Performing surgery is becoming more precise and less invasive thanks to the use of high-tech medical equipment. Robotic surgery and miniaturized instruments have made this possible. In the future, high-tech surgery may be performed on animals and human patients through virtual reality training. But what exactly is high-tech surgery? Here are three ways high-tech surgery is transforming the field of medicine. These techniques may sound like science fiction, but they can help physicians perform their jobs better than ever.
Less invasive procedures with more precision
In a world of ever-increasing complexity, surgical technology has advanced to a point where it is possible to perform complex procedures with fewer incisions and precise cuts. This advancement allows surgeons to plan procedures in a more precise manner and minimizes the amount of tissue damage. High-tech surgical equipment also allows surgeons to move their instruments more precisely, which reduces the risk of damaging critical brain functions.
One of the most advanced minimally invasive procedures today is robotic surgery. This technique uses a high-tech robot with a camera arm and several surgical instruments that operate on patients with minimal disruption to normal tissue. The surgeon sits at a console near the operating table, directing the robot’s movements. Compared to open surgery, the robot’s “hands” mimic the surgeon’s movements and provide the surgeon with a high degree of precision. The surgeon can also operate in areas with tight spaces, requiring fewer incisions and reducing pain and scarring.
Another example of a less invasive procedure is endoscopic surgery. This technique uses tiny instruments and a computer monitor to access organs inside the body. In contrast to open surgery, endoscopic surgery requires a much smaller incision than open surgery. This means that patients can have the procedure faster than ever before. Moreover, patients can enjoy the same benefits of the advanced surgical technology without the risks of traditional open surgery.
Advanced technology has made it possible for surgeons to perform less invasive procedures using smaller incisions and more precise instruments. This has many benefits for patients, including faster recovery time, reduced risk of infection, shorter hospital stay, and less pain. Furthermore, the use of robotic technology and other high-tech equipment allows surgeons to perform a wide range of surgeries with more precision and less risk. However, it does not come without its own risks and limitations.
Robotic surgery
Robotic surgery has the potential to help surgeons perform certain procedures with greater precision and safety. However, surgeons must have the training to use this new technology. Drs. Frank Candela and David Schreier are two such doctors. Their medical corporation, Candela and Schreier Medical Corporation, provides surgical care to the Simi Valley and San Fernando Valley communities in southern California. They specialize in robotic surgery. Read on to learn more about robotic surgery.
The robotic surgical system features a 3D camera and tiny instruments. The camera magnifies the operative field in high definition and provides the surgeon with a clear view of the procedure site. The instruments are also able to rotate independently and in seven degrees of motion. These instruments help the surgeon perform intricate and delicate surgeries with greater precision and less pain. Because of their small size, robotic surgical instruments can fit through small incisions, so surgeons can perform complicated operations in tight spaces or with smaller incisions.
Compared to conventional open surgery, robotic surgery uses small surgical instruments that fit through tiny incisions. They are attached to three robotic arms which allow the surgeon to have maximum range of motion and precision. The instruments also feature a high-definition three-dimensional camera that magnifies body structures, guiding the surgeon’s actions during the procedure. Surgeons at NYU Langone operate the robotic instruments using finger and foot controls and a high-definition monitor.
The da Vinci robotic surgical system uses a minimally invasive approach. The robot’s tiny camera provides a high-definition view of the inside of the body. The robot’s tiny, flexible instruments provide greater control and precision. Robotic surgery has the potential to reduce pain, shorten hospital stays, and minimize the risk of infection and post-operative complications. The robotic technology has become an essential part of surgical treatment and is becoming increasingly common.
Miniaturized instruments
The development of miniature instrumentation for high-tech surgery has a number of advantages. For example, it is significantly smaller than comparable robotic platforms, and offers convenient table-mounting options. It is also able to perform multiple tasks, and has a single port for easy setup. However, its significant drawbacks include significant limitations in maneuverability and the lack of control offered by cable-driven systems. In addition, it is difficult to design flexible instruments compatible with miniaturized robots.
