This Article Abstract Full Text (PDF) All Versions of this Article: 28/4/600    most recent Author Manuscript (PDF) Alert me when this article is cited Alert me if a correction is posted Services Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via Google Scholar Google Scholar Articles by Achard, V. Articles by Guichaoua, M. R. Search for Related Content PubMed PubMed Citation Articles by Achard, V. Articles by Guichaoua, M. R.

Reproductive Failure in Patients With Various Percentages of Macronuclear Spermatozoa: High Level of Aneuploid and Polyploid Spermatozoa

Correspondence to: M R Guichaoua, Laboratoire de Biologie de la Reproduction, Hôpital de la Conception, 147 Bd Baille 13005 Marseilles, France (e-mail: mguichaoua{at}ap-hm.fr).

Received for publication October 3, 2006; accepted for publication March 21, 2007.

	Abstract

Top Abstract Materials and Methods Results Discussion References

 
The aim of this study was to describe the association between various percentages of macronuclear spermatozoa (MNSs), sperm chromosomal abnormalities, and reproductive failure in 4 patients. One patient had a familial history of perinatal deaths. Patients were selected according to the coexistence of normal-sized spermatozoa and MNSs (19%, 22%, 29.5%, and 49.7%). Fluorescent in situ hybridization (FISH) on spermatozoa and semiautomated analysis of nuclear surface were assessed. All patients were characterized by an oligoasthenozoospermia. Three patients had a prevalence of irregular MNSs and prevalence of nondisjunction at the first meiotic division. One patient had a prevalence of regular MNSs and a prevalence of nondisjunction at the second meiotic division. FISH also showed a high rate of polyploidy and various rates of aneuploid sperm. The percentage of sperm with abnormal chromosome complements (25.6%, 43.6%, 51.4%, 71.7% with 3-color FISH) was higher than the percentage of MNSs. A population of apparently normal-sized spermatozoa that could be used for intracytoplasmic sperm injection (ICSI) was aneuploid. Sperm nuclear surface analysis revealed either a shift toward elevated values or distinguished 2 sperm subpopulations: normal and macronuclear. Patients underwent 7 ICSI cycles. The fertilization rate was low for 3 patients (50%, 40%, 50%) and normal for 1 patient (83.3%). Pregnancy rate per transfer was low (14.3%). The present study shows that the macronuclear phenotype can manifest a variety of clinical aspects. It is also shown that mild rates of MNSs impair fertility and constitute a risk of chromosomal abnormality for the embryos and a risk of perinatal death. We suggest conducting FISH on spermatozoa and genetic counseling for a couple when the percentage of MNSs reaches 20% in at least 1 spermiogram.

     Key words: Chromosomal abnormalities, meiosis, FISH, nuclear surface

Aside from patients exhibiting 100% MNSs, infertile patients exhibiting both large-headed spermatozoa (32% to 64%) and various nuclear sizes have been reported (Yurov et al, 1996). In all cases, total teratozoospermia was always detected. Until now, patients with mild percentages of MNSs have been poorly explored. Viville et al (2000) and Vicari et al (2003) reported that the presence of MNSs is associated with an increased incidence of chromosomal abnormalities. Here, we report a detailed semen analysis of 4 infertile human males undergoing an ICSI program and showing various percentages of sperm abnormality. One of them had a predominance of regular large-headed spermatozoa and a family history of reproductive failure. The spermatozoa of all patients were investigated by FISH and semiautomated analysis of nuclear surface. ICSI was performed with selected normal-sized and typical spermatozoa.

