The Effect of Intratesticular Injection of Human Adipose-Derived Stem Cell (hADSC) on Testicular Oxidative Stress and Spermatogenesis Process in the Varicocele Rat Model

doi:10.21203/rs.3.rs-492675/v1

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The Effect of Intratesticular Injection of Human Adipose-Derived Stem Cell (hADSC) on Testicular Oxidative Stress and Spermatogenesis Process in the Varicocele Rat Model

https://doi.org/10.21203/rs.3.rs-492675/v1

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Introduction: Varicocele is the predominant cause of male infertility and was found in 19% - 41% of men with primary infertility and 45% - 81% of men with secondary infertility. Human adipose Derived Stem Cells (hADSC) can suppress oxidative stress in some oxidative injury model. Therefore, this study would like to investigate the effect of intratesticular hADSC injection on MDA level and spermatogenesis process by histopathological examination in the varicocele rat model.

Method: This is an experimental study. A total sampling of 9 male Wistar rats were divided into three groups. Group I consist of 1 Wistar rats without any treatment or model (sham group), group II consist of 4 Wistar rats with varicocele model without hADSC therapy (control group), and group III consist of 4 Wistar rats with varicocele model and were given injections of 1.0x10⁶ hADSC cells intratesticularly 30 days after model was made (therapy group). Testicular tissue was harvested for evaluation.

Results: In all varicocele model rats (group II and III), the result of MDA level in therapy group (2.53 mol/liter) was significantly lower than the MDA level in control group (4.43 mol/liter) (p = 0.01). On histopathological examination, the average Johnson's Score in the therapy and control group was 9,77 and 9,18, respectively. The analysis showed Johnson’s score in the intervention group was significantly higher (p = 0.018).

Conclusion: Intratesticular injection of hADSC can help reduce MDA levels and improve spermatogenesis process, which is damaged by varicoceles.

Urology & Nephrology

human adipose-derived stem cell

varicocele

spermatogenesis

infertility

malondialdehyde

MDA

Infertility is one of the fundamental problems affecting human life.¹ According to the Demographic and Health survey in collaboration with WHO which was conducted from 1990 to 2004, it was found that one in every four couples in developing countries was affected by infertility.²

Male infertility is a concern and contributes to 50% of total infertility cases.^3,4 Varicocele is the most common cause of male infertility worldwide. Varicocele is found in 19% − 41% of men with primary infertility and the cause of 45% − 81% of men with secondary infertility, contributing as the most common cause of male infertility, which can be treated surgically. Studies have shown that varicoceles' incidence has been associated with increased oxidative stress, which may lead to the overproduction of reactive oxygen species (ROS) such as superoxide anion radicals, hydrogen peroxide, singlet oxygen, and nitrite proxy radicals.^5,6

Reactive oxygen species are the oxygen metabolites in the form of a collection of free radicals which react easily. Reactive oxygen species will induce the lipid peroxidation process in the plasma membrane of spermatozoa and may cause damage to spermatozoa in semen and seminiferous tubules, disrupting spermatogenesis.^1,7,10

Oxidative stress can be assessed by measuring the Malondialdehyde (MDA), an organic compound resulting from lipid peroxidation. It can be used to monitor the degree of tissue damage from oxidative stress.

Stem cell transplantation to improve organ structure or tissue function has become a new therapeutic strategy. Stem cells are capable of regenerating and differentiate into specific types of cells.

Adipose-derived stem cells (ADSC) are one of the mesenchymal stem cells (MSC) types with the most optimal therapeutic cell. These stem cells are mesenchymal stromal cells found in the perivascular adipose tissue. A study showed that ADSC could suppress oxidative stress by increasing superperoxide dismutation that will reduce oxidative stress in azoospermia condition.¹¹

Based on the data above, it can be assumed that the administration of ADSC can suppress oxidative stress in varicoceles and improve spermatogenesis. ADSC is considered to be one of the alternative therapies besides surgical therapy of varicocele. We aim to study the effects of ADSC administration on histopathologically assessed spermatogenesis.

This research is a randomized experimental study that used experimental animals (experimental animal study). This research was conducted after obtaining approval and recommendation from the Laboratory Ethics Committee of the Institute of Biosciences, Brawijaya University Malang and were carried out in accordance with relevant guidelines and regulations. A total of nine male Wistar rats weighing 300–350 grams were used as samples and divided into 3 groups. Group I consisted of one Wistar rat without treatment or model (sham group), Group II consisted of four Wistar rats with varicocele model without hADSC therapy (control group). Group III consisted of four Wistar rats with varicocele model and was given 1.0x10⁶ cells intratesticular hADSC injection in 100µl of PBS solution as deep as the tunica albuginea 30 days after the varicocele model was made (therapy group). All rats were euthanized by Isoflurane gas inhalation, and following euthanasia, left orchidectomy was performed 30 days after ADSC administration in group III (Fig. 1). Testicular tissue was harvested for histopathological examination to evaluate the spermatogenesis process using Johnson’s score. This study has been accepted by the Ethics Committee with the research number 013-KEP-UB-2020.

