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| Model | Name | Specifications |
| HF2016.65 | Trumpt valve trocar | Φ10.5mm |
| HF2016.66 | Trumpt valve trocar | Φ5.5mm |
| HF2016.67 | Trumpt valve trocar with protection, bloodless | Φ10.5mm |
| HF2016.68 | Trumpt valve trocar with protection, bloodless | Φ5.5mm |
| Package detail: | Poly bag and special shockproof paper box. |
| Delivery detail: | By air |
FAQ
The popularization and specialization of minimally invasive surgical techniques have made significant progress over the past few decades. From the initial cholecystectomy, minimally invasive surgical techniques have expanded to gastrointestinal, hepatobiliary and pancreatic, bariatric and metabolic, hernia and abdominal wall surgery and other fields, with the volume and complexity of operations gradually increasing. The development of this technology not only improves surgical outcomes but also reduces patient trauma and recovery time.
In terms of popularization, minimally invasive surgical technology has experienced a process from introduction to rapid development in China. Since the 1990s, after 10 years of exploration, it entered a period of rapid development after 2004, and gradually entered a mature platform period after 2015. Nowadays, minimally invasive surgical technology has become a standard surgical method in many hospitals, and more and more patients choose to receive minimally invasive surgical treatment. For example, laparoscopic technology, as a representative of modern minimally invasive surgery, has been carried out in China for more than 30 years and has been widely recognized and promoted.
In terms of specialization, the development of minimally invasive surgical technology cannot be separated from the drive of scientific and technological innovation. After more than 30 years of development, modern minimally invasive surgery represented by laparoscopic technology has gradually matured, various types of minimally invasive surgeries have become popular, and the difficulty of surgery is also increasing. In addition, the application of new technologies such as artificial intelligence, virtual reality, and next-generation mobile communication transmission has further promoted the professional development of minimally invasive surgical technology. For example, the establishment of the 5G Remote Precision Minimally Invasive Surgery Training Center has improved the diagnosis and treatment capabilities of relevant hospitals through advanced diagnosis and treatment technology and training of medical personnel.
In short, the popularization and specialization of minimally invasive surgical techniques benefit from scientific and technological progress and the continuous updating of medical concepts. In the future, with the application of more high-tech means, minimally invasive surgical technology will continue to play an important role in improving surgical results and reducing patient trauma.
There are significant differences in the popularization and specialization process of minimally invasive surgical technology in different countries, which are mainly reflected in the following aspects:
Popularization speed and penetration rate:
China: Minimally invasive surgery has become popular in China rapidly, and the penetration rate still has room for high growth. From 2015 to 2019, the compound annual growth rate (CAGR) of minimally invasive surgical procedures was 19.5%, and it is expected to reach 18.5% from 2020 to 2024. In addition, as of the end of 2019, approximately 4,400 hospitals in China (18.5% of the total) were able to perform minimally invasive surgeries.
Technological innovation and cooperation:
China: China continues to innovate in minimally invasive surgical technology. For example, Ruijin Hospital cooperated with Shanghai University of Technology to develop a mirror-holding robotic arm, which uses the "naked eye 3D" principle and eye tracking technology to improve surgical accuracy. In addition, the First Affiliated Hospital of Guangzhou Medical University proposed tubeless minimally invasive surgical technology for the first time in the world.
International level and leading position:
China: China's minimally invasive surgical technology has reached or is ahead of the international level. For example, minimally invasive surgery in China has been developed from scratch, and has advanced from the treatment of benign tumors to the treatment of malignant tumors, and has been widely used in many professional fields.
Global technology competition landscape:
Global: The technological competition landscape of the global minimally invasive surgical instrument industry shows that market concentration is not high, and CR10 (the sum of the market shares of the top ten patent applicants) shows a volatile downward trend. This shows that there are many companies participating in competition around the world and technological innovation is active.
Promotion and communication:
China: Through live broadcasts of surgeries, forums and salons, etc., China continues to disseminate minimally invasive technology and concepts, and links with provincial and municipal medical institutions across the country to promote the process of minimally invasive and homogeneous medical services.
In the process of popularization and specialization of minimally invasive surgical technology, China has shown rapid growth, continuous technological innovation and international cooperation, as well as international leadership in certain fields.
The latest scientific and technological innovations in minimally invasive surgical technology mainly focus on improving surgical accuracy and safety. The following are some specific developments:
Da Vinci surgical robot: Beijing Obstetrics and Gynecology Hospital has launched the latest generation of da Vinci surgical robot. This robot can improve the overall level of minimally invasive surgery, improve the stability and accuracy of surgery, and is effective in endoscopic minimally invasive surgery. Replenish. In addition, the da Vinci robot has significantly improved the accuracy and flexibility of minimally invasive gynecological surgery.
Minimally Robot: This robot provides high-magnification high-definition three-dimensional images to help doctors accurately position anatomy. Its high-degree-of-freedom mechanical simulation wrist can perform surgical operations without blind spots in a small anatomical space, and through hand tremor filtering technology, it can achieve more precise and efficient tissue dissociation operations, thereby improving surgical accuracy.
Artificial intelligence technology: BIT invented a hybrid tracking technology based on the intelligent fusion of "optical + electromagnetic + image" multi-source sensing. This technology improves the accuracy and robustness of real-time positioning of images, patients and equipment in space, thereby improving Safety and reliability of surgery.