	Materials and Methods

Top Abstract Materials and Methods Results Discussion References

 
Patients

Study participants were selected from 5556 patients who presented to our reproductive center with issues of infertility between November 1993 and July 2003. A total of 7292 spermiograms were obtained from these 5556 patients, and the mean percentage of MNSs per spermiogram was determined to be 1.26. Of the 5556 patients, 15 (2.7/1000) displayed 20% or more MNSs in the first spermiogram. In a first group of 3 patients (0.5/1000), 100% of spermatozoa presented with an MNS phenotype. More frequently (12 patients, 2.15/1000), various percentages of MNSs were found (20% to 62%). Four of these patients agreed to undergo cytogenetic analysis of spermatozoa by FISH. At that time, new semen analysis and the percentage of MNSs were reevaluated. The patients were included in this study if the second spermiogram confirmed the presence of MNSs even if the percentage was less than 20%, which is the case for patients 5 and 11, who had 19% and 17% MNSs in the second analysis, respectively. Unlike In't Veld et al (1997), we were unable to observe large variations in the percentage of MNSs.

Patients 4, 5, 6, and 11 were 27, 36, 36, and 37 years old, respectively. In all cases, the men presented with problems of infertility (Table 1). No direct consanguinity was observed between the relatives of the men. Analysis of the pedigree of patient 11 showed that 5 siblings died during the first days of life from unknown causes. Interestingly, a brother of the patient also suffered from primary infertility but refused to submit to semen analysis. Three patients (patients 4, 5, 6) had a normal karyotype. For patient 11, 50 mitoses were analysed, 2 had the karyotype 47,XY,+21, 1 mitosis was 47,XXY, and 1 mitosis was 45,X. Complementary study of 20 mitosis showed chromosomal loss on 4 mitoses (10-, 15-, 18-, 21-). Interphase FISH with specific probes for chromosomes X, 8, 13, 18, and 21 showed that 5% of the nuclei presented with either a monosomy for chromosome 18 or a trisomy for chromosome 21. This percentage was considered nonsignificantly increased by cytogeneticists, and a constitutional mosaic was eliminated.

All women had normal menstrual cycles, hysterosalpingography, and hormonal assessment. The women's ages were 24, 37, 38, and 35 for patients 4, 5, 6, and 11, respectively.

Semen Analysis

Sperm concentration and motility were evaluated according to the World Health Organization guidelines (1999). One hundred spermatozoa were evaluated for each patient according to strict criteria described by Kruger et al (1986).

Semiautomated Analysis of Sperm Nuclear Surface and its Statistical Treatment

Analysis of sperm nuclear surface was performed for the patients, 3 healthy controls, and a control patient with 100% MNSs (control 100%). Healthy controls were selected among fertile men showing normal spermiograms. Papanicoloaou-stained sperm were analysed using a Zeiss Axioplan microscope (63x magnification; Zeiss, Oberkocher, Germany). Images were digitized with a Sony 3CCD XC077 camera (Sony, Tokyo, Japan) and analyzed with the IPS 32 software (Samba Technologies, Grenoble, France). A specific macro was designed: a constant greytone threshold distinguished sperm heads from background, and the operator controlled the limit between head base and flagellum. The nuclear surface was automatically calculated in µm². Measures were analyzed with an analytical software (STAT 2005; Samba) to fit the maximum amount of measurements in a normal distribution. Results for this operation are given as mean, SD, and percentage of measures that fit in the model.

FISH on Sperm

Written informed consents were obtained for each patient before analysis. Cryopreserved semen samples from the patients were thawed and washed twice in 0.01 mol/L Tris, pH 8, for 10 minutes at 600 x g. The in vitro decondensation procedure was performed as previously described (Yurov et al, 1996). In brief, the sperm preparations were treated with 2N NaOH for 2 minutes at room temperature to induce sperm nuclear decondensation.

Three-color and dual-color FISH experiments were performed using Qbiogen classical satellite probe (Qbiogen, Illkirch, France). Three-color FISH experiments were performed with specific probes for chromosomes 9, X, and Y (Chromosome X Alpha Satellite DXZ1 Probe/Red, Chromosome Y Classical Satellite DYZ1 Probe/Green, Chromosome 9 Classical Satellite Probe/Green and Red; Abbott Molecular Inc, Des Plaines, Ill). Dual-color FISH experiments were performed with specific probes for chromosomes 8 and 18 (Chromosome 8 Alpha Satellite D8Z2 Probe/Green, Chromosome 18 Alpha Satellite D18Z1 Probe/Red; Abbott). FISH was performed according to the protocol recommended by the manufacturer. Preparations were counterstained with 4,6-diamino-2-phenylindole (DAPI). Slides were screened using a 100x objective on a Zeiss Axioskop microscope equipped with a fluorescein isothiocyanate (FITC)/rhodamine/DAPI triple band-pass filter. Signals of a specific color were considered multiple only when separated by at least 1 signal diameter. The efficiency of hybridization was evaluated from the DAPI-stained spermatozoa without FISH signals.

