Temperature Distribution of Vessel Tissue by High Frequency Electric Welding with Combination Optical Measure and Simulation

Biological welding: a rapid and bloodless approach to circumcision

BACKGROUND

Circumcision is essential for male health, yet traditional methods are plagued by issues such as lengthy operative times, bleeding, and slow recovery. This study explores the application of biological welding technology in circumcision, assessing its potential as a safe and efficient novel surgical approach.

METHODS

In this study, 24 male adult dogs were randomly divided into two groups. The biological welding group underwent circumcision using biological welding technology, while the control group received traditional cut-and-suture circumcision. Clinical indicators such as surgical time, blood loss, pathological changes, and recovery time were observed and compared.

RESULTS

The biological welding group had a significantly shorter surgical time compared to the control group (2.33 ± 0.55 min vs. 27.06 ± 5.77 min, p < 0.001). The control group had an average blood loss of 22.35 ± 5.17 ml, whereas the biological welding group experienced zero blood loss (p < 0.001). Recovery time was also significantly shorter in the biological welding group (12.33 ± 3.50 d vs. 16.50 ± 2.57 d, p = 0.004), with a lower incidence of postoperative complications. Pathological analysis indicated that the thermal injury range in the biological welding group was controlled within 2 mm.

CONCLUSION

Biological welding technology demonstrated advantages in circumcision, including short surgical time, no bleeding, minimal thermal damage, and rapid recovery, proving to be a safe and effective novel circumcision technique with potential clinical application value.

Characteristics of Collagen Changes in Small Intestine Anastomoses Induced by High-Frequency Electric Field Welding

High-frequency electric field welding-induced tissue fusion has been explored as an advanced surgical method for intestinal anastomoses; however, intrinsic mechanisms remain unclear. The aim of this study was to investigate microcosmic changes of collagen within the fusion area, with various parameters. Ex vivo small intestine was fused with mucosa-mucosa. Four levels of compressive pressure (100 kPa, 150 kPa, 200 kPa, 250 kPa) were applied for 10 s in order to fuse the colons under a power level of 140 W. Then, collagen fibers of the fusion area were examined by fibrillar collagen alignment and TEM. Three levels of power (90 W, 110 W, 140 W) and three levels of time (5 s, 10 s, 20 s) were applied in order to fuse colons at 250 kPa, and then collagen within the fusion area was examined by Raman spectroscopy. Fibrillar collagen alignment analysis showed that with the increase in compression pressure, alignment of the collagen in the fusion area gradually increased, and the arrangement of collagen fibers tended to be consistent, which was conducive to the adhesion of collagen fibers. TEM showed that pressure changed the distribution and morphology of collagen fibers. Raman spectroscopy showed that increased power and time within a certain range contributed to collagen cross linking. Peak positions of amide I band and amide III band changed. These results suggested that higher power and a longer amount of time resulted in a decrease in non-reducible cross links and an increase in reducible cross links. Compression pressure, power, and time can affect the state of collagen, but the mechanisms are different. Compressive pressure affected the state of collagen by changing its orientation; power and time denatured collagen by increasing temperature and improved the reducible cross linking of collagen to promote tissue fusion.

Dynamic Impedance Analysis of Intestinal Anastomosis during High-Frequency Electric Field Welding Process

The success rate of the electrosurgical high-frequency electric field welding technique lies in reasonable control of the welding time. However, the final impedance value used to control the welding time varies due to differences in tissue size and the welding method during the welding process. This study aims to introduce a new reference indicator not limited by impedance size from dynamic impedance to achieve an adequate weld strength with minimal thermal damage, providing feedback on the tissue welding effect in medical power supplies. End-to-end anastomosis experiments were conducted with porcine small intestine tissue under seven levels of compression pressure. The dynamic impedance changes were analyzed, combined with compression pressure, temperature, moisture, and collagen during welding. The welding process was divided into three stages according to the dynamic impedance, with impedance decreasing in Period Ⅰ and impedance increasing in Period Ⅲ. Period Ⅲ was the key to high-strength connections due to water evaporation and collagen reorganization. The dynamic impedance ratio is defined as the final impedance divided by the minimum impedance, and successful welding would be predicted when detecting the dynamic impedance ratio over 4 (n = 70, p < 0.001). Dynamic impedance monitoring can be used as a macroscopic real-time prediction of the anastomosis effect.