Endoscopic video intelligent sensing: Gao Wenpeng's research group has made progress in the research of endoscopic video intelligent sensing in minimally invasive surgery, which improves the safety of surgical operations by reducing the cognitive load during the operation and providing reference for doctors' intraoperative decision-making. performance, reliability and efficacy.
Sub-millimeter accuracy: Using robots for surgery can improve accuracy to the sub-millimeter level, which means surgery is more accurate and avoids problems caused by human error.
Evaluating the impact of minimally invasive surgical techniques on patient recovery time and rehabilitation process can be analyzed in detail from the following aspects:
Recovery Time:
Minimally invasive surgery usually has a faster recovery time than traditional open surgery. Generally, minor minimally invasive surgeries can be discharged from the hospital 1-2 days after surgery, while more complex surgeries require 3-5 days of recovery.
The specific recovery time also depends on the type of surgery and the patient's physical condition. For example, simple minimally invasive surgeries such as inguinal hernia, appendectomy or cholecystectomy require 5-7 days of recovery after surgery. The wound heals within 7 days and the patient can return to normal work and light physical activities.
For larger minimally invasive surgeries, such as colorectal cancer or laparoscopic liver surgery, recovery time may be longer.
In special cases such as minimally invasive surgery for rhinitis, some patients can return to normal levels 1-2 months after surgery, while some patients may need 3-4 months.
Recovery process:
Minimally invasive surgery is completed through small incisions using instruments such as endoscopes, which reduces damage to organs and interference with organ functions, thereby speeding up postoperative recovery.
Early postoperative feeding and multimodal analgesia are important measures in the concept of enhanced recovery after surgery (ERAS), and these measures help promote patients' postoperative recovery.
As a new pain assessment tool, the 3D pain mapping system can better replace traditional evaluation methods and is of great significance for preoperative diagnosis, intraoperative pain monitoring, postoperative follow-up and surgical effect evaluation.
Individual Differences:
The patient's physical condition and type of surgery are important factors that affect recovery time. The recovery time for different types of surgery is different and related to the patient's own constitution and disease.
For example, there is no fixed time for lung cancer patients to return to normal after minimally invasive surgery. Some patients may return to normal 1 month after surgery, while others can gradually return to normal 2-3 months after surgery.
Minimally invasive surgical techniques significantly shorten the patient's recovery time and rehabilitation process by reducing damage to organs and accelerating postoperative recovery.
The current application status and future trends of minimally invasive surgical technology in the field of weight loss and metabolism are as follows:
Application status
Expansion of the scope of surgery: Minimally invasive surgical technology has expanded from the initial simple cholecystectomy to gastrointestinal, hepatobiliary and pancreatic, weight loss and metabolism, hernia and abdominal wall surgery, etc. The volume and complexity of surgeries have gradually increased.
Increased application of surgical robots: With the advancement of the economy, the development of science and technology, and changes in concepts, the application of surgical robots in bariatric and metabolic surgery has gradually increased.
Multidisciplinary comprehensive treatment: The advancement of minimally invasive surgical technology, the deepening of the understanding of the gastrointestinal tract and metabolic physiological mechanisms, and the application of multidisciplinary comprehensive treatment have made bariatric metabolic surgery more efficient and safer.
future trends
New surgical procedures and technologies continue to emerge: With in-depth research on the mechanism of bariatric metabolic surgery, new forms of digestive tract reconstruction and anastomosis will continue to emerge, further improving the effectiveness and safety of surgery.
Deepening of multidisciplinary comprehensive treatment: In the future, bariatric metabolic surgery will pay more attention to multidisciplinary comprehensive treatment, combining professional knowledge in endocrinology, nutrition, psychological medicine and other aspects to provide patients with more comprehensive treatment plans.
The specific role and effectiveness of the 5G Remote Precision Minimally Invasive Surgery Training Center are mainly reflected in the following aspects:
Technology sinking and promotion: Based on the multi-disciplinary minimally invasive innovative technology of the People's Liberation Army General Hospital, the training center sinks advanced diagnosis and treatment technologies to various military medical institutions, and improves the diagnosis and treatment capabilities of grassroots hospitals through training of medical personnel. This kind of technology sinking not only improves the diagnosis and treatment level of grassroots hospitals, but also alleviates the problem of medical treatment in different places.
Training and education: The training center held the first domestic minimally invasive surgical robot training class, aiming to improve the professional skills of medical staff through systematic training. This training model not only improves the operational capabilities of medical personnel, but also promotes the development of military telemedicine and remote combat trauma treatment.
High-quality medical services: Through the application of 5G technology, the training center can realize the sharing of high-quality medical resources, allowing patients to enjoy high-quality medical services at their doorsteps. For example, the Seventh Medical Center of the People's Liberation Army General Hospital and the People's Hospital of Pishan County, Xinjiang successfully implemented 5G ultra-remote robotic gynecological surgery, demonstrating the efficiency and feasibility of 5G remote surgery in practical applications.
Innovative application and exploration: The 5G Remote Precision Minimally Invasive Surgery Training Center is not only a platform for technology application, but also an important position for innovation in the medical industry.
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Company Name: Tonglu Wanhe Medical Instruments Co., Ltd.
Sales: Aiden
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