Magnetic Compression Anastomosis-Past Experience and Current Proposals for Further Development in Pediatric Minimally Invasive Surgery

Magnets in Paediatric Surgery

Magnetism, recognized in ancient Greece and China, is a fundamental physical force influencing numerous domains, including medicine and surgery. Historically, the medical use of magnets dates back over two millennia. As proof, the ancient Sanskrit medical textbook Sushruta Samhita describes the removal of a metallic arrow lodged in the flesh with a magnet. Modern uses span from diagnostic to therapeutic applications, including in paediatric surgery. High-field magnetism, utilized in Magnetic Resonance Imaging and Transcranial Magnetic Stimulation (TMS), shows promise for various medical conditions, including depression and neurodegenerative diseases. Despite controversy surrounding low-field magnetism, its potential remains a topic of interest. One of the applications in paediatric surgery that has been evaluated in a randomized controlled trial is magnetic acupuncture for supplementary treatment of postoperative pain. As most paediatric surgeons are well aware, the use of magnets also poses risks, particularly in children, where ingested magnets can cause severe gastrointestinal complications. Regulations have tightened in response to increasing cases of magnet ingestion-related injuries but more needs to be done to avoid injury. Currently, magnets play crucial roles in a variety of medical applications, including magnetic cell sorting and therapeutic devices. Notably, magnetic compression anastomosis, which uses magnets to facilitate luminal tissue joining, have seen significant advancements. Innovations include devices for oesophageal atresia repair, with recent studies showing promising results in animal models and early clinical trials. Future research should focus on optimizing magnetic devices, expanding their applications, and ensuring safety. The continued exploration of magnetism's effects on living tissues and the development of new magnetic technologies could revolutionize medical and surgical practices, particularly in paediatric care.

Comparative study on the establishment efficacy of four types of animal models of rectovaginal fistula in rabbits

Various surgical methods have so far been developed for treating rectovaginal fistula (RVF), each with its own advantages and disadvantages. The lack of standardized animal models of RVF is a major reason for the failure to establish a unified and effective surgical method for the treatment of RVF. This study aimed to explore the feasibility of an RVF animal model by magnetic compression and compare it with the traditional modeling method. Thirty-two female Japanese white rabbits were randomly divided into four groups: A, B, C, and D, based on how the rectovaginal septum was treated. The operation time, intraoperative blood loss, and model success rate of each group were determined. The experimental animals were euthanized 2 weeks after the operation. Their rectovaginal septum specimens were obtained. RVF was observed by the naked eye. The fistula size was measured. Histological changes of fistula were observed by hematoxylin and eosin and Masson staining. All rabbits completed the RVF model and survived 2 weeks after the operation. Groups A and B had no bleeding, while groups C and D had < 0.5 mL of bleeding. The magnet detached in 4-6 days in group A, while it remained in place for 2 weeks after surgery in group B. Only one group D rabbit had a plastic hose for 2 weeks after surgery. The RVFs of groups A and C healed by themselves. In group B, the fistula was well formed. In group D, fistula healing was observed in three animals and the diameter of the fistulas was only 2.82-4.64 mm in the other four animals. Groups B and D had a scar on the inner surface of fistulas. Our study shows that the magnetic compression technique based on the T-shaped magnet is a highly useful method to establishing a continuous and stable RVF model in rabbits.

Evaluation of a Magnetic Compression Anastomosis for Jejunoileal Partial Diversion in Rhesus Macaques

PURPOSE

Metabolic surgery remains underutilized for treating type 2 diabetes, as less invasive alternative interventions with improved risk profiles are needed. We conducted a pilot study to evaluate the feasibility of a novel magnetic compression device to create a patent limited caliber side-to-side jejunoileal partial diversion in a nonhuman primate model.

MATERIALS AND METHODS

Using an established nonhuman primate model of diet-induced insulin resistance, a magnetic compression device was used to create a side-to-side jejunoileal anastomosis. Primary outcomes evaluated feasibility (e.g., device mating and anastomosis patency) and safety (e.g., device-related complications). Secondary outcomes evaluated the device's ability to produce metabolic changes associated with jejunoileal partial diversion (e.g., homeostatic model assessment of insulin resistance [HOMA-IR] and body weight).

RESULTS

Device mating, spontaneous detachment, and excretion occurred in all animals (n = 5). There were no device-related adverse events. Upon completion of the study, ex vivo anastomoses were widely patent with healthy mucosa and no evidence of stricture. At 6 weeks post-device placement, HOMA-IR improved to below baseline values (p < 0.05). Total weight also decreased in a linear fashion (R2 = 0.97) with total weight loss at 6 weeks post-device placement of 14.4% (p < 0.05).

CONCLUSION

The use of this novel magnetic compression device to create a limited caliber side-to-side jejunoileal anastomosis is safe and likely feasible in a nonhuman primate model. The observed glucoregulatory and metabolic effects of a partial jejunoileal bypass with this device warrant further investigation to validate the long-term glucometabolic impact of this approach.