Original Article

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Journal of Minimally Invasive Surgery 2021; 24(4): 200-207

Published online December 15, 2021

https://doi.org/10.7602/jmis.2021.24.4.200

© The Korean Society of Endo-Laparoscopic & Robotic Surgery

Laparoscopic surgery: an effective and safe surgical method of pediatric inguinal hernia repair

Eun Jung Kim , Chaeyoun Oh , Jun Won Um

Department of Surgery, Korea University Ansan Hospital, Ansan, Korea

Correspondence to : Jun Won Um
Department of Surgery, Korea University Ansan Hospital, 123 Jeokgeum-ro, Danwon-gu, Ansan 15355, Korea
Tel: +82-31-412-4830
Fax: +82-31-412-4807
E-mail: junwonum@korea.ac.kr
ORCID:
https://orcid.org/0000-0002-0506-0235

Received: August 11, 2021; Revised: October 22, 2021; Accepted: October 31, 2021

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/4.0/) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

Purpose: Inguinal hernia (IH) repair is very commonly performed in children. While open repair (OR) is the standard approach, laparoscopic repair is increasingly used. This study was aimed to investigate safety and feasibility of laparoscopic repair of pediatric IH compared to OR.
Methods: We retrospectively enrolled 105 pediatric patients with IH repair between January 2011 and October 2019. The laparoscopic procedures performed were laparoscopic percutaneous extraperitoneal closure (LPEC), and three-port mini-laparoscopic repair (TLR). The OR was performed as per usual technique.
Results: Thirty-nine patients underwent OR, 16 LPEC, and 50 TLR. The preoperative laterality of IH was 45 patients (42.9%) on the right side, 50 (47.6%) on the left side, and 10 (9.5%) on both sides. It was, however, diagnosed postoperatively in 27 patients (25.7%) on the right side, 38 (36.2%) on the left side, and 40 (38.1%) on both sides. Of the 63 patients who presented with unilateral IH in the laparoscopic groups, 32 (50.8%) had synchronous contralateral patent process vaginalis (PPV) which were simultaneously repaired. This was significantly more common in children under 3 years of age. Operative time in unilateral or bilateral repair was significantly shorter in the laparoscopic repair groups (p < 0.001). Ipsilateral recurrence was not observed in any group. Metachronous contralateral IH occurrence was not significantly different between groups.
Conclusion: Laparoscopic IH repair may have benefit in terms of shorter operation time and diagnosis of unpredicted contralateral PPV compared to OR.

Keywords Inguinal hernia, Pediatrics, Herniorrhaphy, Laparoscopy

Inguinal hernia (IH) repair is the most common surgery performed in children. In children under the age of 18, the incidence of IH is 0.8% to 5% at full term and up to 30% with low birth weight and premature births [1]. Pediatric IH is caused by persistent patency of the vaginal process, unlike IH in adults, which is due to weakness of the abdominal musculature. Therefore, prosthetic mesh reinforcement is necessary in adults, whereas high ligation is sufficient in children [2].

High ligation using open repair (OR) was described over 100 years ago, and the recurrence rate in recently published reports is very low, ranging from 0% to 6% [3,4]. However, complications such as spermatic cord injury, vas deference injury, hematoma, surgical site infection, iatrogenic cryptorchidism, and testicular atrophy can be seen [5]. The laparoscopic approach was first reported for pediatric IH repair in 1992 [6]. Although OR is still widely performed, laparoscopic IH repair is being increasingly used in many institutions, even in neonates, where minimally invasive surgery is mainstream. It has been recently reported that, compared to OR, laparoscopic bilateral IH repair is associated with shorter operation time and fewer wound infections in infants [7]. This study was aimed to investigate safety and feasibility of laparoscopic repair of pediatric IH compared to OR in a single center.

This study was conducted on 105 children and adolescents aged <19 years who underwent IH surgery at Korea University Ansan Hospital from January 2011 to October 2019. We compared OR and laparoscopic repair of pediatric IH performed in a single center and further analyzed the results of two laparoscopic techniques, laparoscopic percutaneous extraperitoneal closure (LPEC) and three-port mini-laparoscopic repair (TLR). It is our policy to conduct only one outpatient follow-up visit approximately one week after the operation, with no further follow-up unless indicated. Therefore, all subjects were contacted via telephone interviews to determine their recent status. Telephone interviews were attempted in October 2019 with 105 patients, and 29 out of 39 patients (74.4%) in the OR group responded. All 16 patients in the LPEC group responded (100%), and 46 out of 50 patients (92.0%) in the TLR group responded. The data were collected retrospectively through medical charts, such as surgical records and anesthesia records.

OR was performed by two surgeons. LPEC has been performed since 2015, and TLR has been performed since 2018. In OR, high ligation was performed only on the symptomatic side, whereas in laparoscopic repair, bilateral repairs were performed when contralateral patent processus vaginalis (PPV) was confirmed. General anesthesia was used for all operations. For the OR, a 1 to 2 cm incision was made in the symptomatic inguinal area, the hernia sac was retrieved, the cord structure was detached, and high ligation was performed. LPEC was performed as previously reported [8]. A 5-mm camera was inserted through the umbilicus, and one 3-mm port was placed in the suprapubic area, through which one assisted laparoscopic instrument was inserted. After checking the patency of the processus vaginalis, an incision of approximately 1 to 2 mm was performed above it. Subsequently, preperitoneal sutures were placed first on the medial side, from 12 o’clock to 6 o’clock of the internal inguinal ring, using a 21-gage spinal needle. At that time, an assisted instrument was used to direct the vas deference and gonadal vessels down the suture line. The needle was removed after coming out in the direction of 6 o’clock, and the 4-0 prolene was pushed down to form the loop. The same process then started in the opposite direction, from 12 o’clock to 6 o’clock, with the needle coming out at 6 o’clock. The sufficiently delivered prolene was caught with a loop and came out, and a tie was carefully performed at the incision site. At that time, the operation was concluded after checking whether the internal inguinal ring was sufficiently closed through the camera (Fig. 1). TLR was performed using the laparoscopic sac transection and peritoneal closure method [9]. We performed the procedure using a 3-mm camera and two 3-mm instruments. After complete transection of the hernia sac at the level of the internal inguinal ring, the peritoneum around the ring was sutured with a 4-0 prolene suture to close it (Fig. 2).

