The Association between Serum Follicle-Stimulating Hor-
mone Levels and the Success of Microdissection Testicular 
Sperm Extraction in Patients with Azoospermia

Mehmet Erol Yildirim,1 Akif Koc,2 Ikbal Cekmen Kaygusuz,3 Hüseyin Badem,4 Omer 
Faruk Karatas,1 Ersin Cimentepe,1 Dogan Unal5

 1Department of Urology,   
 Turgut Ozal University, Faculty  
 of Medicine, Ankara 06510, Tur-   
 key.
  2Department of Urology, Balı- 
 kesir University, Faculty of Me- 
 dicine, Balikesir 10310, Turkey.
 3Department of Gynecology and  
 Obstetrics, Turgut Ozal Univer-
 sity Faculty of Mediine, Ankara  
 06510, Turkey.
 4Department of Urology, Yüksek  
 İhtisas Training and Research 
 Hospital, Ankara 06520, Tur-
 key.
 5Department of Urology, Hacet- 
 tepe University Faculty of Me- 
 dicine, Ankara 06520, Turkey.

Corresponding Author:
  Mehmet Erol Yildirim, MD
  Department of Urology, Tur-
 gut Ozal University School of   
 Medicine, 06510, Yenimahalle, 
 Ankara, Turkey.

 Tel: +90 312 2035221 
 Fax: +90 312 2213670
 E-mail:doctorerol@yahoo.com

 Received April 2014
 Accepted June 2014

Purpose: To evaluate the predictive power of luteinizing hormone (LH), follicle-stimulating hormone 

(FSH), testosterone, testicular biopsy histology and male age were evaluated with respect to the success 

of sperm retrieval in a microdissection testicular sperm extraction (microTESE) procedure, pregnancy 

and live birth rates.

Materials and Methods: We examined the data of 131 infertile men with non-obstructive azoospermia, 

who have undergone microTESE operation. The men were classified into two groups based on serum 

follicle-stimulating hormone (FSH) levels ≤ 15 mIU/mL (group 1) and > 15 mIU/mL (group 2).

Results:  Group 1 consisted of 59 patients (mean age 36.2 ± 6.2 years) and group 2 consisted of 72 (mean 

age 38.8 ± 7.4 years) patients. Sperm retrieval and pregnancy rates were 66.1% and 16.9% in normal 

FSH group, respectively. These parameters were higher than those of men with FSH > 15 (43% and 

8.3%, respectively). Only 128 patients had histopathological diagnosis. Sperm was retrieved from 12/30 

(40%) patients with maturation arrest, 9/29 (31.03%) patients with seminiferous tubules atrophy, 14/40 

(35%) patients with sertoli cell only syndrome and 13/13 (100%) of patients with hypospermatogenesis. 

There was no statistically significant difference in pathological diagnosis between pregnancy and live 

birth rates.

Conclusion: These results demonstrate that there is a significant difference with sperm retrieval, preg-

nancy rates and live birth rates comparing the FSH levels. Histopathological findings did not associate 

with successful microTESE, pregnancy rates and live birth rates.

Keywords: infertility, male; microdissection; sperm retrieval; testicular diseases; azoospermia; sper-

matogenesis.

1825   Sexual Dysfunction and Fertility

SEXUAL DYSFUNCTION AND FERTILITY



UROLOGY JOURNAL   Vol. 11   No. 04   July - August 2014   1826

Association of FSH on microTESE Success-Yildirim et al

when further dissection would jeopardize the testicular blood supply. 

A sample was taken for histopathological investigation from each 

procedure. The patients were divided into two groups based on their 

serum FSH levels; ≤ 15 mIU/mL (group 1) and > 15 mIU/mL (group 
2). The patients were also classified according to their testicular 

pathology, such as maturation arrest, testicular atrophy, 

sertoli cell only syndrome or hypospermatogenesis. The groups 

were compared with regards to sperm retrieval, pregnancy and live 

birth rates. Informed consent was taken from all patients in order 

to use their data. Also, ethics approval was obtained from our 

Institutional Ethics Committee.

Statistical Analysis
Data were analyzed using Statistical Package for the Social Science 

(SPSS Inc, Chicago, Illinois, USA) version 16.0. Independent groups 

were compared using the Mann Whitney U test and group rates 

were compared by the student’s t-test. P values of < .05 were con-

sidered as statistically significant.

