with , rates can exceed 80%, though this is less common in . Management includes maintaining chest tube suction at -20 cm H₂O to facilitate lung re-expansion while monitoring for resolution, with most leaks closing spontaneously within weeks. Respiratory failure, often necessitating mechanical ventilation, occurs in 4.8-15% of cases, particularly in elderly patients or those with rapid lung re-expansion leading to pulmonary edema. Re-expansion pulmonary edema contributes to this by causing alveolar flooding due to increased capillary permeability after prolonged collapse. Treatment involves positive end-expiratory pressure (PEEP) ventilation to support oxygenation and diuretics to reduce fluid overload, with close monitoring in an intensive care setting. Atelectasis and postoperative pneumonia frequently stem from immobility and inadequate ventilation post-surgery, with atelectasis requiring bronchoscopy in about 3.2% of patients. These complications overlap with the underlying empyema but can be exacerbated by pain or residual pleural issues. Risk reduction strategies include early patient mobilization starting on postoperative day 1 and routine use of incentive spirometry to promote deep breathing and prevent collapse. Thromboembolic events, such as deep vein thrombosis (DVT) or pulmonary embolism (PE), affect approximately 0.4-3% of patients after thoracic decortication, influenced by immobility and hypercoagulability from infection. Prophylaxis with low-molecular-weight heparin (LMWH), initiated on postoperative day 1 once hemostasis is confirmed, is standard to mitigate this risk, combined with mechanical compression devices. If diagnosed, anticoagulation therapy is escalated, potentially prolonging hospital stay.

Recovery and Prognosis

Postoperative Care

Following thoracic decortication, patients are typically transferred to an intensive care unit (ICU) or step-down unit for initial monitoring, particularly in high-risk cases such as those with preoperative respiratory compromise, where stays may last 24-48 hours. Vital signs, including temperature, pulse, blood pressure, and oxygen saturation, are continuously tracked, alongside chest tube output and serial chest radiographs to assess lung re-expansion. Arterial blood gas analysis is performed periodically to evaluate oxygenation and ventilation status. Chest tube management involves the placement of one to two tubes—one at the apex and one at the base of the thoracic cavity—to facilitate drainage and prevent fluid or air accumulation. These tubes are connected to suction and monitored every 8 hours for air leaks and fluid output; they are generally removed when drainage is less than 200 mL per 24 hours, there is no air leak, and radiographic evidence confirms lung re-expansion, which typically occurs within 3-7 days postoperatively. Pain control employs a multimodal approach to optimize recovery and facilitate respiratory efforts, starting with thoracic epidural analgesia or patient-controlled analgesia (PCA) using opioids in the immediate postoperative period. Nonsteroidal anti-inflammatory drugs (NSAIDs) and intercostal nerve blocks with bupivacaine are often incorporated, with a transition to oral analgesics by postoperative day 3 as tolerated. Respiratory support focuses on early extubation, usually within 24 hours for stable patients, supplemented by oxygen via nasal cannula or face mask if needed. Incentive spirometry, chest physiotherapy, and encouraged coughing exercises (pulmonary toilet) are initiated promptly to promote lung re-expansion and prevent atelectasis; continuous positive airway pressure (CPAP) may be used in cases of persistent hypoventilation. Discharge criteria include stable vital signs, removal of chest tubes, tolerance of oral intake, absence of fever, and evidence of improved pulmonary function. Patients are typically discharged 3-7 days postoperatively, with follow-up appointments scheduled within 1-2 weeks for wound evaluation and repeat chest radiography. Air leak monitoring continues as part of complication surveillance until resolution.

Clinical Outcomes

Decortication for thoracic empyema demonstrates high success rates, with lung re-expansion achieved in 86-100% of cases depending on the surgical approach and patient selection. Video-assisted thoracoscopic surgery (VATS) decortication yields success rates of 95-99.8% for infection resolution and re-expansion, outperforming open thoracotomy in select studies with rates around 85-100%. Overall, surgical intervention resolves pleural infection in 88-99% of stage II empyema cases, with recurrence rates as low as 0.8-4.6%. Perioperative mortality for decortication in empyema ranges from 0-9%, with 30-day rates typically 2-4% in modern series; elective procedures generally show lower mortality than urgent cases. For malignant pleural mesothelioma treated with pleurectomy/decortication (P/D), perioperative mortality is similarly 2-4%, though overall survival remains influenced by disease stage. Functional improvements post-decortication for empyema include a 14-17% increase in forced expiratory volume in 1 second () and forced vital capacity () at 3-6 months, alongside reduced dyspnea on exertion in most patients. In contrast, P/D for mesothelioma results in significant declines in and (approximately 30% at 3 months), with no significant recovery by 12 months but persistent symptom burden in advanced cases. Long-term outcomes vary by etiology: for benign empyema, recurrence-free survival exceeds 70-95% at 1-5 years, with median overall survival often exceeding 5 years in uncomplicated cases. In mesothelioma P/D, 5-year survival rates range from 20-50%, with median overall survival of 21-34 months and 2-year recurrence-free rates around 37%. Key prognostic factors include timing of intervention, with early decortication (within 7-14 days of hospitalization or <3 months post-onset) associated with improved survival, lower recurrence, and better functional recovery compared to delayed procedures. Complete removal of the pleural peel enhances outcomes, while underlying lung disease or prolonged effusion duration (>1 month) predicts poorer prognosis and higher mortality.