The nonparametric variance analysis was performed using the Mann-Whitney U test. Comparisons between variables were evaluated using the chi-square test. Statistical significance was set at p < 0.05. Statistical analysis was performed using IBM SPSS version 20 (IBM Corp., Armonk, NY, USA).

Of the 105 patients, 73.3% were male. The median age and median weight at the time of surgery were similar in the OR and laparoscopy groups. Most of the patients presented with inguinal swelling, and there was no significant difference between the two groups in the number of patients with major comorbidities. The median duration of follow-up after surgery was 23.6 months, and the recently performed laparoscopy group was significantly shorter than the OR group (Table 1). In subanalysis within the laparoscopic group, there were 16 patients in the LPEC group and 50 patients in the TLR group. There were 16 patients in the LPEC group and 50 patients in the TLR group. The median age and median weight at the time of surgery were significantly lower in the LPEC group (age, 8.5 months [range, 1.3–54.4 months]; weight, 7.6 kg [range, 3.2–17.6 kg]) compared to the TLR group (age, 30.5 months [range, 0.8–183.5 months]; weight, 13.1 kg [range, 3.3–55.0 kg]; p = 0.019 and p = 0.048).

The initial presentation was on the right side in 42.9% of cases, on the left side in 47.6%, and on both sides in 9.5%. Among the patients who underwent laparoscopic surgery, contralateral PPV was found on the left side in 20 of 30 patients (66.7%) whose initial presentation was on the right, and on the right side in 12 of 33 patients (36.4%) whose initial presentation was on the left. That is, out of 63 patients who initially presented for unilateral laparoscopic repair, 32 patients (50.8%) were found to have synchronous contralateral PPV which was simultaneously repaired. Among the patients in the group who underwent laparoscopic surgery, three patients had a history of bilateral inguinal swelling, but two patients underwent unilateral repair because PPV was confirmed only on the right side. Operation time was significantly shorter in the laparoscopy group for both unilateral and bilateral repairs, and the postoperative hospital stay was also significantly shorter in the laparoscopy group than OR group (Table 2). In subanalysis within the laparoscopic group, operation time was significantly shorter in the TLR group for both unilateral and bilateral repairs than LPEC group (unilateral, 33.7 ± 8.4 minutes vs. 47.7 ± 11.8 minutes; bilateral, 37.0 ± 6.0 minutes vs. 62.9 ± 8.9 minutes; p < 0.001 and p < 0.001).

In the laparoscopic repair groups, 43.8% of males and 61.1% of females had a contralateral PPV. This finding appeared to be more frequent in females, but the difference was not significant. By age, contralateral PPV was found in 80% of patients aged from 3 to 6 months, and in 71.4% of patients aged from 1 to 3 years. These results suggest that contralateral PPV tends to decrease significantly after 3 years of age (Table 3).

No ipsilateral recurrence occurred during the postoperative follow-up period. Surgical site infection was observed in one patient (1.5%) after laparoscopic surgery. Ten patients (9.5%) were found to have hydrocele after surgery, but there was no significant difference between groups. Of the 105 patients, three (2.9%) experienced metachronous contralateral IH occurrence after surgery. It occurred in two of the OR group (5.1%) and one of the laparoscopic repair groups (1.5%), but the difference was not significant (p = 0.554). It occurred at 24.03 months, and 21.7 months after surgery in the two OR group patients, and at 2 months after surgery in the one LPEC patient (Table 4).

The operative time was shorter in the laparoscopic repair groups. Contralateral PPV was confirmed in 50.8% of patients who underwent laparoscopic repair for unilateral inguinal swelling, and the probability of such was higher in patients under 3 years of age. Laparoscopic IH repair may have benefit in terms of shorter operation time and diagnosis of unpredicted contralateral PPV compared to OR especially in younger patients.

Almost all IHs in children are congenital indirect hernias that occur through the processus vaginalis, the anatomical path created before birth, through which the testicles descend from the abdomen to the scrotum. The exact timing of the processus vaginalis closure is not clear. Some studies report that 80% to 100% of infants have a PPV at birth, with most of them closing within 6 months of age [10]. It is not well known why the processus vaginalis is not obliterated. Failure of the surrounding smooth muscle cells to undergo apoptosis when the testicles descend has been reported as a cause [11]. It has also been suggested that a decrease in the calcitonin gene-related protein release from the genitofemoral nerve can lead to hernia and scrotal edema after birth [12]. In females, it is the round ligament supporting the uterus that descends through the processus vaginalis, which, if persistently patent, is called the canal of Nuck, and can lead to hernia development [13].

OR is the traditional surgical method of hernia repair in children, and it is still widely practiced [14]. It is fast, safe, and can be done as outpatient. It has, however, a recurrence rate of about 1% to 5% depending on the skill level of the surgeon, the age of the patient, and the accompanying disease [15]. The introduction of laparoscopic repair in the 1990s was a milestone in surgical repair of pediatric hernias. In 1995, Takahara et al. [8] reported on a surgical method called LPEC, and since then, there have been several reports on its safety and efficacy [14,16]. In one systematic review comparing open and laparoscopic repair in children, the operation time was 30.1 minutes for OR and 23.7 minutes for laparoscopic repair in unilateral IH, with no statistical difference between the two (p = 0.33). However, in the case of bilateral hernias, the laparoscopic operation time was significantly shorter than the OR time (46.1 minutes vs. 30.9 minutes, p = 0.01) [7]. These findings have been reproduced in several other studies [17] and suggest that laparoscopic surgery is more efficient in terms of operation time than OR in pediatric IH repair.