RESULTS
The average age of patients undergoing microTESE was 37.72 

± 5.8 (range, 26-57) years. There were 59 patients in group 1 and 

72 patients in group 2. The mean age of group 1 and 2 were 36.2 ± 

6.2 and 38.8 ± 7.4, respectively. There were statistically significant 

differences between both groups with regards to sperm retrieval (P 

= .008), but not to pregnancy rates (P = .136) nor live child delivery 

rates (P = .136) (Table 1).

The mean serum FSH levels were 17.4 ± 16 (95% confidence inter-

val [CI]: 13.6-21.3) m I U / m L  and 24.1 ± 15.8 (95% CI: 20.1-28.2) 

mIU/mL in the sperm retrieved and non-sperm retrieved groups. 

There was a statistically significant difference in serum FSH levels 

(P = .03) between sperm retrieved and non-sperm retrieved groups. 

However, there were neither statistically significant differences in 

serum FSH levels between pregnancy and non-pregnancy groups (P 

= .655) nor between child delivered and non-child delivered groups 

(P = .655) (Table 2). With regards to the patient’s ages, there were 

no statistically significant differences between sperm retrieved and 

non-retrieved groups (P = .66), child delivered and non-child de-

livered groups (P = .457) and pregnancy and non-pregnancy groups 

(P = .457) (Table 2).

There is a negative correlation between sperm retrieval and both se-

rum FSH levels and patient ages (r = -0.207, P = .018 and r = -0.159 

P = .07, respectively). We could collect only 128/131 patients’ data 

regarding their testicular histology. According to these data, there 

were no statistically significant difference between histological 

findings and sperm retrieval (P = .178), pregnancy rate (P = .198), 

or child delivered groups (P = .063) (Table 3). Also there was only a 

positive correlation between hypospermatogenesis and sperm retriev-

al (r = .281, P = .001).

DISCUSSION

INTRODUCTION

Infertility is defined as the inability to conceive a child after one year of regular unprotected intercourse. (1) Infertility is a major health problem that effects approximately 15% of couples, and 
nearly 50% of this is because of male infertility. (2) There are many 

reasons for male infertility, but testicular factors play the leading role. 

Assisted reproductive techniques, such as in vitro fertilization (IVF) 

and intracytoplasmic sperm injection (ICSI), offer the possibility 

of fertilizing oocytes even if only a small number of spermatozoa are 

found in the ejaculate. In cases of azoospermia, sperm is obtained from 

the epididymis and testes by surgical procedures. Microdissection tes-

ticular sperm extraction (microTESE) is performed to recover sperm 

from azoospermic patients and was shown to be successful even in 

testes with only small islets of spermatogenesis.(3) However, every 

failed microTESE-ICSI procedure exposes the couple to an emo-

tional and financial burden. It becomes increasingly important to 

predict the success of sperm retrieval using non-invasive parameters 

before the attempted treatment. There are many studies about using 

a patient’s hormonal status and previous testicular biopsy histology 

to predict the success of microTESE in recent years. (4) In our study, 

the predictive power of luteinizing hormone (LH), follicle-stimulating 

hormone (FSH), testosterone, testicular biopsy histology and male 

age were evaluated with respect to the success of sperm retrieval in 

a microTESE procedure, pregnancy and live birth rates.

MATERIALS AND METHODS
Study Subjects
The data of 131 patients with non-obstructive azoospermia who 

have undergone microTESE between January 2006 and November 

2012 were examined. Inclusion criteria were, no sperm found in the 

ejaculate, existence of bilateral vas deferens and no history of 

genital infection, surgery or vasectomy. Azoospermia was con-

firmed via analysis of two different semen analyses according to 

World Health Organization (WHO) criteria.(5) A semen sample 

was also collected on the day of microTESE. All hormonal levels 

were determined by the chemiluminescent immunoassay (Immulite 

2000, Siemens diagnostics, Los Angeles, C A ,  USA) method. The 

reference range of FSH was 1.5-15 mIU/mL, LH was 4-8.6 mIU/

mL and testosterone was 245-1600 ng/dL.

All patients underwent microTESE with local anesthesia. After a 

midline scrotal incision, we pushed out the biggest testis and 

opened the tunica vaginalis. After the visualization of the tunica 

albuginea, the remainder of the procedure was performed under × 

20 magnification with an operative microscope. Small samples were 

excised from the testis. Each sample was examined immediately by 

the embryologist under × 200 magnification. If no spermatozoa were 

identified in the initial sample, the incision of the tunica albuginea 

was expanded and subsequent samples were taken from the larger 

and more opaque tubules, if needed, from the contralateral testis. 

