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In the field of modern surgery, the high-frequency electrosurgical unit (ESU) has become an indispensable tool due to its unique energy-based technology. By utilizing high-frequency electrical current to generate thermal energy, it enables precise tissue cutting and coagulation. Compared to traditional scalpels, it offers reduced bleeding, a clearer surgical field, and more refined operation. From general surgery to specialized fields such as neurosurgery, gynecology, and otolaryngology, the high-frequency ESU demonstrates outstanding clinical value.

Exploring the Working Principle of High-Frequency Electrosurgery

The core mechanism of high-frequency electrosurgery lies in converting low-frequency electrical current into high-frequency current ranging from 200 kHz to 3 MHz. This current forms a circuit between the active electrode (surgical pen) and the patient return electrode (grounding pad). When the current passes through tissue, the rapid oscillation of electrons generates frictional heat with cellular structures, instantly vaporizing intracellular water and enabling precise tissue cutting.

A key advantage is that high-frequency current selectively targets tissue without stimulating nerves or muscles, minimizing unwanted neuromuscular contractions. Simultaneously, the heat induces protein denaturation and small blood vessel coagulation, achieving rapid hemostasis. This dual functionality—cutting and coagulation—significantly enhances surgical efficiency and safety.

The Four Core Functions of High-Frequency Electrosurgery

The?Simon?High-Frequency Electrosurgical Unit?integrates four key functions into one system:?tissue cutting, coagulation, bipolar mode, and low-temperature ablation.

Cutting Mode

Delivers precise tissue dissection with clean incisions, minimizing thermal damage to surrounding structures.

Coagulation Mode

Instantly seals small blood vessels, significantly reducing bleeding and maintaining a clear surgical field.

Features a?blended mode?that combines cutting and coagulation for optimized surgical efficiency.

Bipolar Mode

Utilizes localized current flow for safe cutting and hemostasis in confined spaces (e.g., nasal cavity, larynx), reducing tissue adhesion risks.

Low-Temperature Ablation (60–80°C)

Revolutionizes minimally invasive ENT surgeries with?superficial thermal effects (1–2 mm depth).

Effectively reduces turbinate size, removes vocal cord polyps or laryngeal papillomas, while preserving mucosal function.

Advantages:

Minimal intraoperative bleeding

Reduced postoperative pain

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Faster recovery

Ideal for delicate procedures such as:

Hypertrophic turbinate reduction

Nasal polyp removal

Pharyngitis treatment

Resection of pharyngeal lymphoid follicles

External auditory canal tumor excision

Clinical Applications of High-Frequency Electrosurgery

High-frequency electrosurgical units (ESUs) are widely utilized across multiple surgical specialties, including general surgery, thoracic surgery, neurosurgery, orthopedics, gynecology, and otolaryngology. Whether in open or minimally invasive laparoscopic procedures, the?Simon?High-Frequency ESU?plays a pivotal role.

In?oncological resections, it not only ensures precise excision of pathological tissues but also seals lymphatic vessels, thereby reducing the risk of tumor cell dissemination and local recurrence.

Notably, the?Simon?ESU?features an?ergonomic design—surgeons can effortlessly adjust power settings via foot pedals or handpiece controls. This adaptability allows seamless transitions between delicate microsurgical dissections and efficient hemostasis of larger vessels (e.g., in hepatobiliary surgeries). Such versatility solidifies its status as an?"all-in-one surgical partner"?in modern operating theaters.

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Clinical Applications and Advantages of High-Frequency Electrosurgery

High-frequency electrosurgical units (ESUs) are extensively utilized across various surgical specialties, playing a pivotal role in both open and minimally invasive laparoscopic procedures. In tumor resection surgeries, they not only enable precise removal of pathological tissues but also effectively seal lymphatic vessels, significantly reducing the risk of tumor cell dissemination.

The?Simon?High-Frequency ESU?features an ergonomic design, allowing surgeons to effortlessly adjust power settings via foot pedals or handpiece controls to accommodate diverse surgical requirements. Moreover, it incorporates multiple safety mechanisms, including tissue impedance monitoring and automatic power adjustment. These advanced features ensure both precision in delicate procedures and reliability in complex general surgeries, substantially enhancing overall surgical safety.

Safety Protocols for High-Frequency Electrosurgery

While high-frequency electrosurgical units (ESUs) offer significant advantages, strict adherence to safety protocols is imperative. To prevent electrical burns caused by current conduction, ensure the patient's body does not contact any metal objects during the procedure. Special caution is required for patients with cardiac pacemakers due to potential electromagnetic interference risks.

Operators must receive professional training and strictly follow operational guidelines. Additionally, appropriate power parameters should be selected based on different tissue types to ensure optimal safety and efficacy.

Future Development Trends of High-Frequency Electrosurgery

With continuous advancements in minimally invasive technology, Simon's high-frequency electrosurgical units (ESUs) are achieving deeper integration with laparoscopic systems and surgical robots, driving the evolution of surgery toward greater precision and efficiency.

In single-port laparoscopic procedures, these ESUs enable precise operations through slender instrument channels. Coupled with intelligent energy platform adjustments, they significantly reduce thermal tissue damage while meeting the stringent hemostasis requirements of minimally invasive surgery.

As a core product of Simon?Medical, high-frequency electrosurgical devices exemplify ongoing technological innovation. Future developments will focus on:

Enhanced integration with robotic-assisted surgical systems

AI-powered real-time tissue response monitoring

Further minimization of lateral thermal damage

Expanded applications in ultra-minimally invasive procedures

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