In the same systematic review, the recurrence rate was 1.6% for OR and 1.4% for laparoscopic repair with no statistical difference between the two techniques (p = 0.66) [7]. However, the rate of complications such as wound infection, hydrocele, iatrogenic cryptorchidism, and testicular atrophy was higher in OR than in laparoscopic repair (2.7% vs. 0.9%, p = 0.001). In a study conducted by Ho et al. [17], there was no statistical difference between OR and laparoscopic repair in terms of postoperative recurrence rate and wound infection. However, postoperative scrotal swelling occurred more frequently in the OR group (p = 0.006). In other studies, metachronous contralateral hernia, surgical site infection, and scrotal swelling occurred significantly less with laparoscopic repair [18]. These results suggest that laparoscopic repair may be preferable, compared to OR, because of few complications such as cryptorchidism and testicular atrophy. This is probably because the visualization of cord structures is good, and dissection can be made safer. In addition, the laparoscopic dissection field is limited to the peritoneal layer, so the vas deferens is less likely to be injured [7].

In addition to a shorter operation time and fewer surgical complications, laparoscopic repair has many other advantages. Laparoscopic repair is a minimally invasive surgery associated with less pain, quick return to daily life, and excellent cosmetic outcomes [16]. In one study, hospital stay and recovery time were overall similar for OR and laparoscopic repair, but patients who underwent LPEC had fewer complications and shorter unilateral surgery time, whereas patients who received TLR had shorter hospital stays [19].

In a study by Korkmaz and Güvenç [16], which compared three-port conventional laparoscopic repair and LPEC, the operation time was seemed shorter in the LPEC group in unilateral hernia repair and was approximately the same in the two groups in bilateral repair. There was no recurrence in the LPEC group and two recurrences (4.3%) in the three-port conventional laparoscopic repair group, which happened during the learning curve period. In the LPEC group, there were cases of inferior epigastric vessel injury resulting in OR and hydrocele formation after surgery. However, no complications occurred in the three-port conventional laparoscopic repair group. In our study, the operative time was shortest in the TLR group for both unilateral and bilateral repairs (p < 0.001). Metachronous contralateral IH occurred in one case (6.2%) in the LPEC group, and none in the TLR group.

In this study, synchronous contralateral PPV was found in 50.8% of patients when laparoscopic repair was performed for unilateral inguinal swelling. In these cases, contralateral repair was performed simultaneously. There is controversy over contralateral groin exploration in infants and children with unilateral indirect IH [20]. The purpose of contralateral exploration is to prevent hernia from occurring later. Disadvantages of contralateral exploration include the possibility of damage to spermatic cord vessels, vas deferens, and testis, and an increase in operation time and anesthesia time [21]. Because contralateral PPV may not always progress to metachronous contralateral IH [22], its repair has been reported to be unnecessary [23]. However, contralateral exploration can avoid the risk of incarceration, additional surgical costs, additional anesthesia, and parental worries [24]. Because the opposite side can be explored without the risk of significant damage to the vas and vessels, pediatric surgeons are increasingly using laparoscopic exploration [25] to detect and repair contralateral PPV [26]. Rather than routinely performing contralateral exploration, several studies of IHs in children have recommended age-specific exploration [22,27]. According to Holcomb et al. [28], bilateral IHs occurred in 50% of children younger than 1 year, 45% of children younger than 2 years, and 37% of those younger than 5 years suggesting that the younger they were, the more common a bilateral IH was. After unilateral hernia correction, 5%–20% of patients had hernias developed on the contralateral side, and repair was needed. In our study, contralateral PPV in patients who underwent laparoscopic surgery for a unilateral indication was found in 80% of patients aged from 3 to 6 months and 71.4% of patients aged from 1 to 3 years, but in only 20% of those over 3 years old. Therefore, we believe that it is better to simultaneously repair contralateral PPV by a laparoscopic technique in patients under 3 years of age with unilateral symptoms.

The recurrence rate in pediatric hernia surgery is reported to be 0% to 6% in OR, and 0% to 15.5% in laparoscopic repair, and recurrence almost always occurs within 1 year after surgery [29]. In our study, there was no ipsilateral recurrence in the three groups during the median follow-up period of 23.6 months. In two patients who underwent OR, metachronous contralateral IH occurred after 24.03 months and 21.7 months; whereas in one patient who underwent LPEC, metachronous contralateral IH occurred 2 months after surgery, and it was due to a small contralateral PPV which was missed. Sumida et al. [30] noted the importance of careful screening to reduce the occurrence of metachronous contralateral hernia in LPEC.

This study has some limitations. This institution was not a specialized pediatric surgical center until 2017. Therefore, the number of pediatric IH was not large. As a result, the study enrollment period became long, and after a pediatric surgeon joined in 2018, the number of pediatric laparoscopic surgery suddenly increased. This is a limitation of this study since the heterogeneity of the enrollees may have acted as a bias in the interpretation of the surgical outcome. In the laparoscopy group, the median duration of follow-up was short enough to be less than 1 year. Since such a short period is not sufficient to evaluate surgical complications, it is possible that the complications in the laparoscopy group were underestimated. In this study, postoperative hospital stay was shorter in the laparoscopic repair group than OR group, which may seem to suggest that laparoscopic repair allows faster return to daily life due to less postoperative pain and faster recovery than OR. However, this study had limitation in enrolling patients over 9 years. As medical care and technology advance during this period, the policy of surgeons and hospitals for ‘hospital stay’ changes. In this institution, both OR and laparoscopic surgery have recently been aimed at day surgery (shorter hospital stay). As mentioned earlier, LPEC has been performed in this institution since 2015, and TLR has been performed since 2018. Therefore, the postoperative hospital stay in this study would not have much meaning in the interpretation of the results due to the bias caused by the long study period.

