Lumbar Transforaminal Endoscopy Instruments Guiding Ruler for ODM Acceptable HJ1024

Lumbar Transforaminal Endoscopy Instruments Guiding Ruler for ODM Acceptable HJ1024

1 Introduction:
If you are looking for minimally invasive surgery medical instruments with good quality, competitive price and reliable service. Wanhe medical is manufaturing these for you. We provide general and professional laparoscopic instruments with CE, FDA approved. 

2 Specifications
1 Adopt optinum stainless steel material
2 Corrosion resistant
3 Tough construction
4 Light weight and easy operation
5 Economic price and optimum quality
 

FAQ

What are the manufacturing processes of minimally invasive orthopedic surgical instruments?

The manufacturing processes of minimally invasive orthopedic surgical instruments mainly include the following aspects:

Structural and functional integrated design: In the design stage, the structure and function of the surgical instrument need to be integrated to ensure its efficiency and safety in actual operation.

CNC machining technology: Use high-quality materials and CNC machining technology to manufacture surgical instrument components. This technology can improve manufacturing accuracy and ensure that each component meets the industry standards of medical devices.

Intelligent flexible manufacturing method: Through intelligent flexible manufacturing methods, precise manufacturing of surgical instruments is achieved. This method can be adjusted according to different surgical needs, thereby improving the adaptability and flexibility of surgical instruments.

Multi-system integration and control strategy: Using multi-system integration and control strategies, various sensors, actuators and other components are integrated into surgical instruments to achieve more complex operations and higher levels of automation.

Precision and efficient manufacturing of amorphous alloys: Use amorphous alloy materials for precision and efficient manufacturing of minimally invasive surgical instruments. This material has good mechanical properties and biocompatibility, and is suitable for manufacturing high-precision surgical instruments.

Robotic-assisted surgical system: With the help of the robotic-assisted surgical system (RAS), combined with artificial intelligence and cutting-edge diagnostic imaging technologies (such as CT, PET, MRI, etc.), the precision and accuracy of surgery can be significantly improved.

The application of these manufacturing processes and technologies makes minimally invasive orthopedic surgical instruments safer, more reliable and more efficient in clinical applications.

What are the latest advances in the integrated design of structure and function in minimally invasive orthopedic surgical instruments?

The latest advances in the integrated design of structure and function in minimally invasive orthopedic surgical instruments are mainly reflected in the following aspects:

Material-structure-function integrated design: The research team of Professor Ding Xiaohong, Zhang Heng and Xiong Min from the School of Mechanical Engineering of Shanghai University of Technology has achieved important results in the direction of "integrated design of material-structure-function". Based on the homogenization method and topological optimization theory, they seek a collaborative design method for material microstructure and macroscopic distribution to achieve the multifunctional design requirements of the structure.

Multi-material, cross-scale structure-function integrated manufacturing: Professor Sun Daoheng's team at Xiamen University combines the flexibility of 3D printing with the easy flow and filling of liquid metal to open up a new method for manufacturing complex microstructures. This method provides a new method for the manufacture of structural-functional integrated flexible electronics, soft robots, antennas and other rich It lays the foundation for the manufacturing of multi-material and cross-scale structures and expands the application scope of metamaterials.

Optical-assisted technology and laser ablation technology: Against the background of the rapid development of artificial intelligence, AR technology and optical tracking and sensing technology have injected new vitality into precise minimally invasive interventional surgery. These technologies enhance the doctor's confidence in operation and make the operation more intelligent and precise.

Intelligent and remote orthopedic surgical robots: The next generation of orthopedic surgical robots are developing towards intelligence, remote control, master-slave control, and full-process assistance. This trend not only improves the accuracy of the operation, but also enhances the safety and efficiency of the operation.

New directions and progress in minimally invasive spinal technology: With the continuous deepening and development of the concept of minimally invasive surgery in spinal surgery, the introduction of radiofrequency control, robots and artificial intelligence has become a new trend. Fresh blood has been injected into minimally invasive spine surgery. The combination of medicine and engineering and interdisciplinary studies have gradually become new hotspots in this field.

What are the application cases of CNC machining technology in the manufacturing of minimally invasive orthopedic surgical instruments?