The procedure stopped when enough spermatozoa were retrieved or 



Therefore, according to Ramasamy and colleagues, we can retrieve 

sperm by microTESE even despite FSH values o f  2-3 times 

higher than normal. Otherwise, pregnancy (46%, 50%, 52% and 

46%, respectively) and live birth rates (38%, 45%, 44% and 36%, 

respectively) were similar in both serum FSH normal and higher 

groups.(4) Bohring and colleagues showed that both serum FSH and 

inhibin B are relevant with spermatogenesis. But they had not con-

cluded these hormones to be definite predictive factors because de-

spite the abnormal levels of these hormones, successful microTESE 

were performed.

Many studies have shown that the histopathology of testes to be 

the best predictor concerning the retrieval of sperms in microTESE.
(13) But, there is some controversy as to whether a random sampling 

may not represent the inherent heterogeneity, because augmenta-

tion of the sampling may cause inflammatory changes, hematoma, 

parenchymal fibrosis or permanent devascularization of the testis.
(14) Tunç and colleagues reported a 42.1% sperm retrieval rate at ger-

minal aplasia, and the best (83.3%) at hypospermatogenesis.(15) Su 

and colleagues reported 24% sperm retrieval rates at sertoli cell only 

syndrome (SCOS) and higher rates were 79% at hypospermatogene-

sis.(16) Tournaye and colleagues reported 67% sperm retrieval rates at 

SCOS, 82% at maturation arrest and 100% at hypospermatogenesis.
(17) Our sperm retrieval rates were 35% at SCOS, 40% at maturation 

arrest, 31.03% at seminiferous tubules atrophy and 100% at hypo-

spermatogenesis, which are consistent with current literature. As we 

grouped patients according to the histopathologic diagnoses, there 

was no correlation with sperm retrieval rates, pregnancy rates and 

live birth rates except in patients with hypospermatogenesis. The 

main paradox of the testis biopsy is the doubt about the histology of 

the rest of the testis.

Evaluation of serum FSH levels with testis histology can be a 

predictor for sperm retrieval in microTESE. There was a correla-

tion between low serum FSH and hypospermatogenesis at sperm 

retrieval; on the other hand, there was not any correlation between 

maturation arrest and SCOS. (3) In another study, a group of 17 men 

with hypospermatogenesis, 22 men with obstructive azoospermia 

and 29 men with normal spermatogenesis in whom sperm was re-

trieved successfully with microTESE, there was no difference in se-

rum FSH levels. (18) Maturation arrest (50%) was the common pat-

tern in the serum FSH normal group, and otherwise SCOS (51.1%) 

was the main group in the higher serum FSH group in our study.

About 15% of couples have infertility problems.(2) The chances 

of having a pregnancy increases from the first month (25%) to a 

year (90%).(6) Male factors play an important role in 50% of infertile 

couples.(7) Today, microTESE plus ICSI gives the chance to have a 

baby to infertile couples.(8) Many infertile couples who were con-

sidered desperate cases in past years may now have children with 

the rise of microTESE and ICSI techniques in clinical practice. 

While there are significant contributions of microTESE proce-

dures to infertility, it has a particular organic and psychological 

morbidity due to its invasiveness. For this reason, predictive mark-

ers are needed for the clinician to make decisions about the first 

or repetitive microTESE. Most of the past studies have focused 

specifically on testicular histology and serum FSH levels to make the 

decision about microTESE.

The present study focuses on whether any association between se-

rum FSH, LH and testosterone levels, testicular histology and sperm 

retrieval, pregnancy and live birth rates. Our threshold level for 

FSH was 15 mIU/mL. Some reports mentioned that we can’t re-

trieve sperm by microTESE with higher serum FSH levels because 

of existing testicular atrophy. (9) Ezeh and colleagues showed a weak 

correlation between serum FSH level and successful microTESE.
(10) No matter how high the serum FSH level that, there is always a 

chance to retrieve sperm.(11) In our study, the sperm retrieval rates 

at serum FSH normal group and serum FSH > 15 mIU/mL group 

were 64.4% and 43%, respectively, and pregnancy and live birth 

rates were 16.9% and 8.33%, respectively. Even if there was a 

statistically significant difference between sperm retrieval rates and 

serum FSH levels (P = .008), there was not such a correlation be-

tween serum FSH levels and pregnancy and live birth rates. Rama-

samy and colleagues reported that sperm retrieval rates in the groups 

with serum FSH values of 15-30 mIU/mL, 31-45 mIU/mL and 

> 45 mIU/mL were 60%, 67% and 60%, respectively, and this 

was, surprisingly, higher than the normal serum FSH (51%) group.(4) 

