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Trends in the Treatment Outcomes and Features of Cryptorchidism in Boys: A Single-Institute Experience

Authors Hori S , Aoki K, Nishimura N , Morizawa Y , Gotoh D , Fukui S , Nakai Y, Miyake M , Torimoto K , Fujimoto K

Received 12 July 2020

Accepted for publication 29 August 2020

Published 14 September 2020 Volume 2020:12 Pages 373—381

DOI https://doi.org/10.2147/RRU.S271869

Checked for plagiarism Yes

Review by Single anonymous peer review

Peer reviewer comments 2

Editor who approved publication: Dr Jan Colli



Shunta Hori, Katsuya Aoki, Nobutaka Nishimura, Yosuke Morizawa, Daisuke Gotoh, Shinji Fukui, Yasushi Nakai, Makito Miyake, Kazumasa Torimoto, Kiyohide Fujimoto

Department of Urology, Nara Medical University, Kashihara, Nara 634-8522, Japan

Correspondence: Kiyohide Fujimoto
Department of Urology, Nara Medical University, 840 Shijo-cho, Kashihara, Nara 634-8522, Japan
Tel +81-744-22-3051
Fax +81-744-22-9282
Email [email protected]

Purpose: Cryptorchidism is one of the most common congenital abnormalities in pediatric urology, and orchiopexy is performed for the prevention of testicular damage and malignant transformation. We examined the distribution and outcomes of cryptorchidism under a single investigator at our institute.
Patients and Methods: This retrospective study included 283 boys diagnosed with cryptorchidism at our institute. Cryptorchidism was diagnosed based on the medical history and physical examination findings. Boys without spontaneous resolution after 6 months of age were indicated for orchiopexy. We investigated the 12-year trend in the distribution and outcomes of cryptorchidism at the institute.
Results: The mean age at diagnosis, gestational age, and birth weight were 2 years, 37 weeks, and 2740 g, respectively. A total of 170 boys underwent orchiopexy under 2 years of age, and 136 boys underwent orchiopexy under the age of 1 year, while 62 boys underwent orchiopexy over the age of 3 years. Abnormalities of the epididymis and disclosure of the processus vaginalis were observed in 44 (25%) and 72 boys (41%), respectively. Comparison of boys with or without hypospadias showed that the age at orchiopexy was higher in boys with hypospadias than in those without hypospadias (P=0.028). In addition, boys without hypospadias had a higher rate of abnormality of the epidermis than those with hypospadias (P=0.024).
Conclusion: Our findings suggest that most boys with cryptorchidism are treated under the age of 2 years and the incidence of epididymal abnormality is relatively high, especially in boys with hypospadias. An understanding of the natural features of cryptorchidism could lead to better management and outcomes. Further research is warranted to develop an appropriate treatment timeline in boys with cryptorchidism.

Keywords: cryptorchidism, hypospadias, orchiopexy, pediatrics, spontaneous resolution

Introduction

Cryptorchidism is one of the most common congenital abnormalities in pediatric urology and is defined as a condition in which the testis incompletely descends into the proper scrotal position, resulting in it being located anywhere between the abdominal cavity and the upper scrotum. The incidence rate is reported to be 2–9% at birth, and some boys have spontaneous resolution by the age of 3–6 months.14 Testicular descent is a complex and still unclear morphological process induced by at least two stages. The first stage is controlled by insulin-like peptide,3 which facilitates gubernacular enlargement, and the second stage is controlled by androgen-facilitating inguinoscrotal migration.4,5 Therefore, various factors affecting these processes, including genetic and environmental components, can be risk factors. Gestational age, birth weight, family history, complications, and maternal smoking during pregnancy are well-known risk factors.69 In addition, it is well known that cryptorchidism is a risk factor for both testicular cancer and infertility in adulthood.9 Therefore, urologists and pediatricians need to diagnose accurately and provide appropriate timely treatment for boys with cryptorchidism.

Orchiopexy is the standard treatment for cryptorchidism. The main aim of orchiopexy is the prevention of testis deterioration caused by a high thermal environment. This is because hypogonadotropic hypogonadism and exposure to higher temperatures are reportedly involved in the disturbed fertility of cryptorchidism.10,11 Histological analysis of cryptorchidism has shown that the testes are progressively damaged over time.12 However, whether orchiopexy results in a decreased incidence of testicular cancer remains controversial. A recent study from Sweden, comprising 16,983 patients, suggested that treatment for cryptorchidism before puberty decreased the risk of testicular cancer.13,14 Although the optimal timing of orchiopexy remains controversial, in most institutes in Japan, including our institute, orchiopexy is performed until at least 2 years of age.