The application cases of CNC machining technology in the manufacturing of minimally invasive orthopedic surgical instruments include the following aspects:

Cervical fixation plate processing: At the 13th Implant Interventional Medical Device Innovation Summit in 2023, the speaker shared the case of using ultrasonic green CNC machine tools to process cervical fixation plates.

Hip patch processing: Also at the above summit, the processing of hip patches was also achieved through CNC technology.

Tibial platform processing: This is also a specific case mentioned at the 13th Implant Interventional Medical Device Innovation Summit.

Robot-assisted surgical instruments: CNC machine tools can The realization of complex geometries and tight tolerances makes it ideal for producing complex surgical tool designs. For example, robotic-assisted surgical instruments can be processed using CNC technology to ensure their precision and functionality.

Spinal trauma products: At the 6th ORTHOmaterials™ Orthopedic and Dental Implant Manufacturing Technology Forum, CNC machining and surface oxidation services for spinal trauma products were provided.

What is the specific implementation of intelligent flexible manufacturing methods in minimally invasive orthopedic surgical instruments?

The specific implementation of intelligent flexible manufacturing methods in minimally invasive orthopedic surgical instruments is mainly reflected in the following aspects:

Machine vision and positioning accuracy: According to, machine vision and positioning accuracy are important aspects that affect flexible production in intelligent manufacturing. In the manufacture of minimally invasive orthopedic surgical instruments, machine vision can be used for identification, measurement, detection and semantic understanding to ensure the accuracy and consistency of surgical instruments.

Multi-mode multiplexing flexible sensing system: It is mentioned that scientists have invented a multi-mode multiplexing flexible sensing system for minimally invasive surgery. This system solves the problems of modulus mismatch between traditional equipment and tissue, single function and insufficient device spatial resolution, and provides a more flexible and efficient solution for minimally invasive orthopedic surgery.

Design of flexible production line for intelligent manufacturing based on industrial robots: It is pointed out that the design scheme of flexible production line integrates system engineering design, electronic information technology, and microelectronics technology, solves the balance problem between high automation technology and high flexibility, and improves equipment utilization, which is of great significance for the production of minimally invasive orthopedic surgical instruments.

Materials and manufacturing challenges of laser scalpels: The materials, structures and manufacturing challenges of flexible fiber robot laser scalpels are discussed. Through the innovation of high-performance biocompatible materials and high-performance waveguide structure design, combined with advanced fiber manufacturing methods, the manufacture of stable transmission media is achieved, which provides technical support for the precise operation of minimally invasive orthopedic surgical instruments.

Research progress of flexible minimally invasive surgical robots: shows that the Minimally Invasive Center of Shenzhen Institutes of Advanced Technology, Chinese Academy of Sciences, has conducted in-depth research on the research and development route of dexterous surgical robots and the design mechanism of snake-like surgical robots, and has made new progress, which shows that the application of flexible minimally invasive surgical robots in minimally invasive orthopedic surgery is constantly improving.

Renaissance of production relations driven by digital technology: emphasizes that flexible production can achieve rapid production of multiple varieties and small batches through digital system control, which helps to improve the flexibility of enterprises, meet the personalized needs of customers, reduce costs, and enhance innovation capabilities, which has a positive impact on the production of minimally invasive orthopedic surgical instruments.

Robot Intelligent Manufacturing Project: describes the research work based on three flexible manufacturing processes (robot arc additive manufacturing, robot plate incremental forming, robot composite material weaving). The realization of these processes helps to connect and associate the data between the design and manufacturing ends of minimally invasive orthopedic surgical instruments, and uses parametric design, computer graphics, robot kinematics and other technologies to realize parametric models and robot motion control, thereby improving production efficiency and product quality.

Experimental verification of the performance of flexible minimally invasive surgical robots: In the experiment, the researchers conducted experimental verification of the prototype. By obtaining the motion trajectory information of the master hand (doctor control) and the slave surgical instrument in real time, the performance of the flexible surgical instrument under fine operation was verified, which provided an experimental basis for the practical application of minimally invasive orthopedic surgical instruments.

Flexible robots: It is mentioned that the emergence of flexible robots has created a new space for extreme minimally invasive diagnosis and treatment, which shows that the application prospects of flexible robots in minimally invasive orthopedic surgery are broad.

Flexible manufacturing: Production mode under diversified and customized needs: The characteristics of flexible manufacturing are elaborated in detail, including flexibility and customization, agility and efficiency, modularization and generalization, automation and intelligence, which are essential to meet the diversified and customized needs of minimally invasive orthopedic surgical instruments.