Varicocele Model of Wistar Rat

Adult Wistar rats were put under anesthesia via an intraperitoneal route using 90 mg/kg ketamine and 4 mg/kg xylazine. A midline laparotomy incision was performed to expose the upper left abdominal quadrant. The left kidney and associated blood vessels were then exposed by displacing the intraperitoneal organ to the right. The left kidney, left renal vein, left adrenal vein, and left spermatic vein were then visualized. Through a blunt dissection, the left renal vein was freed from the adhering fat and connective tissue. The left renal vein should be exposed in a medial position from the entry point of the left spermatic vein and left adrenal vein. After the left renal vein was freed from the surrounding tissue, a 4 − 0 silk suture was used to ligate the vein. Ligation was carried out by inserting a 0.85 mm metal wire in the middle and knotted four times, then the wire was removed, and the left renal vein would slightly expand according to the size of the knot. This would result in consistent partial occlusion of the left renal vein in each model (Fig. 2). The intraperitoneal organs were then returned to their original position, and the abdomen was resutured by using 2 − 0 silk suture.¹

Human Adipose-Derived Stem Cell Isolation and Characterization

Human adipose tissue was obtained from adult male/female fat subjected to other surgeries who had agreed to donate his/her fat for research by signing informed consent. Adipose tissue was obtained with needle biopsy or liposuction aspiration method. Adipose tissue was stored at room temperature for no more than 24 hours before use. Then, the adipose tissue was washed with phosphate-buffered saline (PBS) containing 5% penicillin/streptomycin (P/S). Culture and cell multiplication were done by thawing 1 tube, splitting once, and changing the medium once.

Flow cytometry assay was used to validate the isolated cells using the following markers: CD105 (+), CD45 (-). In the validation application, cell viability was at 86.78%, with 1 cc each containing 1.0x10⁶ cells for use. All tissue harvesting procedures, cell isolation, culture, and characterizations were conducted in the Tissue and Cell Bank of Dr. Soetomo General Hospital Surabaya, sample-numbered with 120.E/MSC/Penelitian/AdiposeTasijo_09/060220 and were declared suitable for the application.

Johnson’s Score

One of the parameters for evaluating spermatogenesis in the seminiferous tubules is by using Johnson's score. The testicular tissue is dehydrated through a graded series of 70–100% ethanol and embedded in paraffin. One portion with a diameter of 5 µm was obtained to be deparaffinated and stained with Hematoxylin-Eosin (H&E), which was then examined under a light microscope. The histopathological grade of spermatogenesis was assessed between 1 and 10 based on the development of sperm cells found in at least 5 microscopic areas in 100 seminiferous tubules. Johnson's total score is then determined by dividing the total score by the number of tubules evaluated.

Left Internal Spermatic Vein Width

The success of the varicocele model was assessed based on the left internal spermatic vein width of the male rats 4 weeks after ligation. Comparison of mean internal spermatic vein width in each group is shown in Table 1. If Group II and III were combined into 1 group, namely the group of mice with a varicocele model, and were compared to group I without varicocele model, it was shown that partial ligation of the left renal vein was proven to induce the development of artificial left varicocele in mice. The mean internal spermatic vein width in the group of rats with varicocele model was 0,70 mm. This result was greater compared to group I (sham) without varicocele model, which was 0.23 mm. (p = 0.005).

Table 1

Comparison of Left Internal Spermatic Vein Width
Group	N	Left Internal Spermatic Vein Width (mm)
Group	N	Mean	Std Deviation	Range
Without Varikokel	1	0.23	-	-
With Varikokel	8	0.7	0.070	0.52–0.72
p = 0.005

MDA Concentration

There was a significant difference in MDA levels between group II (control) and group III (therapy) as shown in Fig. 3 (p = 0.01). The mean MDA levels in the therapy group were lower (2.53 mol/liter) than the group without ADSC (4.43 mol/liter).

Histological Examination (Johnson’s Score)

There is also a significant difference in Johnson's Score between group II (control) and group III (therapy) (Figs. 3 and 4) The average value of Johnson's Score in group III (therapy) was higher than group II (control). Group III, who received ADSC, had an average Johnson's score of 9.77, whereas group II without ADSC had an average Johnson's score of 9.18. Data analysis by using the Kolmogorov Smirnov test showed that the data distribution was not normal (p < 0.05). Based on the results of normalization tests that were not normally distributed, data analysis was performed using the Mann-Whitney test. There was a significant difference in the mean value of Johnson's Score between treatment groups with p = 0.018

Several theories hypothesized the relationship between varicocele and infertility, including increased temperature in germ cells sensitive to temperature changes, cadmium accumulation, testicular hypoxia, and metabolite reflux, leading to increased stress oxidative. This oxidative stress causes damage to the function and maturity of spermatogenesis, membrane peroxidation, and hormonal disturbances, which reduce male reproductive potential in the form of decreased sperm count, shape, and motility.¹⁴