In conclusion, the operative time of IH repair was shorter in the laparoscopic repair groups than in the OR group; metachronous contralateral IH occurred in 5.1% of the OR group and 1.5% of the laparoscopic repair group, but the difference was not significant. Contralateral PPV was confirmed in 50.8% of patients who underwent laparoscopic repair for unilateral inguinal swelling, and the probability of finding synchronous contralateral PPV was significant in patients under three years of age. Laparoscopic IH repair is safe and effective and can be used to detect synchronous contralateral PPV especially in younger patients, thus preventing metachronous contralateral IH occurrence.

Ethical statements

This study was performed in accordance with the Declaration of Helsinki. This study was approved by the Institutional Review Board of Korea University Ansan Hospital (No. 2021AS0191), and informed consent was waived due to its retrospective nature.

Authors’ contributions

Data curation, Formal analysis, Investigation, Visualization, Methodology, Project administration: EJK, CO

Writing–original draft: EJK, CO

Writing–review & editing: CO, JWU

All authors read and approved the final manuscript.

Conflict of interest

All authors have no conflicts of interest to declare.

Funding/support

None.

Fig. 1. Laparoscopic percutaneous extraperitoneal closure. (A) Preperitoneal suturing performed first on the medial side from 12 o’clock to 6 o’clock of the internal inguinal ring using a 21-gage spinal needle. (B) Suturing in the opposite direction from 12 o’clock to 6 o’clock, with the needle coming out into the loop at 6 o’clock. (C) Closure of the internal inguinal ring.
Fig. 2. Three-port mini-laparoscopic repair. (A) The hernia sac is transected at the level of the internal inguinal ring. (B) Suturing the peritoneum around the internal inguinal ring with a purse-string suture. (C) Closure of the internal inguinal ring.
Table. 1.

Patient characteristics

CharacteristicTotalOpenLaparoscopyp value
No. of patients1053966>0.999
Male sex77 (73.3)29 (74.4)48 (72.7)>0.999
Age at operation (mo)17.2 (0.8–183.5)17.1 (0.8–136.7)20.2 (0.8–183.5)0.686
<3 mo30 (28.6)12 (30.8)18 (27.3)0.824
<1 yr45 (42.8)18 (46.2)27 (40.9)0.684
<3 yr65 (61.9)24 (61.5)41 (62.1)>0.999
≥3 yr40 (38.1)15 (38.5)25(37.9)>0.999
Weight at operation (kg)10.5 (3.08–55)10.2 (3.08–42)11 (3.2–55)0.907
<521 (20.0)8 (20.5)13 (19.7)>0.999
<1047 (44.8)19 (48.7)28 (42.4)0.549
≥1058 (55.2)20 (51.3)38 (57.6)0.549
Initial symptom
Inguinal swelling104 (99)39 (100)65 (98.5)>0.999
Vomiting2 (1.9)1 (2.6)1 (1.5)>0.999
Fever3 (2.9)0 (0)3 (4.5)0.293
Hydrocele21 (20.0)11 (28.2)10 (15.2)0.132
Major comorbiditiesa)5 (4.8)1 (2.6)4 (6.1)0.649
Follow-up (mo)23.6 (0.5–106.7)83.8 (11.0–106.7)8.7 (0.5–58.4)<0.001

Values are presented as number only, number (%), or median (range).

a)Atrial septal defect, 1; ventricular septal defect, 1; patent ductus arteriosus, 1; coarctation of aorta, 1; tetralogy of Fallot, 1.


Table. 2.

Operation findings

VariableTotalOpenLaparoscopyp value
No. of patients1053966
Side of initial presentation
Right45 (42.9)15 (38.5)30 (45.5)0.544
Left50 (47.6)17 (43.6)33 (50.0)0.551
Bilateral10 (9.5)7 (17.9)3 (4.5)0.037
Side at operation
Right27 (25.7)15 (38.5)12 (18.2)0.036
Left38 (36.2)17 (43.6)21 (31.8)0.294
Bilateral40 (38.1)7 (17.9)33 (50.0)0.002
Right to bilateral20 (19.0)None20 (30.3)
Left to bilateral12 (11.4)None12 (18.2)
Operation time (min)
Unilateral43.5 ± 14.749.7 ± 15.437.5 ± 11.2<0.001
Bilateral50.1 ± 22.186.3 ± 22.242.4 ± 12.6<0.001
Postoperative stay (day)0.73 ± 0.70.9 ± 0.550.64 ± 0.710.018

Values are presented as number only, number (%), or mean ± standard deviation.


Table. 3.

Contralateral patent processus vaginalis in laparoscopic repair group

VariableNo. (%)p value
Sex0.272
Male21/48 (43.8)
Female11/18 (61.1)
Age0.010
<3 mo11/18 (61.1)
3 mo–6 mo4/5 (80.0)
6 mo–1 yr2/4 (50.0)
1 yr – 3 yr10/14 (71.4)
3 yr–5 yr2/12 (16.7)
≥5 yr3/13 (23.1)

Table. 4.

Postoperative complications and occurrence of metachronous contralateral inguinal hernia

VariableTotalOpenLaparoscopyp value
No. of patients1053966-
Recurrence0 (0)0 (0)0 (0)-
Surgical site infection1 (1.0)0 (0)1 (1.5)>0.999
Hydrocele10 (9.5)3 (7.7)7 (10.6)0.741
Hematoma2 (1.9)2 (5.1)0 (0)0.136
Seroma2 (1.9)0 (0)2 (3.0)0.529
Totala)14 (13.3)5 (12.8)9 (13.6)>0.999
Occurrence of metachronous contralateral inguinal hernia3 (2.9)2 (5.1)1 (1.5)0.554

Values are presented as number only or number (%).

a)Multiple complications could occur in the same patients.


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Article

Original Article

Journal of Minimally Invasive Surgery 2021; 24(4): 200-207

Published online December 15, 2021 https://doi.org/10.7602/jmis.2021.24.4.200

Copyright © The Korean Society of Endo-Laparoscopic & Robotic Surgery.

