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The Fontan operation is the final stage of single-ventricle palliation that effectively separates the pulmonary and systemic circulations. The procedure connects the inferior vena cava directly to the pulmonary arteries or to the previously created superior cavopulmonary anastomosis, which allows all of the deoxygenated systemic venous return to flow directly to the lungs. The single ventricle then pumps oxygenated pulmonary venous blood to the systemic circulation. Baseline higher central venous pressure drives the Fontan circulation. There is an increased incidence of severe spinal deformities in children with congenital heart disease that will require corrective surgery, including posterior spinal fusion. Anesthesia for posterior spinal fusion in Fontan patients presents significant challenges, especially as the patient is in the prone position, which further exacerbates hemodynamic instability. This chapter discusses the perioperative management of a Fontan patient for posterior spinal fusion.
Supine orientation is the standard treatment position for radiation therapy for head and neck cancer. Some patients, however, cannot tolerate this due to pooling of secretions and airway concerns, and theoretically, treatment would be better tolerated in a prone position. Here, we described the first prone treatment setup and delivery for a patient with head and neck cancer.
Methods:
A 68-year-old male patient with inoperable locally advanced, T4aN0M0, squamous cell carcinoma of the maxillary sinus was simulated, planned, and treated in prone position due to sinus congestion.
Results:
Prone position was well tolerated by the patient, who then did not require daily anaesthesia for airway secretion management. The prone dosimetry demonstrated good target coverage and normal tissue sparing. His treatment setup was found to be reproducible throughout the course of therapy.
Conclusions:
We successfully demonstrated the feasibility of prone treatment position for patients with head and neck cancer who are unable to tolerate supine position due to unmanageable secretions. Consideration should be given to prone treatment when designing both radiation therapy protocols and individual treatment plans.
Coronavirus disease 2019 is an international pandemic. One of the cardinal features is acute respiratory distress syndrome, and proning has been identified as beneficial for a subset of patients. However, proning is associated with pressure-related side effects, including injury to the nose and face.
Method
This paper describes a pressure-relieving technique using surgical scrub sponges. This technique was derived based on previous methods used in patients following rhinectomy.
Conclusion
The increased use of prone ventilation has resulted in a number of referrals to the ENT team with concerns regarding nasal pressure damage. The described technique, which is straightforward and uses readily available materials, has proven effective in relieving pressure in a small number of patients.
Intra-operative positioning considerations are more important for the obese patient. The supine position causes a marked increase in intra-abdominal pressure, which results in a splinting effect of abdominal contents on the diaphragm. Awake, spontaneously breathing obese patients should be in a head-up position. The Trendelenburg position can be used to engorge neck veins to facilitate central venous cannulation. Spontaneously breathing obese patients generally do not tolerate the Trendelenburg position. In mild to moderately obese patients, respiratory mechanics, lung volumes, and oxygenation all increase when changing from the supine to prone position. Due to the difficulties moving and positioning mobidly obese (MO) patients, procedures routinely performed prone are often done in the lateral decubitus position. In the lithotomy position the patient is on their back with their legs and thighs flexed at right angles. MO patients are at special risk for rhabdomyolysis (RML), a potentially fatal post-operative complication.
We investigated the effects of prone position on respiratory dead space and gas exchange in 14 anaesthetized healthy patients undergoing elective posterior spinal surgery of more than 3 h of duration.
Methods
The patients received a total intravenous anaesthetic with propofol/remifentanil/cisatracurium. They were ventilated at a tidal volume of 8–10 mL kg−1, zero positive end-expiratory pressure and an inspired oxygen fraction of 0.4. Physiological, airway and alveolar dead spaces were calculated by analysis of the volumetric capnography waveform. Measurements were made in supine position (20 min after the beginning of mechanical ventilation) and 30, 120 and 180 min after turning to prone position.
Results
We found that the alveolar dead space/tidal volume ratio did not change. PaO2/FiO2 increased, although not statistically significantly. Dynamic compliance was reduced due to a reduction in tidal volume and an increase in plateau pressure.
Conclusions
Patients undergoing surgery in prone position for a duration of 3 h under general anaesthesia including muscle relaxation and mechanical ventilation without positive end-expiratory pressure have stable haemodynamics and no significant changes in the alveolar dead space to tidal volume ratio. Oxygenation tended to improve.
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