MIS devices are available in various sizes and have become extremely specialized. They can perform specific tasks in a short amount of time without needing a lot of technique from the surgeon. Miniaturized instruments are also increasingly being integrated with sensors. They can monitor blood flow, pressure, and electrical fields. In addition, these instruments can provide vital anatomical feedback. These advantages are important factors in attracting investment. However, many potential benefits of miniaturized instruments are still untapped.
The Da Vinci Xi Surgical System, currently available at South County Hospital, is one of the most sophisticated minimally invasive options available. The surgeons at this hospital have performed more than 2,000 procedures with the da Vinci. With the da Vinci, surgeons sit at an ergonomically designed console, which controls the robotic arms that insert the instruments. The surgeon can also view the procedure through a high-definition screen.
The miniaturized tools are also useful in accessing difficult areas. For example, an advanced miniaturized mechanical surgeon needs imaging capability, a delivery well for tiny surgical instruments, and a wireless pH monitoring system. Another feature of these miniaturized instruments is the ability to access small conduits inside the body. The tiny instruments are so small that they do not require sutures. The surgical tools can be used without sutures, promoting wound healing.
Another benefit of da Vinci is its ability to scale. Surgeons can easily calibrate the robot’s arm and wrist motions to fit their hand movements. In addition, their movements are mirrored by the robotic arm, which eliminates awkward and potentially dangerous hand-eye coordination issues. With the use of da Vinci, surgeons can perform complex surgical procedures with greater accuracy and control. This system is not yet ready to replace the human hand, but it is a valuable tool.
Virtual reality training
With the development of VR training programs, surgeons can learn to perform complex procedures virtually. Surgical theaters use a simulated brain model generated by magnetic resonance imaging (MRI). Students operate on a simulated brain using joysticks to control a realistic simulation. When increasing pressure on the joystick, the system visually moves a blood vessel. It is possible to connect several VR platforms to practice the same procedure with colleagues.
VR surgery training programs offer many benefits. The ability to interact with surgeons virtually reduces the learning curve and ensures accurate execution. Virtual reality tools also provide the opportunity to practice different techniques and develop muscle memory. As a result, surgeons with a higher degree of proficiency will be less likely to make mistakes during surgery. These tools are highly customizable, allowing medical professionals to customize the training sessions to their needs. Virtual reality can be used in conjunction with clinical training, as well.
Surgical simulations are an effective alternative to expensive cadaver training. They provide real-time feedback, and have sophisticated scoring systems that enhance self-learning. Using a virtual reality simulator allows trainees to practice different surgical skills without compromising patient safety. Although virtual reality training is not yet ready for full-fledged surgery, it can help surgeons practice and hone their skills before performing the procedure on real patients.
Medical students can practice new skills using the Osso VR system before performing actual surgeries. The software uses hand-sensors and a laptop to track the user’s movements. The camera can also measure the surgeon’s performance in real time. VR training for high-tech surgery can improve accuracy and speed. In addition to the training platform, the VR system also has a mastery meter, which measures the performance of trainees.
VR has many practical uses. More than any other field, VR has been helpful in medical education. Surgeons can train in remote locations in different areas of interest and are now recognized as valid training by accrediting bodies. With platforms such as Surgical Theater and SyncThink, surgeons can also learn different techniques remotely. Apart from simulation, these platforms may also contain reading material, data, and realistic operations.
High Tech Surgery Innovations
While we are always hearing about the latest high tech surgery innovations, how do we know which ones are really cutting-edge? This article looks at the Da Vinci Xi robot, the Globus Excelsius GPS, the TransEnterix Senhance scalpel, and Synaptive Medical’s BrightMatter. What do they have in common? And how do they change the way we think about surgery? Read on to find out.
