1 Department of Obstetrics and Gynaecology and 2 Department of Medical Genetics, University of British Columbia, 3 British Columbia's Research Institute for Children's & Women's Health and 4 British Columbia's Women's Hospital & Health Centre, Vancouver, BC, Canada
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Abstract |
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Key words: aneuploid/chromosomes/cytogenetic analysis/recurrent miscarriage/spontaneous abortion
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Introduction |
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Recurrent miscarriage, defined as three or more consecutive miscarriages, affects up to 3% of couples trying to establish a family (US Department of Health and Human Services, 1982). Risk factors for recurrent miscarriage include: loss of a euploid pregnancy, loss after the first trimester, difficulty conceiving, and delivery of a very low birthweight baby (Strobino et al., 1986
). Historically, structural genetic, endocrine, anatomic and autoimmune factors are associated with recurrent miscarriage in ~60% of cases (Hill et al., 1992
; Clifford et al., 1994
; Stephenson, 1996
). In the other 40% of cases, no association with these factors could be found. Routine cytogenetic analysis of miscarriages has remained an uncommon practice to date. This unfortunate omission has impacted on the management of couples with repeated pregnancy wastage. Not only has cytogenetic analysis of miscarriages been shown to be cost-effective in the health care system (Wolf and Horger, 1995
), but the results also help the physician to decide whether further investigations are warranted. In addition, the results are useful in the counselling of couples who are trying to understand why their pregnancy ended in miscarriage and to decide whether to try again.
The objectives of this study were to determine the frequency and distribution of cytogenetically abnormal miscarriages from couples with recurrent miscarriage and to compare the results with the general population using historical data. Our hypothesis was that euploid miscarriages should be more common in couples with recurrent miscarriage, a finding that would support an association between non-cytogenetic factors and recurrent miscarriage. In addition, the distribution of cytogenetic abnormalities in miscarriages from couples with recurrent miscarriage should be similar to the general reproductive population since these errors are thought to occur randomly, although frequency increases with advancing maternal age (Warburton et al., 1987).
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Materials and methods |
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The frequency and distribution of cytogenetically normal and abnormal miscarriages were compared with data (n = 7182) compiled from seven miscarriage surveys done in different geographic areas (Jacobs and Hassold, 1987) and selected specimens (n = 1228) from the same institution (Kalousek et al., 1993). The recurrent miscarriage data were stratified for maternal age and compared with stratified population-based data (n = 2201) (Hassold and Chiu, 1985
).
Cytogenetic analysis
Culturing of amniotic membrane and/or chorionic sac followed by routine cytogenetic analysis using Giemsa banding was used exclusively until the year 2000. Subsequently, comparative genomic hybridization (Lomax et al., 2000) was requested if the tissue failed to grow or if maternal contamination was questioned, i.e. cultured chorion revealed 46,XX.
Statistical analysis
Distributions were compared using the 2-test. In Tables II and III
, the last two cytogenetic categories (structural and other) were collapsed for statistical analysis. Yates' correction for continuity was applied for 2x2 comparisons. P < 0.05 was accepted as statistically significant.
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Results |
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The 285 patients in the data set had a total of 1281 documented miscarriages. Therefore, the median number of miscarriages per patient was four (range 312). The mean maternal age at time of pregnancy loss was 34.3 years (range 1946 years). The miscarriages were pre-clinical in 29/420 (7%), embryonic in 237/420 (56%) and fetal in 154/420 (37%).
The frequency of cytogenetic diagnoses in the recurrent miscarriage data set is summarized in Table I. In all, 225 (54%) of the specimens that had a cytogenetic diagnosis were euploid, of which 120 were female (including two balanced translocations) and 105 were male. A total of 195 (46%) of the specimens were abnormal, of which 131 (67%) were trisomic, 37 (19%) were polyploid, 18 (9%) were monosomic X and eight (4%) were unbalanced translocations, either reciprocal or Robertsonian. There was one case of combined trisomy 21 and monosomy X (46,X+21). The most frequent trisomic was 15 (22 cases), followed by trisomies 16 (19 cases), 22 (16 cases), 21 (12 cases), 14 (11 cases) and 13 (11 cases).
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In Table III, the distribution of cytogenetic categories in the recurrent miscarriage data set was first compared with the tabulated data set of seven miscarriage surveys (Jacobs and Hassold, 1987). There was a significant difference in the distribution of cytogenetic categories between the two data sets (P = 0.01), with a trend towards more trisomics (31 versus 26.8%) and less monosomy X (4 versus 8.6%) in the recurrent miscarriage group. Secondly, the recurrent miscarriage data set was compared with a selected cytogenetic data set from the same institution between 1978 and 1989, based on a reproductive history of recurrent pregnancy loss, advanced maternal age, or abnormal embryonic phenotype (Kalousek et al., 1993
). A significant difference in the distribution of cytogenetic categories between the two data sets (P = 0.0001) was seen, with a trend towards more euploid specimens (54 versus 37%) and less monosomy X (4 versus 8.2%), polyploidies (9 versus 15%) and unbalanced translocations (2 versus 6%).
