CHAPTER 74 Minimally Invasive Surgery
2 What are some currently practiced laparoscopic, thoracoscopic, or endoscopic procedures?
General surgery: Multiple procedures involving the appendix, colon, small bowel, gallbladder, bile ducts, stomach, esophagus, liver, spleen, pancreas, and adrenals. In addition, hernia repairs, diagnostic laparoscopy, adhesiolysis, gastric bypass, gastric banding, Nissen fundoplication, and feeding-tube placement can be performed laparoscopically
Gynecologic procedures: Diagnostic procedures for chronic pelvic pain, hysterectomy, tubal ligation, pelvic lymph node dissection, hysteroscopy, myomectomy, oophorectomy, and laser ablation of endometriosis
Thoracoscopic procedure/video-assisted thoracic surgery: Lobectomy, pneumonectomy, wedge resection, drainage of pleural effusions and pleurodesis, evaluation of blunt or pulmonary trauma, resection of solitary pulmonary nodules, tumor staging, repair of esophageal perforations, pleural biopsy, excision of mediastinal masses, transthoracic sympathectomy, splanchnicectomy, pericardiocentesis, pericardiectomy, and esophagectomy
Urologic procedures: Laparoscopic nephrectomy/nephroureterectomy, pyeloplasty, orchiopexy, cystoscopy/ureteroscopy, and prostatectomy
Neurosurgery: Ventriculoscopy, microendoscopic diskectomy, interbody fusion, anterior spinal surgery and scoliosis/kyphosis correction, and image-guided techniques to approach masses/tumors easily
Plastic/reconstructive surgery: Breast augmentation, brow lift, face lift, and liposuction techniques
4 What are the benefits of laparoscopy when compared with open procedures?
Intraoperative benefits: Decreased stress response with a reduction of acute phase reactants (C-reactive protein and interleukin-6), decreased metabolic response with reduced hyperglycemia and leukocytosis, decreased fluid shifts, better preserved systemic immune function, and avoidance of prolonged exposure and manipulation of abdominal contents.
Postoperative benefits: Less postoperative pain and fewer analgesic requirements, improved pulmonary function (secondary to decreased pain, decreased atelectasis, and earlier ambulation), improved cosmesis because of smaller incisions, fewer wound infections, decreased postoperative ileus, decreased length of hospitalization, and a quicker resumption of normal daily activities.
5 Why has carbon dioxide become the insufflation gas of choice during laparoscopy?
The choice of an insufflating gas for the creation of pneumoperitoneum is influenced by the blood solubility of the gas and its tissue permeability, combustibility, expense, and potential to cause side effects. The ideal gas would be physiologically inert, colorless, and capable of undergoing pulmonary excretion. Although a number of gases have been used (Table 74-1), carbon dioxide (CO2) has become the gas of choice since it offers the best compromise between potential advantages and disadvantages.
Advantages | Disadvantages | |
---|---|---|
CO2 | Colorless | Hypercarbia |
Odorless | Respiratory acidosis | |
Inexpensive | Cardiac dysrhythmias, rarely resulting in sudden death | |
Does not support combustion | ||
Decreased risk of air emboli compared with other gases because of its high blood solubility | More postoperative neck and shoulder pain resulting from diaphragmatic irritation (compared with other gases) | |
N2O | Decreased peritoneal irritation | Supports combustion and may lead to intra-abdominal explosions when hydrogen or methane is present |
Decreased cardiac dysrhythmias (compared with CO2) | Greater decline in blood pressure and cardiac index (compared with CO2) | |
Air | Supports combustion | |
Higher risk of gas emboli (compared with CO2) | ||
O2 | Highly combustible | |
Helium | Inert | Greatest risk of embolization |
Not absorbed from abdomen |