Da Vinci Xi
Using the da Vinci Xi robotic system, Dr. Cribbins is able to perform intricate procedures with greater precision. The da Vinci Xi’s robotic arms offer a full 360 degree range of motion. A human wrist simply cannot provide this kind of range of motion. The robot also extends surgeons’ hands and magnifies surgical sites for enhanced visibility. This advanced technology reduces postoperative pain and minimizes tissue disruption.
The da Vinci Xi Surgical System allows for efficient chest and abdominal access. It is an expansion of the da Vinci System’s core features. The da Vinci Xi’s ergonomic design and wristed instruments translate surgeon movements into tiny instruments for enhanced precision. The immersive 3D-HD vision system virtually extends the surgeon’s eyes to see the surgical site. This new technology enables doctors to perform a range of surgeries in minimally invasive manners.
Despite the numerous benefits, da Vinci Xi surgery still comes with risks. While minimally invasive procedures have their risks, all surgeries can result in serious complications, including the need for hospitalization. These complications can be as simple as bleeding and infection. In severe cases, the patient may suffer long-term damage and function. If complications occur, they may be life-threatening or require extensive revision surgery. The da Vinci surgical system can also cause a patient’s recurrence of the same surgery.
Because the Da Vinci Xi robot uses 3D images, surgeons are able to see the surgical site more clearly than ever. With its small robotic arms, the robot can make smaller incisions than ever before, resulting in less blood loss and less pain. Furthermore, the robot mimics the tremor of the human hand. These characteristics make da Vinci Xi highly effective for a range of urologic surgeries.
Globus ExcelsiusGPS
The robotic navigation system, which uses GPS to guide the surgeon during spinal surgery, has transformed the way spine surgeries are performed. It was designed by Globus Medical Inc., a leading musculoskeletal solutions company. Over 20,000 spine procedures have been performed using the ExcelsiusGPS robot. This advanced technology makes it easier and safer for surgeons to perform complex spinal procedures. Dr. Roland Kent, the robotic navigation system’s surgeon, has used it in over 80 surgeries since it was first introduced to the market in April 2018.
The robot allows surgeons to perform more precise procedures. The robot helps them place implants and hardware more accurately, resulting in less bleeding and muscle damage. Additionally, this technology speeds up the recovery time for patients. The benefits of this advanced technology cannot be overstated. Using a robot in spine surgery is an excellent option for patients who have had previous surgeries. And because patients are able to recover faster and feel more comfortable after the procedure, it is well worth it.
The robot’s advanced navigation capabilities and robotics make it a viable alternative to traditional techniques. The Globus ExcelsiusGPS system allows surgeons to see anatomy more accurately than with a traditional surgical assistant. The system also helps doctors reduce the amount of radiation they have to absorb during a surgery. Consequently, surgeons can perform more complicated procedures, like knee replacements. With its unique technology, the robot can even reduce the risk of infections during spine surgery.
Another key feature of the ExcelsiusGPS system is that it does not use the interspinous clamp. Instead, it relies on a fiducial array and surveillance marker on the PSIS. The surgeon can see this data in real time and use the foot pedal to move the robotic arm to the desired position. The rigid robotic arm can bear significant force without displacement, allowing the surgeon to drill directly through the guide tube and eliminate the need for K-wires.
TransEnterix Senhance scalpel
The Senhance robotic surgery system was approved by the Japanese regulators for a wide range of procedures, including urology, laparoscopy, and some thoracic surgeries. The Japanese medical device market is worth $40 billion a year, with capital equipment spending of $5 billion. There are 8,400 hospitals in Japan, and 80 percent of them are private. Laparoscopic surgery is particularly prevalent in Japan, and the Senhance is approved for these procedures. As the only competitor to Intuitive Surgical, Senhance touts its haptic force feedback technology and reusable instruments. The Senhance Ultrasound is also a reusable device.