View larger version (88K): [in this window] [in a new window]   Figure 1. Light microscopic analysis of macronuclear spermatozoa (MNSs) after Papanicolaou staining. (A) Irregularly shaped MNSs with multiple flagella. (B) Regular macronuclear spermatozoa (arrow).

Statistical Analysis

     Sperm Head Surface Analysis— To determine whether multiple sperm subpopulations (according to nuclear size) coexisted within an ejaculate, a maximum threshold of 20 µm² was applied and the remaining population was tested for normal distribution by Shapiro-Wilk W, Anderson-Darling, Martinez-Iglewicz, and Kolmogorov-Smirnov tests. Whenever the remaining population showed a normal distribution, the existence of 2 sperm populations was assumed.

     FISH on Spermatozoa— To compare the difference between sex chromosome and autosome nondisjunction, a ² test was used.

	Results

Top Abstract Materials and Methods Results Discussion References

 
Sperm Analysis

Oligoasthenozoospermia is a general feature of these patients (Table 1). The viability of spermatozoa was normal (more than 50%) for patients 4, 5, and 6. A low viability was found for 2 ejaculates (15% and 6%) of patient 11. Regular analysis of sperm morphology after Papanicolaou staining showed that the mean percentages of MNSs varied from 19% to 49.7%. Two patients (patients 4 and 5) had a normal mean percentage of typical forms whereas it was low for patients 6 and 11. Considering MNSs alone, patients 4, 5, and 6 presented with a prevalence of irregular nuclear shapes (86%, 67%, and 76%) whereas patient 11 presented with a prevalence of regular nuclear shapes (52%) (Figure 1A and B).

Sperm Head Surfaces Analysis

Characteristics of measured spermatozoal surfaces for each control/patient are presented in Table 2. Means of healthy controls (1, 2, and 3) were 13.5, 11.9, and 13.4 µm² with low dispersion (ie, SDs were 2.8, 1.9, and 1.9 µm², respectively). Measurements for control 100% had an elevated mean (30.4 µm²) and a widely spread distribution (SD, 9.8 µm²). We observed that the distributions of the measured surfaces for the 4 patients had overall characteristics that were intermediate between those of normal and 100% macronuclear controls. The means were 16, 18.4, 18.7, and 11.8 µm² for patients 4, 5, 6, and 11, respectively, with SDs of 5.9, 6.1, 6.3, and 4.2 µm². The observation of the frequency histograms for each surface (Figure 2) shows a shift toward elevated values for patients 5 and 11 but not for healthy controls. Indeed, the percentages of spermatozoa whose surfaces were higher than 20 µm² represented only 2.7% (10/366), 0.5% (2/416), and 0% (0/277) of the total for controls 1, 2, and 3 whereas they accounted for 20% (44/220), 32.2% (55/171), 35.2% (38/108), and 4.4% (42/946) in patients 4, 5, 6, and 11, respectively. The presence of a subpopulation of MNSs for 2 patients was assessed in the following manner. Measures for controls showed a normal distribution whereas measures for the patients did not (the normality tests used are listed in "Material and Methods"). However, after suppressing values above 20 µm², the remaining populations showed normal distribution for patients 4 and 5, with means of 13.7 ± 3 µm² and 15 ± 2.5 µm.² This was not observed in patients 6 and 11 because of the low number of measures above the threshold. Therefore, we concluded that, for patients 4 and 5, 2 populations of spermatozoa coexisted (normal and oversized).