In this study, we aimed to investigate the distribution, outcomes, and features of cryptorchidism in patients treated at our institute by a single investigator. An understanding of the prevalence of cryptorchidism, outcomes including spontaneous resolution and surgical intervention, and features such as the relationship with hypospadias can lead to better management and strategies.

Patients and Methods

Study Cohort and Data Collection

The inclusion criteria were boys who were diagnosed with cryptorchidism at our institute and the exclusion criteria were boys for whom clinical data were insufficient retrospectively. The study flowchart is shown in Figure 1. A total of 283 Japanese boys were diagnosed with cryptorchidism at our institute between January 2006 and December 2017. Of 283 boys, 23 boys (8.1%) were excluded from this study because the baseline clinical data or follow-up data were missing. Subsequently, boys without detailed clinical data were excluded (n=76 [26.9%]) and data of the remaining 184 boys (65.0%), including 204 testes, were investigated retrospectively in this study. Clinical characteristics including age, gestational period, birth weight, follow-up period, location of testis, surgical information, and outcomes were all obtained from medical charts. None of the boys underwent hormonal therapy. The main outcome of this retrospective study was the feature of treatment, especially orchiopexy, in Japanese boys.

Figure 1 Study flow. A total of 283 boys were diagnosed with cryptorchidism between January 2006 and December 2017 at our institute. Twenty-three boys were excluded owing to the lack of baseline data or follow-up data. The remaining 260 boys were investigated in this study. Of the 260 boys, 232 underwent orchiopexy. Of the 260 boys, 76 boys were additionally excluded because of the lack of detailed data. A detailed investigation was conducted for the remaining 184 boys.

Ethics Approval and Consent to Participate

This study was conducted in compliance with the study’s protocol and following the provisions of the Declaration of Helsinki (2013) and was approved by the research ethics committee of Nara Medical University (project identification code: 2630). The requirement for informed patient consent was waived because of the retrospective nature of the analysis. Personal information linked to research subjects and donors was anonymized (when necessary, the information was labeled with an identifying code to make it possible to distinguish between the individuals). Then, deidentified patient data were analyzed.

Diagnosis and Orchiopexy

The diagnosis and treatment plan were conducted by a single investigator (K.A.) who had expertise in pediatric urology. Cryptorchidism was diagnosed based on the medical history and findings of the physical examination and imaging tests, including ultrasonography or magnetic resonance imaging, if necessary. Cryptorchidism was defined when a testis is not at the bottom of the scrotum but at the upper scrotum, in the inguinal canal, or in the intraperitoneal, and a testis cannot be manually descended to the bottom of the scrotum and returned to the original position immediately. Generally, cryptorchidism was classified into palpable and non-palpable testes, and the surgical procedure for cryptorchidism was determined based on this information. Orchiopexy was performed after the age of six months because previous reports showed that cryptorchidism rarely descended after the age of three to six months.1,2 Resolution and termination of follow-up were defined when a testis has descended into the scrotum spontaneously or by orchiopexy.

Statistical Analysis

Statistical analyses were performed and figures were plotted using GraphPad Prism 7.0 (GraphPad Software, San Diego, CA, USA). Student’s t-test or the Mann–Whitney U-test was used for statistical analysis. Two-sided tests were used in all cases, and a P value <0.05 was considered statistically significant in all analyses.

Results

Characteristics of the Cohort

Table 1 shows the clinical characteristics of the cohort of 184 boys for whom detailed clinical data were available. The mean age at diagnosis, gestational age, and birth weight were 2 years (range 0–9), 37 weeks (range 23–42), and 2740 g (range 622–4812), respectively. Of 184 boys, 72 cases (39%) were consulted at our institute following a health examination for the baby. There were 164 boys (89%) with unilateral cryptorchidism (right side, 75 boys [41%]; left side, 89 boys [48%]) and 20 boys (11%) with bilateral cryptorchidism. Of 184 boys, 131 boys, including 143 testes, were diagnosed with palpable testes. The testicular location of 143 palpable testes were as follows: 23 testes (15%) were located at the upper scrotum, 115 testes (81%) were located in the inguinal canal, and 5 testes (4%) were of an unknown location. With regard to complications, there were 13 (7%), 9 (5%), 13 (7%), 2 (1%), and 12 (6%) cases of hydrocele, inguinal hernia, hypospadias, micropenis, and contralateral retractile testis, respectively. The mean follow-up period was 36 months (range 0–145). Eventually, orchiopexy was performed in 162 boys (88.0%; 177 testes [86.7%]), the condition improved spontaneously in 12 boys (6.5%; 14 testes [6.9%]), and 10 boys (5.5%; 13 testes [6.4%]) were being followed up at the last observation date in this study.