With the FDA’s approval, TransEnterix plans to bring artificial intelligence to the operating room. It has secured clearance for its Senhance laparoscopic system, which gives surgeons eye-tracking camera controls, 3D visualization, and haptic feedback. The system also pairs small instruments with high-tech camera systems. These features make Senhance an attractive buyout candidate for a broader healthcare company or a medical device market leader.
Despite its relatively recent arrival on the market, Senhance is far from a replacement for Da Vinci. The Da Vinci system is an ideal tool for laparoscopic surgeries, but Senhance is designed for the same purposes. While the Senhance has a few advantages over Da Vinci, it’s not intended to replace the robot in every application. It’s more suited for certain procedures, such as abdominal surgery, where less is more.
The Senhance system aims to improve surgical accuracy. Its advanced technology is built on traditional laparoscopic instruments and includes eye-tracking and force feedback to control the motion of the surgical tools. It is currently cleared for use in 2.7 million operations in the U.S. each year. It’s currently used by 100 surgeons globally, and has successfully completed 4,000 operations in various surgical specialties. The system is meant to improve patient outcomes and reduce costs.
Synaptive Medical's BrightMatter
The BrightMatter high-tech surgical solution from Synaptive Medical uses a robotic arm and highly detailed imaging to guide neurosurgeons during the procedure. The robot and its software also allow surgeons to avoid key brain structures during the procedure. The company’s innovative robotic arm uses a highly advanced robotic microscope that provides physicians with unprecedented detail during surgery. This robotic arm helps surgeons perform more complicated neurosurgical procedures with less risk to the patient.
The company’s brightMatter servo allows neurosurgeons to navigate 3D fiber tractography with precision, and a navigation planning system. It works in tandem with a system called BrainPath, which allows surgeons to access abnormal areas through a tiny hole in the skull. Synaptive Medical’s BrainPath is used in LGMC’s operating room, which was one of the first in the country to use the system.
In addition to the BrightMatter navigation system, the company also plans to launch its next-generation robotics platform, which lets surgeons view patient fiber tracts in real time. The fully automated digital microscope is attached to a robotic arm and follows the surgeon’s tools. It eliminates the need to manually manipulate optics, thereby ensuring superior surgical ergonomics and efficiency. The company is currently building an international office in Lausanne, Switzerland.
The new platform, which is currently under development at Packard Children’s Hospital, will allow doctors to see important anatomy during the procedure. The BrightMatter Guide will help surgeons navigate complex procedures, and the Servo will mount the optics platform on an automated positioning system. This will help the surgeons use the BrightMatter Guide and BrightMatter Drive to track surgical tools and externally aim light.
Synaptive Medical's Modus V
Synaptive Medical’s Modus V surgical microscope combines superior vision with minimally invasive procedures. Its five robotically assisted motions allow the surgeon to see more than just the anatomy of the tumor. Its optics feature a higher field of view, natural color reproduction, and improved depth of focus to ensure a clear view of key anatomical structures. The Modus V is equipped with advanced camera and illumination capabilities that give surgeons real-time intraoperative feedback.
The Modus V is a part of the BrightMatter platform, which includes the robotic medical device and software that maps white matter tracts in the brain. This software enables surgeons to create a three-dimensional map of the brain’s neural connections, a unique perspective for the operative environment. This helps surgeons plan and navigate the surgery with ease. Moreover, the system is designed to enhance surgical precision and reduce postoperative discomfort.
The company has also developed a new version of its Modus V robotic digital microscope, which includes 3D visualization and hands-free control. This device is an addition to the BrightMatter platform and is part of Synaptive Medical’s Modus high-tech surgical suite. The Modus V allows surgeons to perform less invasive surgeries and may even make previously inoperable diagnoses operable.
In addition to its new voice-activated control, the Modus V offers surgeons the option to view the surgical area in three-dimensional (3D). Additionally, it also has an automatic lighting system that allows the surgeon to see the surgical field. It is a sophisticated surgical tool and may be the first robot assistant. The Modus V can be used to perform brain, spinal, and neurosurgical procedures, as well as other complex surgeries.