View larger version (27K): [in this window] [in a new window]   Figure 2. Semiautomated analysis of sperm nuclear surfaces by optical microscopy (µm2) for a control patient, a patient showing 100% macrocephalic sperm (control 100%), and patients 5 and 11 (n = 366, 216, 171, and 946 sperm, respectively). Histograms show the distribution in percentages. For each population, the STAT 2005 software fitted a maximum of cases within normally distributed populations. All of the cases were fitted for control (mean, 13.5 ± 2.8 µm2) and control 100% (mean, 30.4 ± 9.8 µm2). Two subpopulations were observed for patients 5 and 11.

FISH on Sperm

The mean efficiency of hybridization was 99.2% (range, 96.4% to 100%). The percentage of chromosomal abnormalities was first evaluated on all spermatozoa despite their size and then on apparently normal-sized spermatozoa (nonmacronuclear). Totals of 1430, 2811, 1955, and 3981 sperm nuclei were scored from patients 4, 5, 6, and 11, respectively.

     Three-Color FISH— High percentages of chromosomal abnormalities were found in the 4 patients (51.4%, 43.6%, 71.7%, and 25.6% in patients 4, 5, 6, and 11, respectively) (Table 3). These values are greater than the percentages observed in 3 controls (total abnormalities, 0.9%, 0.3%, and 0.5%, respectively). A great heterogeneity in the distribution of the chromosomes was found in the 4 patients. Nevertheless, diploidy was the prevalent abnormality in patient 11 (64.5% of the chromosomal abnormalities vs 33.2%, 23.6%, and 25.3%, for patients 4, 5, and 6, respectively) whereas complex aneuploidies prevailed in other patients.

Various types of diploidies were present with respect to the sex chromosomes (ie, either 99XY, 99XX, or 99YY). Nevertheless, for patients 4, 5, and 6, nondisjunction at the first meiotic division (99XY) (12.4%, 7.3%, and 14.1% for patients 4, 5, and 6, respectively) prevailed over nondisjunction at the second meiotic division (99XX or 99YY) (4.7%, 2.9%, and 4.0% for patients 4, 5, and 6, respectively). Concerning patient 11, nondisjunction was prevalent at the second meiotic division (9.9% vs 6.6% of nondisjunction at the first meiotic division).

In the 4 patients, the total percentage of chromosome abnormalities with probes specific for chromosomes X,Y and 9 was higher than the mean percentage of MNSs (Tables 1 and 4): 51.4% vs 29.5%, 43.6% vs 22%, 71.7% vs 49.7%, and 25.6% vs 19% for patients 4, 5, 6, and 11, respectively. The mean percentage of aneuploid normal-sized spermatozoa in patients was significantly higher than those observed in the controls (3.5% vs 0.5%, P < .001); patient 11 had particularly few aneuploid normal-sized spermatozoa (1.1% in patient 11 vs 12.3%, 4.5%, and 3.7% in patients 4, 5, and 6, respectively).

     Dual-color FISH— High percentages of chromosomal abnormalities were found (54.5%, 37.6%, 61.8%, and 11.1% for patients 4, 5, 6, and 11, respectively) (Table 4). These values were greater than the percentages observed in the 3 controls (0.7%, 0.5%, and 0.8%, respectively). As with 3-color FISH, few spermatozoa had more than 46 chromosomes in patient 11 compared with the 3 others. The mean rate of aneuploid normal-sized spermatozoa was significantly higher than those observed in the controls (2.8% vs 0.7%, P < .001); this rate is normal in patient 11 (0.4% vs 5.3%, 3.1%, and 2.4% in patients 4, 5, and 6, respectively).

ICSI Cycles

Seven ICSIs were performed for these 4 patients. Thirty-two metaphase II oocytes were retrieved and injected, and 21 diploid zygotes were obtained. The mean fertilization rate (diploid zygotes/metaphase II oocytes) was not different from the normal values obtained in our laboratory (65.6% vs 36%). Notably, however, this rate was lower for patients 4, 5, and 6 (50%, 40%, and 50%, respectively) than for patient 11 (83.3%). The cleavage and transfer rates (diploid embryos/diploid zygotes) were 90.5% (19/21) and 100% (7/7), respectively. The mean number of transferred embryos per transfer was not different from usual values of our laboratory (1.7 [12/7] vs 1.8). One clinical pregnancy was obtained for patient 4, leading to the delivery of a healthy girl. The clinical pregnancy rate per transfer was lower (14.3%) compared with the mean rate of our center (30%). Nevertheless, the number of patients is too limited for a statistical analysis.