The frequency of euploid specimens in the recurrent miscarriage data set, stratified for maternal age at time of pregnancy loss, was compared with a population-based data set (Hassold and Chiu, 1985), as shown in Table IV
. The Hassold and Chiu data were used for this comparison since the larger Jacobs and Hassold study did not stratify for maternal age. More euploid specimens were observed in women with recurrent miscarriage aged 1829 years (65 versus 52%, P = 0.03) and aged 3035 years (63 versus 48%, P = 0.001) than in the unselected population. There was no difference in the women aged
36 years.
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Discussion |
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Although this is a large study comparing the cytogenetic diagnoses of miscarriages in couples with recurrent miscarriage to an unselected reproductive population and a selected population from the same institution, further studies are warranted. Since comparative genomic hybridization was not introduced clinically until recently, some of the published control data may contain erroneous results due to culturing of tissue contaminated by maternal cells. In addition, this technique may also help to reduce bias caused by culture failure, which may be more common in chromosomally abnormal pregnancy tissue. With the advancement of early pregnancy monitoring, the historic distribution of cytogenetic results may differ significantly from recent results because of the inclusion, although limited, of pre-clinical loss. Collection of matched control data from the same institution will be required to confirm these observations.
The significant difference in the failure rate of conventional cytogenetic analysis, according to mode of ascertainment of specimens, is an important clinical finding which has not previously been reported. Unless comparative genomic hybridization is readily available, a D&C is advantageous over collection of spontaneously expelled tissue, if cytogenetic analysis is important for subsequent patient management.
The recent manuscript of Carp et al. reports the cytogenetic results of 125 specimens from 167 patients with unexplained recurrent miscarriage collected at curettage using conventional G-banding techniques (Carp et al., 2001). Their failure rate of 25% was significantly higher than ours of 12% overall (P = 0.0001). Carp et al. reported that 89 (71%) of the specimens were euploid, although the ratio of 46,XX and 46,XY was not included in their results. Their higher frequency of euploid miscarriages (71 versus 53%, P = 0.0005) could have been due to the subgroup of recurrent miscarriage patients studied or maternal contamination, or, most likely, the preferential culture failure of chromosomally abnormal specimens. The mean maternal age in their study was 31 years, slightly younger than in the present study, and thus would be expected to show a higher rate of euploid miscarriages.
As noted, the distribution of cytogenetically abnormal categories, stratified by maternal age at time of miscarriage, was not significantly different for the recurrent miscarriage data set and the unselected reproductive population of Hassold and Chiu (1995). Overall, the most frequent trisomic in the recurrent miscarriage group was 15, followed by 16, 22, 21, 14 and 13. In the large unselected data set of Jacobs and Hassold, trisomy 16 was the most frequent trisomic, followed by 22, 21, 15 and 13 (Jacobs and Hassold, 1987). Since the frequency of trisomics involving acrocentric chromosomes (1315, 21, 22) is known to increase more strongly with maternal age than other trisomics (Hassold and Jacobs, 1984), the difference in trisomic frequency may simply reflect a higher mean maternal age in our data set. Alternatively, there may be significant between-laboratory variation in the detection of individual trisomies (Hassold et al., 1984
). Lastly, the inclusion of cytogenetically defined pre-clinical miscarriages (demise <6 weeks gestation) in our data set could also have been responsible for the difference in trisomic frequency between the cases and controls.
The higher frequency of euploid miscarriages in women with recurrent miscarriage <36 years of age compared with the unselected reproductive population confirms that there may be other factors associated with recurrent miscarriage. This is consistent with the findings of Warburton et al. showing an increased risk for having a chromosomally normal miscarriage after one chromosomally normal miscarriage, once age of the mother was corrected for (Warburton et al., 1987). Only by excluding miscarriages with cytogenetic abnormalities will we be able to truly identify couples who have non-random recurrent miscarriage. The effect of maternal age in couples with recurrent miscarriage is significant. It is therefore even more important to determine the karyotype of losses in women aged
36 years to avoid unnecessary, costly and time-consuming investigations and treatments. In addition, the effectiveness of therapeutic interventions may be more conclusively determined if index miscarriages that are cytogenetically abnormal are excluded from analysis (Ogasawara et al., 2000
).
This study illustrates the importance of cytogenetic analyses of miscarriages in couples with a history of recurrent miscarriage. The results provide further evidence that there are non-cytogenetic factors associated with recurrent miscarriage, particularly in women under the age of 36 years. With widespread use of cytogenetic analysis by conventional G-banding and comparative genomic hybridization, when maternal contamination is questioned or with culture failure, the criteria used for evaluation of reproductive loss may change in the near future. We propose that a history of at least two euploid miscarriages, rather than the present criteria of at least three miscarriages (usually of unknown cytogenetics), would identify couples who are more likely to have a non-cytogenetic factor associated with their history of recurrent pregnancy loss. Such stringent cytogenetic criteria may also improve our ability to identify causative factors and therapeutic interventions that could be of benefit. With the storage of formalin-fixed miscarriage tissue, the clinician could selectively request comparative genomic hybridization to determine whether the couple met such criteria for evaluation. Patients and clinicians would benefit psychologically and diagnostically, as well as the health care system, from knowing which pregnancies were lost due to random meiotic errors and which couples required evaluation for non-cytogenetic factors associated with recurrent pregnancy loss.
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Acknowledgements |
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Notes |
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Submitted on June 15, 2001; resubmitted on September 10, 2001
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References |
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accepted on October 30, 2001.