How can multi-system integration and control strategies improve the level of operation automation of minimally invasive orthopedic surgical instruments?

Multi-system integration and control strategies play a significant role in improving the level of operation automation of minimally invasive orthopedic surgical instruments. The following is a detailed analysis:

Multi-system integration can achieve more complex surgical operations by adopting master-slave design and multi-robot arm architecture. This design not only improves the flexibility and precision of the surgical robot, but also allows doctors to focus more on the key steps during the operation.

The modular design of surgical instruments allows doctors to choose the right tools according to specific needs, while force feedback technology provides real-time tactile feedback to help doctors better grasp the position and strength of surgical instruments, thereby improving the safety and efficiency of the operation.

High-precision three-dimensional imaging technology can provide detailed anatomical information for surgery, making surgical planning more accurate. This not only reduces the possible errors in surgery, but also improves the overall effect of the surgery.

Using intelligent algorithms for surgical planning can predict and avoid potential risks in advance. In addition, the application of remote surgery and virtual reality interaction technology allows doctors to perform surgical operations in different locations, further improving the flexibility and accessibility of surgery.

The methodological system of system engineering promotes the integrated innovation of multi-system control, enabling better collaboration between various subsystems. This integration method not only optimizes the performance of the overall system, but also reduces the complexity and maintenance cost of the system.

Control engineers can significantly improve the automation level of the device by using Lambda engineering tuning methods and strong causal PID control. These methods can ensure the stability and response speed of the equipment under normal working conditions, thereby improving the automation of surgical instruments.

How is the application effect of precision and efficient manufacturing technology of amorphous alloys in minimally invasive orthopedic surgical instruments?

The application effect of precision and efficient manufacturing technology of amorphous alloys in minimally invasive orthopedic surgical instruments is remarkable. According to, the research team established the theory, process and evaluation system of precision and efficient design, manufacturing and clinical application of zirconium-based amorphous alloy minimally invasive surgical instruments, including ultra-sharp stainless scalpels, non-destructive vascular clamps and precise and firm minimally invasive suture grasping forceps, which shows that amorphous alloys have good application prospects in minimally invasive surgical instruments.

It is further pointed out that although zirconium-based amorphous alloys present unique deformation and processing characteristics during high-speed processing, such as viscosity, crystallization, melting, burning and luminescence, these characteristics may pose challenges to the application of high-end minimally invasive surgical instruments, but through the study of the glass formation mechanism, formation ability and influencing factors of vacuum die-casting bulk medical zirconium-based amorphous alloys, these limitations can be overcome and their application in minimally invasive surgical instruments can be promoted.

The importance of advanced processing methods and multi-field coupling technology of amorphous alloy characteristics in breaking through the size limitations of amorphous alloy forming capabilities, as well as the use of advanced die-casting technology to achieve the manufacture of key precision structural parts, provided technical support for the application of amorphous alloys in minimally invasive orthopedic surgical instruments.

Various manufacturing and forming strategies and processing technologies of amorphous alloys were demonstrated, including thermal coupling manufacturing technology, ultrasonic vibration induced plasticity, low-temperature preparation technology and equipment, and atomic manufacturing concepts. These original breakthroughs made it possible to obtain decimeter-level giant amorphous alloys and complex and precise pure amorphous device structures, thereby enhancing the application potential of amorphous alloys in minimally invasive orthopedic surgical instruments.

The research content based on the structural characteristics and requirements of typical amorphous alloy parts such as 5G consumer electronic components, industrial robot reducer gears and bone screws, and bone plates was mentioned, which shows that the application of amorphous alloys in the field of medical devices is not limited to minimally invasive orthopedic surgical instruments, but also covers the efficient and precise manufacturing of other high-performance parts.

The research progress of amorphous alloy laser manufacturing technology and the development of new manufacturing and forming technologies were discussed separately, such as selective laser melting 3D printing technology, laser strip printing technology, fused filament manufacturing technology, ultrasonic manufacturing, thermoplastic manufacturing, etc. These technologies provide new ideas for solving the problems of size and room temperature brittleness of amorphous alloy materials, and further promote the application of amorphous alloys in minimally invasive orthopedic surgical instruments.

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