Laparoscopic surgery: an effective and safe surgical method of pediatric inguinal hernia repair

Eun Jung Kim , Chaeyoun Oh , Jun Won Um

Department of Surgery, Korea University Ansan Hospital, Ansan, Korea

Correspondence to:Jun Won Um
Department of Surgery, Korea University Ansan Hospital, 123 Jeokgeum-ro, Danwon-gu, Ansan 15355, Korea
Tel: +82-31-412-4830
Fax: +82-31-412-4807
E-mail: junwonum@korea.ac.kr
ORCID:
https://orcid.org/0000-0002-0506-0235

Received: August 11, 2021; Revised: October 22, 2021; Accepted: October 31, 2021

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/4.0/) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

Abstract

Purpose: Inguinal hernia (IH) repair is very commonly performed in children. While open repair (OR) is the standard approach, laparoscopic repair is increasingly used. This study was aimed to investigate safety and feasibility of laparoscopic repair of pediatric IH compared to OR.
Methods: We retrospectively enrolled 105 pediatric patients with IH repair between January 2011 and October 2019. The laparoscopic procedures performed were laparoscopic percutaneous extraperitoneal closure (LPEC), and three-port mini-laparoscopic repair (TLR). The OR was performed as per usual technique.
Results: Thirty-nine patients underwent OR, 16 LPEC, and 50 TLR. The preoperative laterality of IH was 45 patients (42.9%) on the right side, 50 (47.6%) on the left side, and 10 (9.5%) on both sides. It was, however, diagnosed postoperatively in 27 patients (25.7%) on the right side, 38 (36.2%) on the left side, and 40 (38.1%) on both sides. Of the 63 patients who presented with unilateral IH in the laparoscopic groups, 32 (50.8%) had synchronous contralateral patent process vaginalis (PPV) which were simultaneously repaired. This was significantly more common in children under 3 years of age. Operative time in unilateral or bilateral repair was significantly shorter in the laparoscopic repair groups (p < 0.001). Ipsilateral recurrence was not observed in any group. Metachronous contralateral IH occurrence was not significantly different between groups.
Conclusion: Laparoscopic IH repair may have benefit in terms of shorter operation time and diagnosis of unpredicted contralateral PPV compared to OR.

Keywords: Inguinal hernia, Pediatrics, Herniorrhaphy, Laparoscopy

INTRODUCTION

Inguinal hernia (IH) repair is the most common surgery performed in children. In children under the age of 18, the incidence of IH is 0.8% to 5% at full term and up to 30% with low birth weight and premature births [1]. Pediatric IH is caused by persistent patency of the vaginal process, unlike IH in adults, which is due to weakness of the abdominal musculature. Therefore, prosthetic mesh reinforcement is necessary in adults, whereas high ligation is sufficient in children [2].

High ligation using open repair (OR) was described over 100 years ago, and the recurrence rate in recently published reports is very low, ranging from 0% to 6% [3,4]. However, complications such as spermatic cord injury, vas deference injury, hematoma, surgical site infection, iatrogenic cryptorchidism, and testicular atrophy can be seen [5]. The laparoscopic approach was first reported for pediatric IH repair in 1992 [6]. Although OR is still widely performed, laparoscopic IH repair is being increasingly used in many institutions, even in neonates, where minimally invasive surgery is mainstream. It has been recently reported that, compared to OR, laparoscopic bilateral IH repair is associated with shorter operation time and fewer wound infections in infants [7]. This study was aimed to investigate safety and feasibility of laparoscopic repair of pediatric IH compared to OR in a single center.

MATERIALS AND METHODS

This study was conducted on 105 children and adolescents aged <19 years who underwent IH surgery at Korea University Ansan Hospital from January 2011 to October 2019. We compared OR and laparoscopic repair of pediatric IH performed in a single center and further analyzed the results of two laparoscopic techniques, laparoscopic percutaneous extraperitoneal closure (LPEC) and three-port mini-laparoscopic repair (TLR). It is our policy to conduct only one outpatient follow-up visit approximately one week after the operation, with no further follow-up unless indicated. Therefore, all subjects were contacted via telephone interviews to determine their recent status. Telephone interviews were attempted in October 2019 with 105 patients, and 29 out of 39 patients (74.4%) in the OR group responded. All 16 patients in the LPEC group responded (100%), and 46 out of 50 patients (92.0%) in the TLR group responded. The data were collected retrospectively through medical charts, such as surgical records and anesthesia records.

OR was performed by two surgeons. LPEC has been performed since 2015, and TLR has been performed since 2018. In OR, high ligation was performed only on the symptomatic side, whereas in laparoscopic repair, bilateral repairs were performed when contralateral patent processus vaginalis (PPV) was confirmed. General anesthesia was used for all operations. For the OR, a 1 to 2 cm incision was made in the symptomatic inguinal area, the hernia sac was retrieved, the cord structure was detached, and high ligation was performed. LPEC was performed as previously reported [8]. A 5-mm camera was inserted through the umbilicus, and one 3-mm port was placed in the suprapubic area, through which one assisted laparoscopic instrument was inserted. After checking the patency of the processus vaginalis, an incision of approximately 1 to 2 mm was performed above it. Subsequently, preperitoneal sutures were placed first on the medial side, from 12 o’clock to 6 o’clock of the internal inguinal ring, using a 21-gage spinal needle. At that time, an assisted instrument was used to direct the vas deference and gonadal vessels down the suture line. The needle was removed after coming out in the direction of 6 o’clock, and the 4-0 prolene was pushed down to form the loop. The same process then started in the opposite direction, from 12 o’clock to 6 o’clock, with the needle coming out at 6 o’clock. The sufficiently delivered prolene was caught with a loop and came out, and a tie was carefully performed at the incision site. At that time, the operation was concluded after checking whether the internal inguinal ring was sufficiently closed through the camera (Fig. 1). TLR was performed using the laparoscopic sac transection and peritoneal closure method [9]. We performed the procedure using a 3-mm camera and two 3-mm instruments. After complete transection of the hernia sac at the level of the internal inguinal ring, the peritoneum around the ring was sutured with a 4-0 prolene suture to close it (Fig. 2).