	Discussion

Top Abstract Materials and Methods Results Discussion References

 
MNSs were rarely observed in fertile patients with normal sperm parameters (0.9% [Bujan et al, 1988] and 1.6% [Schwartz et al, 1984]) and in infertile patients (1.26% [our personal data]). Inversely, a high level (ie, about 100%) of irregular and multitailed MNSs is associated with severe male infertility. It appears that the macronuclear phenotype can manifest a variety of clinical aspects. Indeed, Escalier (2002) has already described 3 types of this syndrome, and a new type with perinatal death was described by Benzacken et al (2001). Then, patients with frequencies of 64% and 54% of MNSs and total teratozoospermia were reported by Viville et al (2000) and Vicari et al (2003) whereas Yurov et al (1996) described a patient with 40% spermatozoa displaying MNSs, all of which were of the regular form. A new situation appears in the present study in which 4 patients had mild mean percentage of MNSs (19%, 22%, 29.5%, and 49.7%) (Table 1) associated with typical spermatozoa. Three of these patients had a predominance of irregular MNSs whereas patient 11 showed a predominance of regular forms (52%), which is a rare phenotype only previously described by Yurov et al (1996). This patient, whose familial history revealed that 5 siblings died during the perinatal period, was also distinct in that FISH showed a different profile of sperm chromosomal abnormalities (see "Results") and a prevalence of nondisjunction during the second meiotic division (Table 3). This last characteristic was never described until now and could be correlated with the perinatal deaths in the proband's sibling. Indeed, whereas the first division is specific to meiosis, the mechanisms used in meiotic division II are similar to those used in normal mitosis. Thus, the factor involved in both spermatogenic defect and perinatal deaths in the case of patient 11 could be a cell cycle–regulating factor expressed both in somatic cells and in division II meiotic cells. Nevertheless, it is too early to say if preferential involvement of the second meiotic division in the MNSs predisposes the embryos to subsequent perinatal deaths. It is still also too early to propose a preferential relationship between a particular sperm phenotype and a clinical phenotype.

FISH on sperm also revealed in all patients high frequencies of chromosomal abnormalities (Tables 3 and 4) compared with the frequencies of MNSs (Table 1), suggesting that apparently normal-sized spermatozoa presented aneuploidy. Indeed, evaluation of the aneuploidy rate of apparently normal-sized spermatozoa (see "Results") showed that these spermatozoa, which could be used for ICSI, have significantly higher abnormal karyotype than controls but with interindividual variations, leading to a high risk of chromosomally abnormal embryos. We compared the results of FISH with semiautomated analysis of the sperm nuclear surface. This last approach enabled the visualization of an increase of the mean nuclear sperm surface for patients 4, 5, and 6 and above all in the SD of the 4 patients with either a spreading of the histogram toward the great value (patients 6 and 11) or a second subpopulation of oversized spermatozoa (patients 4 and 5) (Figure 2). This method also shows the existence of various sizes of spermatozoa from the apparently normal-sized to fourfold increased nuclear spermatozoa (Figure 2). Consequently, several spermatozoa with moderate size increase may be classified as normal sized during the assessment of sperm morphology by light microscopy analysis or during the selection of spermatozoa for ICSI.