Table 1 Characteristics of 184 Boys with Cryptorchidism

Features of Boys Who Underwent Orchiopexy

Table 2 shows the clinical characteristics of the cohort of 162 boys who underwent orchiopexy and had available detailed clinical data. The mean age, height, and weight at orchiopexy were 1 year (range 0–9), 79.3 cm (range, 48.0–130.0), and 11.1 kg (range, 2.8–28.0), respectively. The surgical procedures were divided into 4 groups: scrotal (4 boys, 2%), inguinal (77, 48%), laparoscopic (4, 2%), and both laparoscopic and inguinal (17, 11%). Preoperative testicular atrophy was observed in 18 testes (10%). During orchiopexy, abnormality of the epididymis and closure of the processus vaginalis were observed in 44 (25%) and 24 boys (13%), respectively, based on the available data. The Fowler–Stephens method was used for 8 testes (5%) located intra-abdominally. The gonadal artery was cut in all 8 testes, and of the 8 testes, 4 were treated in two steps, and the remaining 4 testes were treated in one step. During orchiopexy, 6 testes were vanishing testes and 18 testes were resected because of nubbin. In addition, there was no perioperative complication. Eventually, there was no testis re-elevation, and testicular atrophy was observed in 1 testis after orchiopexy.

Table 2 Surgical Information (n=162)

Comparison of Characteristics Between Boys Who Underwent Orchiopexy and Boys Improved Spontaneously

In the cohort of 184 boys who had available detailed data, 162 boys underwent orchiopexy, the condition in 12 boys improved spontaneously, and 10 boys were under observation. To investigate the differences in characteristics between boys who underwent orchiopexy and boys in whom the condition improved spontaneously, 162 and 12 boys were compared. Table 3 shows the clinical characteristics of the cohort of 174 boys. There was no significant difference in the age at diagnosis, gestational age, or birth weight between the two groups (P=0.41, P=0.40, and P=0.10, respectively). All boys who exhibited spontaneous improvement were diagnosed with cryptorchidism incidentally (P=0.017). In addition, there were no differences in the side, palpation, and location of the testis between the two groups (P=0.33, P=0.53, and P=0.31, respectively).

Table 3 Comparison of Characteristics Between Boys Who Underwent Orchiopexy and Boys Improved Spontaneously (n=174)

Comparison of Characteristics Between Cryptorchidism without Hypospadias and with Hypospadias

In the cohort of 184 boys who had available detailed data, 13 boys were concomitant with hypospadias. To investigate the difference in characteristics between boys without and with hypospadias, 171 and 13 boys were compared. Table 4 shows the clinical characteristics of the cohort of 184 boys. There was no difference in the age at diagnosis between the two groups. Boys with hypospadias had significantly shorter gestational period and lower birth weight than those without hypospadias (P=0.0058 and P=0.0006, respectively). Boys with hypospadias were also incidentally diagnosed with cryptorchidism (P=0.017). Comparison of boys who underwent orchiopexy in both groups (boys without hypospadias, n=150; boys with hypospadias, n=12) showed that the age at orchiopexy was higher in boys with hypospadias than in those without hypospadias (P=0.028). In addition, boys without hypospadias had a higher rate of abnormality of the epidermis than those with hypospadias (P=0.024).

Table 4 Comparison of Characteristics Between Cryptorchidism without Hypospadias and with Hypospadias (n=184)

Discussion

This study summarizes our experience of treating boys with cryptorchidism, including the frequency and its chronological transition, at our institute for a period of 12 years. Orchiopexy performed at the mean age of 1 year. Vanishing testes were observed in 6 testes and orchiectomy was performed in 18 testes with nubbin. After orchiopexy, there was no testis re-elevation, and testicular atrophy was observed in 1 testis. A comparison of the characteristics between boys whose condition improved after orchiopexy and in whom the condition improved spontaneously showed that all cases of spontaneous improvement were diagnosed incidentally. In addition, a comparison of the characteristics between boys without hypospadias and boys with hypospadias revealed that boys with hypospadias tend to be born in a shorter gestational time, with low birth weight, and epididymis abnormalities.

