Postoperative neurocognitive disorders (PoNCDs), such as postoperative delirium and cognitive dysfunction or decline can occur after surgery, especially in older patients. This significantly affects patient morbidity and surgical outcomes. Among various risk factors, recent studies have shown that preoperative frailty is associated with developing these conditions. Although the mechanisms underlying PoNCDs remain unclear, neuroinflammation appears to play an important role in their development. For the prevention and treatment of PoNCDs, medication modification, a balanced diet, and prehabilitation and rehabilitation programs have been suggested. The risk of developing PoNCDs is thought to be lower in ambulatory patients. However, owing to technological advancements, an increasing number of older and sicker patients are undergoing more complex surgeries and are often not closely monitored after discharge. Therefore, equal attention should be paid to all patient populations. This article presents an overview of PoNCDs and highlights issues of particular interest for ambulatory surgery.

The application of extended reality (XR) technology is rapidly expanding in the medical field, including anesthesia. This review aims to introduce the current literature on XR utilization to help anesthesiologists adopt this technology in education and clinical practice. XR is useful for both knowledge acquisition and skill training in a wide range of settings, from students to medical professionals. One of its major benefits is harm reduction through simulation scenarios that allow for immersion in clinical situations and opportunities to practice procedures and tasks. These scenarios often involve both technical and non-technical skills, enabling clinicians to enhance their capabilities without risking patient safety. In clinical settings, XR can also be used with patients to increase familiarity with medical procedures, provide education, and reduce anxiety. XR can also serve as a distraction technique, diverting the patient’s attention from medical procedures and enhancing comfort, which may contribute to reduced opioid use. Although the potential benefits of XR in anesthesia have been reported in various educational and clinical contexts, challenges, such as limited financial reimbursement and restricted technical accessibility, remain. With further research and technological advancements, XR technology has the potential for widespread adoption in anesthesia practice.

The application of extended reality (XR) technology is rapidly expanding in the medical field, including anesthesia. This review aims to introduce the current literature on XR utilization to help anesthesiologists adopt this technology in education and clinical practice. XR is useful for both knowledge acquisition and skill training in a wide range of settings, from students to medical professionals. One of its major benefits is harm reduction through simulation scenarios that allow for immersion in clinical situations and opportunities to practice procedures and tasks. These scenarios often involve both technical and non-technical skills, enabling clinicians to enhance their capabilities without risking patient safety. In clinical settings, XR can also be used with patients to increase familiarity with medical procedures, provide education, and reduce anxiety. XR can also serve as a distraction technique, diverting the patient’s attention from medical procedures and enhancing comfort, which may contribute to reduced opioid use. Although the potential benefits of XR in anesthesia have been reported in various educational and clinical contexts, challenges, such as limited financial reimbursement and restricted technical accessibility, remain. With further research and technological advancements, XR technology has the potential for widespread adoption in anesthesia practice.

The application of extended reality (XR) technology is rapidly expanding in the medical field, including anesthesia. This review aims to introduce the current literature on XR utilization to help anesthesiologists adopt this technology in education and clinical practice. XR is useful for both knowledge acquisition and skill training in a wide range of settings, from students to medical professionals. One of its major benefits is harm reduction through simulation scenarios that allow for immersion in clinical situations and opportunities to practice procedures and tasks. These scenarios often involve both technical and non-technical skills, enabling clinicians to enhance their capabilities without risking patient safety. In clinical settings, XR can also be used with patients to increase familiarity with medical procedures, provide education, and reduce anxiety. XR can also serve as a distraction technique, diverting the patient’s attention from medical procedures and enhancing comfort, which may contribute to reduced opioid use. Although the potential benefits of XR in anesthesia have been reported in various educational and clinical contexts, challenges, such as limited financial reimbursement and restricted technical accessibility, remain. With further research and technological advancements, XR technology has the potential for widespread adoption in anesthesia practice.

The application of extended reality (XR) technology is rapidly expanding in the medical field, including anesthesia. This review aims to introduce the current literature on XR utilization to help anesthesiologists adopt this technology in education and clinical practice. XR is useful for both knowledge acquisition and skill training in a wide range of settings, from students to medical professionals. One of its major benefits is harm reduction through simulation scenarios that allow for immersion in clinical situations and opportunities to practice procedures and tasks. These scenarios often involve both technical and non-technical skills, enabling clinicians to enhance their capabilities without risking patient safety. In clinical settings, XR can also be used with patients to increase familiarity with medical procedures, provide education, and reduce anxiety. XR can also serve as a distraction technique, diverting the patient’s attention from medical procedures and enhancing comfort, which may contribute to reduced opioid use. Although the potential benefits of XR in anesthesia have been reported in various educational and clinical contexts, challenges, such as limited financial reimbursement and restricted technical accessibility, remain. With further research and technological advancements, XR technology has the potential for widespread adoption in anesthesia practice.