1.Development and future of minimally invasive surgery in western China.
Chinese Journal of Gastrointestinal Surgery 2017;20(3):244-246
There are vast land and lots of people in western China, but the economy developing is relatively slow. However, the minimally invasive surgery was carried out firstly in China. Moreover, the type, number and difficulty of the minimally invasive surgery increased year by year. Especially, in the western area of China, Dr Zhou Zongguang, Yu Peiwu and Zheng Shuguo et al. have performed much pioneering work in laparoscopic surgery for rectal cancer, gastric cancer and laparoscopic liver resection. They led the standard development of minimally invasive in China. In the future, western China should continue to strengthen the standardized training of minimally invasive surgery, make great effort to carry out evidence-based research of minimally invasive surgery, provide evidences of high level of clinical application in minimally invasive surgery. At the same time, we should carry out the robotic and 3D laparoscopic surgery actively, leading the development of minimally invasive surgery more standardized and more widespread in western China.
China
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Digestive System Surgical Procedures
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methods
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trends
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Evidence-Based Medicine
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Hepatectomy
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methods
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Humans
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Laparoscopy
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methods
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Minimally Invasive Surgical Procedures
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education
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methods
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standards
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trends
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Rectal Neoplasms
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surgery
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Robotic Surgical Procedures
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Stomach Neoplasms
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surgery
2.Concurrent and predictive validation of robotic simulator Tube 3 module.
Jae Yoon KIM ; Seung Bin KIM ; Jong Hyun PYUN ; Hyung Keun KIM ; Seok CHO ; Jeong Gu LEE ; Je Jong KIM ; Jun CHEON ; Seok Ho KANG ; Sung Gu KANG
Korean Journal of Urology 2015;56(11):756-761
PURPOSE: We previously described a new procedure specific module (Tube 3) to allow the practice of vesicourethral anastomosis after robot-assisted radical prostatectomy. Herein, we report a predetermined proficiency level of Tube 3 and preliminary validation to explore whether this new module can lead to performance improvement in the da Vinci system. MATERIALS AND METHODS: Eight urology residents and three urology fellows performed the Tube 3 module 1 hour daily for 7 days. The learning curve was depicted through a scatterplot and the stable point was identified through the cumulative sum chart. Concurrent and predictive validations were performed with the da Vinci system. The mean time to complete the task and end product rating score between Tube 3 training group and no Tube 3 training group were compared. RESULTS: Concerning the learning curve, about 41 repetitions comprising about 5 hours were needed to achieve this stable point when the mean time to complete Tube of 384 seconds was set as a target. With regarding to the concurrent and predictive validation, there significant differences were evident in the mean time to complete 16 needle passages and the vesicourethral anastomosis and the end product rating score. CONCLUSIONS: The virtual reality (VR) simulator can yield sufficient improvement in technical performance in Tube 3 within 5 hours. The acquired proficiency can be transferable to the vesicourethral anastomosis using the da Vinci system.
Anastomosis, Surgical/methods
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Clinical Competence
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Computer Simulation
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Education, Medical, Graduate/*methods
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Humans
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Learning Curve
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Male
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Prostatectomy/*education/methods
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Robotic Surgical Procedures/*education/methods
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Simulation Training/methods
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Urethra/surgery
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Urinary Bladder/surgery
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User-Computer Interface
3.Current status of robotic surgery in Japan.
Korean Journal of Urology 2015;56(3):170-178
The da Vinci S surgical system (Intuitive Surgical) was approved as a medical device in 2009 by the Japanese Ministry of Health, Labour and Welfare. Robotic surgery has since been used in gastrointestinal, thoracic, gynecological, and urological surgeries. In April 2012, robotic-assisted laparoscopic radical prostatectomy (RALP) was first approved for insurance coverage. Since then, RALP has been increasingly used, with more than 3,000 RALP procedures performed by March 2013. By July 2014, 183 institutions in Japan had installed the da Vinci surgical system. Other types of robotic surgeries are not widespread because they are not covered by public health insurance. Clinical trials using robotic partial nephrectomy and robotic gastrectomy for renal and gastric cancers, respectively, have recently begun as advanced medical treatments to evaluate health insurance coverage. These procedures must be evaluated for efficacy and safety before being covered by public health insurance. Other types of robotic surgery are being evaluated in clinical studies. There are several challenges in robotic surgery, including accreditation, training, efficacy, and cost. The largest issue is the cost-benefit balance. In this review, the current situation and a prospective view of robotic surgery in Japan are discussed.
Cost-Benefit Analysis
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Esophageal Neoplasms/surgery
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Gastrectomy/*methods
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Gynecologic Surgical Procedures/methods
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Humans
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Japan
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Laparoscopy/*methods
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Nephrectomy/*methods
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Otolaryngology/methods
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Prospective Studies
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Prostatectomy/*methods
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Rectal Neoplasms/surgery
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Robotic Surgical Procedures/education/*trends
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Stomach Neoplasms/surgery
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Thymectomy/methods
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Thyroid Diseases/surgery
4.Era of enhanced recovery after surgery and robotic gastric cancer surgery.
Chinese Journal of Gastrointestinal Surgery 2017;20(5):495-499
Enhanced recovery after surgery (ERAS) has been rapidly developing by combining several techniques with evidence-based adjustments, including preoperative education, preoperative carbohydrate loading, epidural or regional anesthesia, early initiation of enteral nutrition, ambulation and multi-modal pain management. The core part of ERAS is to reduce and reverse surgical stress and therefore greatly improve clinical outcome. Under the guidance of ERAS, perioperative management of robotic gastric cancer operation should follow the basic principles of ERAS and clinical pathway to maximize the advantages of the robotic surgery. ERAS protocol is safe and feasible for patients undergoing robotic radical gastrectomy and it can reduce surgical stress, shorten hospital stay, improve quality of life and does not increase complications, whose mechanism may be associated with the reduction of inflammation and insulin resistance, the decrease of resting energy exposure, and the protection of mitochondria function. It is worth emphasizing that it is very important to fully understand the changes of pathophysiology during perioperative period, to strictly implement the ERAS pathway based on optimized evidence-based medicine, to cooperate closely with the multidisciplinary team, to observe and manage the postoperative complications dynamically by systemic classification. The improvement of ERAS program on the outcome of patients should be summarized regularly and the new interventional strategies should be evaluated further according to the international standard.
Anesthesia, Epidural
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Anesthesia, Local
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Convalescence
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Critical Pathways
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Enteral Nutrition
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Gastrectomy
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instrumentation
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methods
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rehabilitation
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Humans
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Length of Stay
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Pain Management
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Patient Education as Topic
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Postoperative Care
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methods
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standards
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Postoperative Complications
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prevention & control
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Preoperative Care
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Quality of Life
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Recovery of Function
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Robotic Surgical Procedures
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rehabilitation
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Stomach Neoplasms
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surgery