In this study, it was found that there is a significant difference in mean MDA levels between groups (p = 0.01). MDA levels in the therapy group were lower (2.53 mol/liter) than the group without ADSC (4.43 mol/liter), this result was in line with other studies showing that ADSC can self-renew in the vascular stroma and can influence local regulation of angiogenesis and blood vessels remodeling, thereby suppressing oxidative stress by increasing the activity of superoxide dismutase which will cause a decrease in the formation of MDA.^15–17

Varicoceles can cause progressive deterioration of the Sertoli cells and trigger the release of spermatogonia cells before their peak maturity. Histopathologic examination in varicocele may show normal and defective spermatogenesis.¹⁸

In a previous study conducted by Qin et.al, it was found that varicocele can cause damage to the endothelial part of the testis and seminiferous tubules, as well as interfering with the spermatogenesis process. They conducted a study by ligating the left renal vein in mice until it was enlarged by two or more times and found a significant reduction in sperm count compared to the control group.¹⁹

This study showed that the group of mice with varicocele receiving ADSC therapy had a better Johnson’s score (9,77) than the group of mice with varicocele without receiving therapy (9,18)(p = 0.018).

The group model of mice with varicocele that received ADSC therapy had an average Johnson’s Score of 9.77, with the highest score of 9,93 and the lowest score of 9,4. This score showed normal spermatogenesis histopathologically. Normal spermatogenesis is characterized by the presence of seminiferous tubules that are covered by a thin basal membrane and germinal epithelium, indicating normal sperm development from spermatogonia to spermatocytes, including spermatids and spermatozoa.

Whereas in the group model of varicocele mice without ADSC therapy, the lowest Johnson's score was 8.33. The picture in this sample shows the histopathological features of hypospermatogenesis, where the germinal epithelium shows a normal stage of sperm development, but the number is greatly reduced.

We used human ADSC in this study because the number of fat cells from liposuction was abundant, and in the future, we aim to use human ADSC in human patients. Therefore we started using human ADSC in mice. Human ADSC will not induce xenogenic immunological reactions because it does not express MHC class II.

We performed ADSC intratesticular injection method and found a significant result of spermatogenesis improvement. Intratesticular injection of ADSC gives a better result compared to intravenous injection because there is a blood-testis barrier in the intravenous line that may prevent stem cells from entering testis tissue through the circulation. In addition, it will prevent ADSC from getting trapped in the lungs due to their large size of molecules.²⁰ Another advantage of intratesticular administration of stem cells is that they can significantly protect from testicular damage. Although complications from injection procedure may cause anti-sperm antibody formation that can lead to infertility, long term follow up is necessary.²¹

Sampling was carried out on the 30th day after ADSC administration to the group of rats with varicocele. The 30 days assessment for sampling was used to assess the success of the effect of ADSC on the spermatogenesis cycle of Wistar rats, ranging from 30 to 48 days.²²

Stem cell injection may prevent tissue damage caused by oxidative stress. After administration of stem cells, stem cells were integrated into interstitial area and seminiferous tubules and into the vascular walls of the testis, secreting various growth factors, such as Basic Fibroblast Growth Factor and Stem Cell Factor, which would reduce the level of oxidative stress, regulating hormonal levels and promoting regeneration of Leydig cells and germ cells, which would improve the process of spermatogenesis and increase Johnson’s Score in the testis.²¹ Intratesticular injection of ADSC also has the effect of increasing and repairing testosterone levels. It suggests that ADSC may improve the endocrine function of the testis.²⁰

Male infertility could be a consequence of interference in germ cells, Sertoli or Leydig due to varicocele. This can be corrected through stem cell transplantation.

Based on the results and discussion of this study, it can be concluded that the administration of ADSC may improve the spermatogenesis process damaged by varicoceles. This shows the benefits of ADSC as a stem cell therapy which may be further investigated as one of the therapeutic options in improving the spermatogenesis process for patients with varicocele.

Ethics approval and consent to participate

We have read and complied with the policy of the journal on ethical consent and the standards of animal care, as stated in the Guide to Authors. The work has been approved by our institution’s Institutional Review Board with number 013-KEP-UB-2020

Consent for publication

Not Applicable

Availability of data and materials

All data generated or analyzed during this study can be requested to the corresponding author.

Competing interests

None

Funding

This study was supported from internal Universitas Padjadjaran grant

Authors' contributions

Conception and design: All authors

Administrative support: All authors

Provision of study materials or patients: All authors

Collection and assembly of data: All authors

Data analysis and interpretation: All authors

Manuscript writing: All authors

Final approval of manuscript: All authors

Acknowledgements

The authors have no acknowledgments.

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Table 1 Comparison of Left Internal Spermatic Vein Width

Group	N	Left Internal Spermatic Vein Width (mm)
Group	N	Mean	Std Deviation	Range
Without Varikokel	1	0.23	-	-
With Varikokel	8	0.7	0.070	0.52-0.72

p = 0.005

No competing interests reported.

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The Effect of Intratesticular Injection of Human Adipose-Derived Stem Cell (hADSC) on Testicular Oxidative Stress and Spermatogenesis Process in the Varicocele Rat Model

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