The present study points out that mild rates of MNSs significantly impair fertility and constitute a risk for embryos. Nevertheless, ICSI was performed on selected typical spermatozoa in the 4 patients. Although the mean fertilization rate was normal in comparison with the normal values of our center (65.6% vs 63%), only patient 11 had a normal fertilization rate (83.3%). The other 3 patients displayed relatively low fertilization rates (50%, 40%, and 50%, for patients 4, 5, and 6, respectively). This discrepancy could be related to the low rate of chromosomal abnormalities in the apparently normal-sized spermatozoa in patient 11 (1.1% and 0.4% with 3-color and dual-color FISH, respectively). Moreover, in this limited experience with mild levels of MNSs, the implantation and ongoing pregnancy rates were low (14.3%). Only 1 pregnancy was obtained, in the couple in which the wife was the youngest (24 years old versus 35, 36, and 37 years old) (Table 1). Further studies will be necessary to confirm the low fertilization rate in these couples.

In conclusion, this study emphasizes that mild phenotypes of MNSs reduce the fertility and may have consequences on the embryos. Low fertilization and pregnancy rates may be due to the high incidence of aneuploidy in the apparently normal-sized spermatozoa that may be used for ICSI (patients 4, 5 and 6). Yet, chromosomal imbalance in the embryos could directly result from the gene mutation (patient 11). Indeed, a mutation in a gene that plays a role in the function and regulation of both mitotic and meiotic cycles could lead to the failure of chromosomal segregation in an embryo that initially has a normal karyotype, leading to embryo developmental arrest or perinatal death. Although the factor involved in this syndrome is unknown, we suggest conducting FISH on spermatozoa and genetic counseling before ICSI for infertile couples when the percentage of MNSs reaches 20% in at least 1 spermiogram. The monitoring of possible pregnancies is difficult to define. We think that several ultrasound examinations must be recommended in case of ongoing pregnancy, whereas PGD is arguable. Indeed, Kahraman et al (1999, 2004) reported a possible beneficial effect of eliminating chromosomal abnormal embryos with PGD on abortion rates in patients with high percentages of MNSs whereas the success of PGD has yet to be proven in aneuploidy screening (Shahine and Cedars, 2006).

	Acknowledgments

 
We are grateful to Pr J. M. Grillo, Director of the In Vitro Fertilization Center, and D. Escalier for scientific guidance. We thank C. Missirian for karyotype analysis; C. Allasia for his help on analysis of nuclear surfaces; M. J. Fays-Bernardin, D. Chapelle, C. Metton, and D. Daïoglou for their technical assistance; and Missirian C. for cytogenetic analysis of somatic cells. Help for writing in English was provided by the Journal Experts Company, San Francisco, Calif.

	Footnotes

 
This work was supported by grants from the Société d'Andrologie de Langue Française (SALF).

	References

Top Abstract Materials and Methods Results Discussion References

 
Benzacken B, Gavelle FM, Martin-Pont B, Dupuy O, Lievre N, Hugues JN, Wolf JP. Familial sperm polyploidy induced by genetic spermatogenesis failure: case report. Hum Reprod. 2001; 16: 2646 –2651.[Abstract/Free Full Text]

Bujan L, Mieusset R, Mondinat C, Mansat A, Pontonnier F. Sperm morphology in fertile men and its age related variation. Andrologia. 1988; 20: 121 –128.[Medline]

Devillard F, Metzler-Guillemain C, Pelletier R, DeRobertis C, Bergues U, Hennebicq S, Guichaoua M, Sele B, Rousseaux S. Polyploidy in large-headed sperm: FISH study of three cases. Hum Reprod. 2002;17: 1292 –1298.[Abstract/Free Full Text]

Escalier D. Genetic approach to male meiotic division deficiency: the human macronuclear spermatozoa. Mol Hum Reprod. 2002; 8: 1 –7.[Abstract/Free Full Text]

Escalier D. Human spermatozoa with large heads and multiple flagella: a quantitative ultrastructural study of 6 cases. Biol Cell. 1983;48: 65 –74.[Medline]

In't Veld PA, Broekmans FJ, de France HF, Pearson PL, Pieters MH, van Kooij RJ. Intracytoplasmic sperm injection (ICSI) and chromosomally abnormal spermatozoa. Hum Reprod. 1997; 12: 752 –754.[Abstract/Free Full Text]

Kahraman S, Akarsu C, Cengiz G, Dirican K, Sozen E, Can B, Guven C, Vanderzwalmen P. Fertility of ejaculated and testicular megalohead spermatozoa with intracytoplasmic sperm injection. Hum Reprod. 1999; 14: 726 –730.[Abstract/Free Full Text]