The nonparametric variance analysis was performed using the Mann-Whitney U test. Comparisons between variables were evaluated using the chi-square test. Statistical significance was set at p < 0.05. Statistical analysis was performed using IBM SPSS version 20 (IBM Corp., Armonk, NY, USA).

RESULTS

Of the 105 patients, 73.3% were male. The median age and median weight at the time of surgery were similar in the OR and laparoscopy groups. Most of the patients presented with inguinal swelling, and there was no significant difference between the two groups in the number of patients with major comorbidities. The median duration of follow-up after surgery was 23.6 months, and the recently performed laparoscopy group was significantly shorter than the OR group (Table 1). In subanalysis within the laparoscopic group, there were 16 patients in the LPEC group and 50 patients in the TLR group. There were 16 patients in the LPEC group and 50 patients in the TLR group. The median age and median weight at the time of surgery were significantly lower in the LPEC group (age, 8.5 months [range, 1.3–54.4 months]; weight, 7.6 kg [range, 3.2–17.6 kg]) compared to the TLR group (age, 30.5 months [range, 0.8–183.5 months]; weight, 13.1 kg [range, 3.3–55.0 kg]; p = 0.019 and p = 0.048).

The initial presentation was on the right side in 42.9% of cases, on the left side in 47.6%, and on both sides in 9.5%. Among the patients who underwent laparoscopic surgery, contralateral PPV was found on the left side in 20 of 30 patients (66.7%) whose initial presentation was on the right, and on the right side in 12 of 33 patients (36.4%) whose initial presentation was on the left. That is, out of 63 patients who initially presented for unilateral laparoscopic repair, 32 patients (50.8%) were found to have synchronous contralateral PPV which was simultaneously repaired. Among the patients in the group who underwent laparoscopic surgery, three patients had a history of bilateral inguinal swelling, but two patients underwent unilateral repair because PPV was confirmed only on the right side. Operation time was significantly shorter in the laparoscopy group for both unilateral and bilateral repairs, and the postoperative hospital stay was also significantly shorter in the laparoscopy group than OR group (Table 2). In subanalysis within the laparoscopic group, operation time was significantly shorter in the TLR group for both unilateral and bilateral repairs than LPEC group (unilateral, 33.7 ± 8.4 minutes vs. 47.7 ± 11.8 minutes; bilateral, 37.0 ± 6.0 minutes vs. 62.9 ± 8.9 minutes; p < 0.001 and p < 0.001).

In the laparoscopic repair groups, 43.8% of males and 61.1% of females had a contralateral PPV. This finding appeared to be more frequent in females, but the difference was not significant. By age, contralateral PPV was found in 80% of patients aged from 3 to 6 months, and in 71.4% of patients aged from 1 to 3 years. These results suggest that contralateral PPV tends to decrease significantly after 3 years of age (Table 3).

No ipsilateral recurrence occurred during the postoperative follow-up period. Surgical site infection was observed in one patient (1.5%) after laparoscopic surgery. Ten patients (9.5%) were found to have hydrocele after surgery, but there was no significant difference between groups. Of the 105 patients, three (2.9%) experienced metachronous contralateral IH occurrence after surgery. It occurred in two of the OR group (5.1%) and one of the laparoscopic repair groups (1.5%), but the difference was not significant (p = 0.554). It occurred at 24.03 months, and 21.7 months after surgery in the two OR group patients, and at 2 months after surgery in the one LPEC patient (Table 4).

DISCUSSION

The operative time was shorter in the laparoscopic repair groups. Contralateral PPV was confirmed in 50.8% of patients who underwent laparoscopic repair for unilateral inguinal swelling, and the probability of such was higher in patients under 3 years of age. Laparoscopic IH repair may have benefit in terms of shorter operation time and diagnosis of unpredicted contralateral PPV compared to OR especially in younger patients.

Almost all IHs in children are congenital indirect hernias that occur through the processus vaginalis, the anatomical path created before birth, through which the testicles descend from the abdomen to the scrotum. The exact timing of the processus vaginalis closure is not clear. Some studies report that 80% to 100% of infants have a PPV at birth, with most of them closing within 6 months of age [10]. It is not well known why the processus vaginalis is not obliterated. Failure of the surrounding smooth muscle cells to undergo apoptosis when the testicles descend has been reported as a cause [11]. It has also been suggested that a decrease in the calcitonin gene-related protein release from the genitofemoral nerve can lead to hernia and scrotal edema after birth [12]. In females, it is the round ligament supporting the uterus that descends through the processus vaginalis, which, if persistently patent, is called the canal of Nuck, and can lead to hernia development [13].

OR is the traditional surgical method of hernia repair in children, and it is still widely practiced [14]. It is fast, safe, and can be done as outpatient. It has, however, a recurrence rate of about 1% to 5% depending on the skill level of the surgeon, the age of the patient, and the accompanying disease [15]. The introduction of laparoscopic repair in the 1990s was a milestone in surgical repair of pediatric hernias. In 1995, Takahara et al. [8] reported on a surgical method called LPEC, and since then, there have been several reports on its safety and efficacy [14,16]. In one systematic review comparing open and laparoscopic repair in children, the operation time was 30.1 minutes for OR and 23.7 minutes for laparoscopic repair in unilateral IH, with no statistical difference between the two (p = 0.33). However, in the case of bilateral hernias, the laparoscopic operation time was significantly shorter than the OR time (46.1 minutes vs. 30.9 minutes, p = 0.01) [7]. These findings have been reproduced in several other studies [17] and suggest that laparoscopic surgery is more efficient in terms of operation time than OR in pediatric IH repair.

