Intestinal anastomosis is an essential operative procedure in restoring the continuity of the gastrointestinal tract after resection of bowel lesions, such as necrotic intestinal segments, malignancy, inflammatory bowel disease, and trauma (1–4). In comparison with adult surgery, small intestine anastomosis is difficult and has a high risk of complications due to the smaller diameter of the intestine, inflammation, edema, or immaturity in the pediatric group, especially in premature infants (5–7).

To effectively reduce the occurrence of complications related to anastomosis and to improve patients' surgical outcomes, various modified anastomosis techniques have been developed (8, 9). Double-layer anastomosis may lead to increased tissue damage and impaired blood supply with possibly delayed healing. Single-layer anastomosis is proved to be effective and safe (10, 11). The drawback of hand-sewn single-layer anastomosis is its insecurity in case of high-risk intestinal anastomosis, such as an edematous intestine (11). When the stitches are tied, excessive tension placed on the suture might result in tissue cutting, even anastomotic leakage (12, 13). In the 1950s, Gambee (14) designed a single-layer anastomosis technique. After that, the Gambee stitch and its modification procedures have been widely accepted in gastrointestinal anastomosis (15–17). As an advantage, this technique can improve tissue healing because of minimal disturbance in the blood supply of the anastomotic site (14, 17). However, the Gambee pattern requires more needle manipulation, a modified Gambee stitch that includes the second stitch (through the mucosa on the opposite side to the submucosa), and the third stitch (through the submucosa to the mucosa of the first side) was described by Shureih et al. (16). This technique requires less needle manipulation, being easier to perform with the same good results. Gambee et al. (17) reported subsequent experiences, including the posterior half of the anastomosis sutured within the lumen and the anterior half sutured by the classic Gambee stitch. Its advantage is easy to perform. Liang (18) introduced another single-layer suture technique with simplicity and reliability.

Previous studies revealed that the single-layer continuous Lembert pattern anastomosis is faster to perform and as strong as a two-layer anastomosis (9, 10, 19). Slieker et al. (20) analyzed the literature and concluded that a continuous suture is preferable for completing an anastomosis owing to the technical and time-consuming nature, although clinical and experimental studies have not revealed that the continuous suture technique is superior to the interrupted one. Modified Gambee stitch should remain an option in bowel anastomosis (2). Herein, we describe an alternative asymmetric figure-of-eight single-layer suture method, aiming to create a model that is safe, feasible, and easy to perform. Its feasibility and effectiveness were evaluated in an in vitro porcine anastomosis model.

The anastomosis construction time was 18.08 ± 5.43 min in the figure-of-eight suture group and 19.95 ± 5.21 min) as shown in Table 1. The mean time of anastomosis construction was relatively short in the figure-of-eight suture group, although a significant difference could not be reached between the two groups.

When the intraluminal pressure reached 30 mmHg, one (16.67%) leakage at the anastomotic line occurred in the figure-of-eight suture group (24 mmHg), while two (33.33%) leakages (at the anastomotic line and suture hole at 24 and 28 mmHg, respectively) in the interrupted suture group. No significant difference was noted between the two groups (p > 0.9999).

The suture knots in the figure-of-eight suture group were 15.67 ± 3.30, which were significantly reduced in comparison with the interrupted suture group (22.17 ± 2.03; p = 0.0038). The mean cost of suture material was significantly decreased in the figure-of-eight suture group than that in the interrupted suture group (167.11 ± 35.20 vs. 236.45 ± 21.70 CNY, p = 0.0038), as shown in Table 1.

The extra- and intraluminal appearances of the two different anastomosis techniques were all tightly approximations, as shown in Figure 3.

Intestinal anastomosis for restoring gut continuity is an essential procedure (1–4). Owing to the smaller diameter and immature intestine in small infants and neonates, intestinal anastomosis remains a challenge for surgeons. The single-layer intestinal anastomosis has been proven safe and effective. However, its insecurity in case of high-risk intestinal anastomoses, such as an edematous intestine or severe bowel inflammation, might lead to a change of intraoperative strategy (5, 7, 11, 19). Based on intestinal anastomosis facileness and biomechanics, we designed an alternative asymmetric figure-of-eight suture and evaluated its effects through in vitro experiments on a porcine ileum specimen. Fresh bowel specimens were cleaned, manipulated, and monitored within 9 h after animal sacrifice to minimize the impact of the storage duration on the results (25, 37).

In the present study, the results showed that the asymmetric figure-of-eight suture required fewer suture knots in the anastomosis, which should save time by lesser needle manipulation and knot tying, although the time difference did not reach a statistically significant level owing to the small sample size. Rapid completion of an anastomosis with minimal trauma to the bowel is an important determinant of success in intestinal anastomosis, especially in those subjects that are suffering from a life-threatening gastrointestinal problem related to serious systemic condition, such as hemodynamic instability (38).

Anastomotic leakage is a severe postoperative complication that may lead to diffuse peritonitis, sepsis, and even life-threatening conditions (37, 39). Studies, including techniques, materials, and perioperative care have aimed to improve the outcome of intestinal anastomosis (20, 31, 40, 41). Intraoperative detection of the anastomosis quality and repairing defects without delay can significantly reduce the risk of postoperative leakage (31, 42).

Air testing, methylene blue perfusion testing, and intraoperative colonoscopy were selected to detect anastomotic leaks in both the in vitro experimental model and clinical research (2, 31, 42). In the present study, intraluminal leakage pressure with methylene blue perfusion was conducted to detect any potential anastomotic leakage as described by the previous study (42). Roumen et al. (32) reported that no adverse effects on the anastomosis occurred with the intraluminal pressure set at 40 cmH₂O (approximately 29.41 mmHg). Avoiding luminal overexpansion will decrease the risk of potential induction of suture tract leakage (43). Accordingly, the intraluminal leakage pressure value at 30 mmHg was set in the present study. One leakage in the figure-of-eight suture group and two in the interrupted suture group occurred at the suture hole or anastomotic line. Other research suggests that the leakage may be linked to the needle size or a technique related to tissue tearing (44). The first stitch in the asymmetric figure-of-eight suture technique included whole layers, and the second stitch covered three layers except the mucosal layer. Furthermore, the two stitches were not at a horizontal level, which may lead to a shorter intersuture distance and tension-free while tying the knot, resulting in a secure anastomosis. This alternative suture technique might minimize the tension and avoid cutting through the fragile tissue (45). Anti-tension of the anastomosis caused by suturing the submucosa twice might improve the security of the anastomosis. Early and tight mucosal apposition may protect the bowel anastomosis from luminal content stimulation and potential infection (46, 47). Although this single-layer suture technic for intestinal anastomosis was feasible, the knot must be carefully tied with adequate strength to avoid any possible tissue strangulation at the anastomotic site (30), and an additional Lembert's suture should be placed if needed (48).

This study has several limitations. First, it is an in vitro experiment with small sample size. Second, an in vitro study could not simulate the pathophysiological process of intestinal anastomosis, including intra-abdominal adhesion formation. Although the new synthetic absorbable sutures seem to generate less adhesion response, steps such as avoiding excessive suture materials could play a role in preventing adhesion formation (49–51). The effects of suture material exposure on adhesion formation need to be clarified in animal models. Third, all cadaveric ileum specimens were harvested from one pig, which might not cover the intestine specimens from the general population of pigs.

In conclusion, the preliminary in vitro study showed that the single-layer asymmetric figure-of-eight suture anastomosis technique was feasible and low-cost, but essentially it is a safe pattern for intestinal anastomosis, which presented less leakage than the single-layer interrupted suture technique.