Kahraman S, Sertyel S, Findikli N, Kumtepe Y, Oncu N, Melil S, Unal S, Yelke H, Vanderzwalmen P. Effect of PGD on implantation and ongoing pregnancy rates in cases with predominantly macrocephalic spermatozoa. Reprod Biomed Online. 2004; 9: 79 –85.[Medline]

Kruger TF, Menkveld R, Stander FS, Lombard CJ, Van der Merwe JP, van Zyl JA, Smith K. Sperm morphologic features as a prognostic factor in in vitro fertilization. Fertil Steril. 1986; 46: 1118 –1123.[Medline]

Lewis-Jones I, Aziz N, Seshadri S, Douglas A, Howard P. Sperm chromosomal abnormalities are linked to sperm morphologic deformities. Fertil Steril. 2003; 79: 212 –215.[CrossRef][Medline]

Nistal M, Paniagua R, Herruzo A. Multi-tailed spermatozoa in a case with asthenospermia and teratospermia. Virchows Arch B Cell Pathol. 1977;26: 111 –118.[Medline]

Pieters MH, Speed RM, de Boer P, Vreeburg JT, Dohle G, In't Veld PA. Evidence of disturbed meiosis in a man referred for intracytoplasmic sperm injection. Lancet. 1998; 351: 957 .[Medline]

Porcu G, Mercier G, Boyer P, Achard V, Banet J, Vasserot M, Melone C, Saias-Magnan J, D'Ercole C, Chau C, Guichaoua MR. Pregnancies after ICSI using sperm with abnormal head-tail junction from two brothers: case report. Hum Reprod. 2003; 18: 562 –567.[Abstract/Free Full Text]

Schwartz D, Mayaux MJ, Guihard-Moscato ML, Spira A, Jouannet P, Czyglik F, David G. Study of sperm morphologic characteristics in a group of 833 fertile men. Andrologia. 1984; 16: 423 –428.[Medline]

Shahine LK, Cedars MI. Preimplantation genetic diagnosis does not increase pregnancy rates in patients at risk for aneuploidy. Fertil Steril. 2006;85: 51 –56.[CrossRef][Medline]

Vicari E, de Palma A, Burrello N, Longo G, Grazioso C, Barone N, Zahi M, D'Agata R, Calogero AE. Absolute polymorphic teratozoospermia in patients with oligo-asthenozoospermia is associated with an elevated sperm aneuploidy rate. J Androl. 2003; 24: 598 –603.[Abstract/Free Full Text]

Viville S, Mollard R, Bach ML, Falquet C, Gerlinger P, Warter S. Do morphological anomalies reflect chromosomal aneuploidies?: case report. Hum Reprod. 2000; 15: 2563 –2566.[Abstract/Free Full Text]

World Health Organization. WHO Laboratory Manual for the Examination of Human Semen and Sperm-Cervical Mucus Interaction. 4th ed. Cambridge, United Kingdom: Cambridge University Press; 1999 .

Yakin K, Kahraman S. Certain forms of morphological anomalies of spermatozoa may reflect chromosomal aneuploidies. Hum Reprod. 2001;16: 1779 –1780.[Free Full Text]

Yurov YB, Saias MJ, Vorsanova SG, Erny R, Soloviev IV, Sharonin VO, Guichaoua MR, Luciani JM. Rapid chromosomal analysis of germ-line cells by FISH: an investigation of an infertile male with large-headed spermatozoa. Mol Hum Reprod. 1996; 2: 665 –668.[Abstract/Free Full Text]

This Article Abstract Full Text (PDF) All Versions of this Article: 28/4/600    most recent Author Manuscript (PDF) Alert me when this article is cited Alert me if a correction is posted Services Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via Google Scholar Google Scholar Articles by Achard, V. Articles by Guichaoua, M. R. Search for Related Content PubMed PubMed Citation Articles by Achard, V. Articles by Guichaoua, M. R.