In the same systematic review, the recurrence rate was 1.6% for OR and 1.4% for laparoscopic repair with no statistical difference between the two techniques (p = 0.66) [7]. However, the rate of complications such as wound infection, hydrocele, iatrogenic cryptorchidism, and testicular atrophy was higher in OR than in laparoscopic repair (2.7% vs. 0.9%, p = 0.001). In a study conducted by Ho et al. [17], there was no statistical difference between OR and laparoscopic repair in terms of postoperative recurrence rate and wound infection. However, postoperative scrotal swelling occurred more frequently in the OR group (p = 0.006). In other studies, metachronous contralateral hernia, surgical site infection, and scrotal swelling occurred significantly less with laparoscopic repair [18]. These results suggest that laparoscopic repair may be preferable, compared to OR, because of few complications such as cryptorchidism and testicular atrophy. This is probably because the visualization of cord structures is good, and dissection can be made safer. In addition, the laparoscopic dissection field is limited to the peritoneal layer, so the vas deferens is less likely to be injured [7].

In addition to a shorter operation time and fewer surgical complications, laparoscopic repair has many other advantages. Laparoscopic repair is a minimally invasive surgery associated with less pain, quick return to daily life, and excellent cosmetic outcomes [16]. In one study, hospital stay and recovery time were overall similar for OR and laparoscopic repair, but patients who underwent LPEC had fewer complications and shorter unilateral surgery time, whereas patients who received TLR had shorter hospital stays [19].

In a study by Korkmaz and Güvenç [16], which compared three-port conventional laparoscopic repair and LPEC, the operation time was seemed shorter in the LPEC group in unilateral hernia repair and was approximately the same in the two groups in bilateral repair. There was no recurrence in the LPEC group and two recurrences (4.3%) in the three-port conventional laparoscopic repair group, which happened during the learning curve period. In the LPEC group, there were cases of inferior epigastric vessel injury resulting in OR and hydrocele formation after surgery. However, no complications occurred in the three-port conventional laparoscopic repair group. In our study, the operative time was shortest in the TLR group for both unilateral and bilateral repairs (p < 0.001). Metachronous contralateral IH occurred in one case (6.2%) in the LPEC group, and none in the TLR group.

In this study, synchronous contralateral PPV was found in 50.8% of patients when laparoscopic repair was performed for unilateral inguinal swelling. In these cases, contralateral repair was performed simultaneously. There is controversy over contralateral groin exploration in infants and children with unilateral indirect IH [20]. The purpose of contralateral exploration is to prevent hernia from occurring later. Disadvantages of contralateral exploration include the possibility of damage to spermatic cord vessels, vas deferens, and testis, and an increase in operation time and anesthesia time [21]. Because contralateral PPV may not always progress to metachronous contralateral IH [22], its repair has been reported to be unnecessary [23]. However, contralateral exploration can avoid the risk of incarceration, additional surgical costs, additional anesthesia, and parental worries [24]. Because the opposite side can be explored without the risk of significant damage to the vas and vessels, pediatric surgeons are increasingly using laparoscopic exploration [25] to detect and repair contralateral PPV [26]. Rather than routinely performing contralateral exploration, several studies of IHs in children have recommended age-specific exploration [22,27]. According to Holcomb et al. [28], bilateral IHs occurred in 50% of children younger than 1 year, 45% of children younger than 2 years, and 37% of those younger than 5 years suggesting that the younger they were, the more common a bilateral IH was. After unilateral hernia correction, 5%–20% of patients had hernias developed on the contralateral side, and repair was needed. In our study, contralateral PPV in patients who underwent laparoscopic surgery for a unilateral indication was found in 80% of patients aged from 3 to 6 months and 71.4% of patients aged from 1 to 3 years, but in only 20% of those over 3 years old. Therefore, we believe that it is better to simultaneously repair contralateral PPV by a laparoscopic technique in patients under 3 years of age with unilateral symptoms.

The recurrence rate in pediatric hernia surgery is reported to be 0% to 6% in OR, and 0% to 15.5% in laparoscopic repair, and recurrence almost always occurs within 1 year after surgery [29]. In our study, there was no ipsilateral recurrence in the three groups during the median follow-up period of 23.6 months. In two patients who underwent OR, metachronous contralateral IH occurred after 24.03 months and 21.7 months; whereas in one patient who underwent LPEC, metachronous contralateral IH occurred 2 months after surgery, and it was due to a small contralateral PPV which was missed. Sumida et al. [30] noted the importance of careful screening to reduce the occurrence of metachronous contralateral hernia in LPEC.

This study has some limitations. This institution was not a specialized pediatric surgical center until 2017. Therefore, the number of pediatric IH was not large. As a result, the study enrollment period became long, and after a pediatric surgeon joined in 2018, the number of pediatric laparoscopic surgery suddenly increased. This is a limitation of this study since the heterogeneity of the enrollees may have acted as a bias in the interpretation of the surgical outcome. In the laparoscopy group, the median duration of follow-up was short enough to be less than 1 year. Since such a short period is not sufficient to evaluate surgical complications, it is possible that the complications in the laparoscopy group were underestimated. In this study, postoperative hospital stay was shorter in the laparoscopic repair group than OR group, which may seem to suggest that laparoscopic repair allows faster return to daily life due to less postoperative pain and faster recovery than OR. However, this study had limitation in enrolling patients over 9 years. As medical care and technology advance during this period, the policy of surgeons and hospitals for ‘hospital stay’ changes. In this institution, both OR and laparoscopic surgery have recently been aimed at day surgery (shorter hospital stay). As mentioned earlier, LPEC has been performed in this institution since 2015, and TLR has been performed since 2018. Therefore, the postoperative hospital stay in this study would not have much meaning in the interpretation of the results due to the bias caused by the long study period.