Variables  Serum FSH Levels (mIU/mL)       P Value
                                       ≤ 15            > 15
Sperm retrieved 38/59 (66.1) 31/72 (43)     .008
Pregnancy rate            10/59 (16.9)          6/72 (8.33)        .136
Live birth rate             10/59 (16.9)          6/72 (8.33)        .136

Table 1. Sperm retrieval, pregnancy and live birth rates compared between 
two groups.*

Variables  Sperm Retrieval      Pregnancy Occurrence  Child Delivery
          Yes (n = 69) No (n = 62)     P Value       Yes (n = 69)     No (n = 62)   P Value    Yes (n = 69)   No (n = 62)    P value

Serum FSH (mIU/mL)    17.48 ± 6.02   24.1 ± 15.8      .03           15.9 ± 14.3      21.2 ± 16.4    .655          15.9 ± 14.0     21.2 ± 16.4    .652 

Age (years)             37.5 ± 5.5      38.5 ± 7.8        .66           37.2 ± 5.9        38.1 ± 6.7      .457         37.4 ± 6.2     38.2 ± 6.6       .457  

Table 2. Comparison of FSH levels and age according to the sperm retrieval, pregnancy and live birth rates.

* Data are presented as no. (%).

1827   Sexual Dysfunction and Fertility



UROLOGY JOURNAL   Vol. 11   No. 04   July - August 2014   1828

10.  Ezeh UI, Moore HD, Cooke ID. Correlation of testicular sperm extra-
  ction with morphological, biophysical and endocrine profiles in men   
  with azoospermia due to primary gonadal failure. Hum Reprod.   
  1998;13:3066-74.

11.  Kim ED, Gilbaugh JH 3rd, Patel VR, Turek PJ, Lipshultz LI. Testis biop-
  sies frequently demonstrate sperm in men with azoospermia and signifi-
  cantly elevated follicle-stimulating hormone levels. J Urol. 1997;
  157:144-6.

12.  Bohring C, Schroeder-Printzen I, Weidner W, Krause W. Serum levels 
  of inhibin B and follicle-stimulating hormone may predict successful 
  sperm retrieval in men with azoospermia who are undergoing testicular 
  sperm extraction. Fertil Steril. 2002;78:1195-8.

13.  Seo JT, Ko WJ. Predictive factors of successful testicular sperm recovery 
  in non-obstructive azoospermia patients. Int J Androl. 2001;24:306-10.

14.  Schlegel PN, Su LM. Physiological consequences of testicular sperm 
  extraction. Hum Reprod. 1997;12:1688-92.

15.  Tunc L, Kirac M, Gurocak S, et al. Can serum Inhibin B and FSH levels,
  testicular histology and volume predict the outcome of testicular sperm 
  extraction in patients with non-obstructive azoospermia? Int Urol Neph-
  rol. 2006;38:629-35.

16.  Su LM, Palermo GD, Goldstein M, Veeck LL, Rosenwaks Z, Schlegel 
  PN. Testicular sperm extraction with intracytoplasmic sperm injection 
  for nonobstructive azoospermia: testicular histology can predict success 
  of sperm retrieval. J Urol. 1999;161:112-6.

17.  Tournaye H, Liu J, Nagy PZ, et al. Correlation between testicular histol-
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18.  Ballescá JL, Balasch J, Calafell JM, et al. Serum inhibin B determination 
  is predictive of successful testicular sperm extraction in men with 
  non-obstructive azoospermia. Hum Reprod. 2000;15:1734-8.

  

CONCLUSION
Sperm retrieval, pregnancy and live child birth chances are better 

in serum FSH normal patients when compared to the serum FSH 

higher groups; however, statistical analyses showed no significant 

difference between both FSH groups concerning these three 

parameters. Even though there is a relationship between sperm 

retrieval, pregnancy and live birth rates, and hypospermatogenesis, 

there are not statistically significant differences from the other histo-

pathological diagnoses.

CONFLICT OF INTEREST
None declared.

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Histopathology    Number  Sperm Retrieved Pregnancy Rate  Live Birth

Maturation arrest    30  12  1   1
Seminiferous tubules atrophy   29  9  2   2
Sertoli cell only syndrome   40  14  3   3
Normal histology    16  14  5   3
P Values    -----  .178  .198   .063

Table 3. Classification of sperm retrieval, pregnancy and live birth rates according to the histopathological findings.

Association of FSH on microTESE Success-Yildirim et al