Cryptorchidism is one of the most common diseases in pediatric urology, while the mechanism of development is still not completely understood, and the optimal timing of orchiopexy remains controversial. In Japan, orchiopexy is performed by the age of 2 years based on the recommendation of the Japanese guidelines for cryptorchidism.15 The European Association of Urology (EAU) guidelines recommend that any kind of treatment that consists of leading the testis to the bottom of the scrotum should be started at the age of 6 months and finished by the age of 12 months or at the latest, 18 months.16 The American Urological Association (AUA) guidelines also recommend that orchiopexy should be started at the age of 6 months and finished within the next year.17 The treatment is commonly initiated at 6 months of age. This is because cryptorchidism rarely descends after the age of 3 to 6 months, while spontaneous resolution is generally observed by the age of 6 months; therefore, careful follow-up is recommended by that period.1,2 In this study, spontaneous improvement was observed in 12 cases, of which 5 (41.6%) improved over the age of 12 months. Therefore, the criteria for decision-making for orchiopexy might still be controversial. Both the EAU and AUA guidelines recommend that orchiopexy should be performed at the latest by 18 months of age, and the EAU guideline is more rigorous by advocating that orchiopexy should be performed by the age of 12 months. A previous report also suggested that orchiopexy should be performed within the first year of life to protect fertility potential and no later than the age of 2 years in boys with palpable inguinal cryptorchid testes because of a progressive loss of germ cells and Leydig cells by histological analysis of cryptorchidism.18 Although the present study did not investigate fertility in adulthood, histological changes that cause testicular atrophy might not have occurred. The Japanese guidelines might strictly recommended an earlier timing for performing orchiopexy, but further evaluation is needed to establish an evidence in Japan.

With regard to the feature of orchiopexy in this study, 25% of cases that underwent orchiopexy were concomitant with abnormality of the epididymis. Favorito et al previously reported that anomalies of the epididymis were found in 35% of boys with cryptorchidism and in only 4% of normal fetuses. They also mentioned that disclosure of the processus vaginalis was observed in 58% of boys with cryptorchidism and in only 5% of fetuses.19 In this study, disclosure of the processus vaginalis was observed in at least 41% of boys. Barthold et al showed in their prospective study that a closed, partially closed, and open processus vaginalis was associated with an abnormality of the epididymis in 14%, 36%, and 69% of boys, respectively, and abnormalities of the epididymis were more frequently associated with cryptorchidism (72%) than with descended (34%) testes. They concluded that a higher incidence of epididymal anomalies associated with disclosure of the processus vaginalis and androgenic stimulation might be required not only for closure of the processus vaginalis but also epididymal development.20 Kim et al also reported that epididymal abnormalities were observed more frequently when testis was located at proximal from the scrotum, including distal to the external inguinal ring, inguinal canal, and the abdomen.21 Although unclear mechanisms have been implicated in congenital diseases, deficiency in the androgen exposure might cause various phenotypes including cryptorchidism, abnormalities of epididymis, and disclosure of processus vaginalis.

With respect to deficient androgen exposure, cryptorchidism is closely correlated with hypospadias and known as a component of the testicular dysgenesis syndrome composed of cryptorchidism, hypospadias, testicular cancer, and low sperm quality.22,23 In this study, 13 boys (7%) were diagnosed with cryptorchidism and hypospadias. Boys with hypospadias had a shorter gestational period, lower birth weight, and higher incidence of epididymal abnormalities than boys without hypospadias. Iwatsuki et al showed that testicular function in boys with both cryptorchidism and hypospadias is more severely impaired than that in boys with cryptorchidism or hypospadias, according to an analysis of serum hormones including luteinising hormone, follicle-stimulating hormone, and total testosterone.24 Therefore, boys with both cryptorchidism and hypospadias might need to undergo orchiopexy early to minimize the damage to the testis.

The present study has some limitations. The patient data were obtained retrospectively from a single institution, and the sample size was small. In boys with cryptorchidism, the evaluation and prevention of infertility and testicular cancer in adulthood are the most interesting and important issues. None of the boys developed testicular cancer, while we evaluated only boys who had available data in adulthood in this study. We could not evaluate infertility in this study. Further tracking investigation is needed to evaluate these paramount issues.

Conclusion

Our findings suggest that most boys with cryptorchidism are treated under the age of 2 years and the incidence of epididymal abnormality is relatively high, particularly in boys with hypospadias. Although cryptorchidism is one of the most common diseases in pediatric urology, the mechanism of its development is still not fully understood. Further research is warranted to develop an appropriate treatment timeline in boys with cryptorchidism.

Acknowledgments

The authors would like to thank all patients and their families who participated in this study for their important contributions. We also wish to thank Mariko Yoshimura (Department of Urology, Nara Medical University, Nara, Japan) for invaluable help with obtaining and summarizing the data used in this study.

Disclosure

The authors report no conflicts of interest in this work.

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