In conclusion, the operative time of IH repair was shorter in the laparoscopic repair groups than in the OR group; metachronous contralateral IH occurred in 5.1% of the OR group and 1.5% of the laparoscopic repair group, but the difference was not significant. Contralateral PPV was confirmed in 50.8% of patients who underwent laparoscopic repair for unilateral inguinal swelling, and the probability of finding synchronous contralateral PPV was significant in patients under three years of age. Laparoscopic IH repair is safe and effective and can be used to detect synchronous contralateral PPV especially in younger patients, thus preventing metachronous contralateral IH occurrence.

NOTES

Ethical statements

This study was performed in accordance with the Declaration of Helsinki. This study was approved by the Institutional Review Board of Korea University Ansan Hospital (No. 2021AS0191), and informed consent was waived due to its retrospective nature.

Authors’ contributions

Data curation, Formal analysis, Investigation, Visualization, Methodology, Project administration: EJK, CO

Writing–original draft: EJK, CO

Writing–review & editing: CO, JWU

All authors read and approved the final manuscript.

Conflict of interest

All authors have no conflicts of interest to declare.

Funding/support

None.

Fig 1.

Figure 1.Laparoscopic percutaneous extraperitoneal closure. (A) Preperitoneal suturing performed first on the medial side from 12 o’clock to 6 o’clock of the internal inguinal ring using a 21-gage spinal needle. (B) Suturing in the opposite direction from 12 o’clock to 6 o’clock, with the needle coming out into the loop at 6 o’clock. (C) Closure of the internal inguinal ring.
Journal of Minimally Invasive Surgery 2021; 24: 200-207https://doi.org/10.7602/jmis.2021.24.4.200

Fig 2.

Figure 2.Three-port mini-laparoscopic repair. (A) The hernia sac is transected at the level of the internal inguinal ring. (B) Suturing the peritoneum around the internal inguinal ring with a purse-string suture. (C) Closure of the internal inguinal ring.
Journal of Minimally Invasive Surgery 2021; 24: 200-207https://doi.org/10.7602/jmis.2021.24.4.200

Table 1 .. Patient characteristics.

CharacteristicTotalOpenLaparoscopyp value
No. of patients1053966>0.999
Male sex77 (73.3)29 (74.4)48 (72.7)>0.999
Age at operation (mo)17.2 (0.8–183.5)17.1 (0.8–136.7)20.2 (0.8–183.5)0.686
<3 mo30 (28.6)12 (30.8)18 (27.3)0.824
<1 yr45 (42.8)18 (46.2)27 (40.9)0.684
<3 yr65 (61.9)24 (61.5)41 (62.1)>0.999
≥3 yr40 (38.1)15 (38.5)25(37.9)>0.999
Weight at operation (kg)10.5 (3.08–55)10.2 (3.08–42)11 (3.2–55)0.907
<521 (20.0)8 (20.5)13 (19.7)>0.999
<1047 (44.8)19 (48.7)28 (42.4)0.549
≥1058 (55.2)20 (51.3)38 (57.6)0.549
Initial symptom
Inguinal swelling104 (99)39 (100)65 (98.5)>0.999
Vomiting2 (1.9)1 (2.6)1 (1.5)>0.999
Fever3 (2.9)0 (0)3 (4.5)0.293
Hydrocele21 (20.0)11 (28.2)10 (15.2)0.132
Major comorbiditiesa)5 (4.8)1 (2.6)4 (6.1)0.649
Follow-up (mo)23.6 (0.5–106.7)83.8 (11.0–106.7)8.7 (0.5–58.4)<0.001

Values are presented as number only, number (%), or median (range)..

a)Atrial septal defect, 1; ventricular septal defect, 1; patent ductus arteriosus, 1; coarctation of aorta, 1; tetralogy of Fallot, 1..


Table 2 .. Operation findings.

VariableTotalOpenLaparoscopyp value
No. of patients1053966
Side of initial presentation
Right45 (42.9)15 (38.5)30 (45.5)0.544
Left50 (47.6)17 (43.6)33 (50.0)0.551
Bilateral10 (9.5)7 (17.9)3 (4.5)0.037
Side at operation
Right27 (25.7)15 (38.5)12 (18.2)0.036
Left38 (36.2)17 (43.6)21 (31.8)0.294
Bilateral40 (38.1)7 (17.9)33 (50.0)0.002
Right to bilateral20 (19.0)None20 (30.3)
Left to bilateral12 (11.4)None12 (18.2)
Operation time (min)
Unilateral43.5 ± 14.749.7 ± 15.437.5 ± 11.2<0.001
Bilateral50.1 ± 22.186.3 ± 22.242.4 ± 12.6<0.001
Postoperative stay (day)0.73 ± 0.70.9 ± 0.550.64 ± 0.710.018

Values are presented as number only, number (%), or mean ± standard deviation..


Table 3 .. Contralateral patent processus vaginalis in laparoscopic repair group.

VariableNo. (%)p value
Sex0.272
Male21/48 (43.8)
Female11/18 (61.1)
Age0.010
<3 mo11/18 (61.1)
3 mo–6 mo4/5 (80.0)
6 mo–1 yr2/4 (50.0)
1 yr – 3 yr10/14 (71.4)
3 yr–5 yr2/12 (16.7)
≥5 yr3/13 (23.1)

Table 4 .. Postoperative complications and occurrence of metachronous contralateral inguinal hernia.

VariableTotalOpenLaparoscopyp value
No. of patients1053966-
Recurrence0 (0)0 (0)0 (0)-
Surgical site infection1 (1.0)0 (0)1 (1.5)>0.999
Hydrocele10 (9.5)3 (7.7)7 (10.6)0.741
Hematoma2 (1.9)2 (5.1)0 (0)0.136
Seroma2 (1.9)0 (0)2 (3.0)0.529
Totala)14 (13.3)5 (12.8)9 (13.6)>0.999
Occurrence of metachronous contralateral inguinal hernia3 (2.9)2 (5.1)1 (1.5)0.554

Values are presented as number only or number (%)..

a)Multiple complications could occur in the same patients..


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