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A Mathematical Model for Recurrent Twinning

Published online by Cambridge University Press:  01 August 2014

J.O. Fellman*
Affiliation:
Folkhälsan Institute of Genetics, Population Genetics Unit, Helsinki, Finland
A.W. Eriksson
Affiliation:
Institute of Human Genetics, Free University of Amsterdam, The Netherlands
*
Swedish School of Economics, Arkadiagatan 22, SF-00100 Helsinki 10, Finland

Abstract

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In an attempt to improve our understanding of the factors that affect human twinning, we further developed the models given by Hellin (1895) and Peller (1946). The connection between these models and our own model (“Fellman's law”) were studied. These attempts have resulted in a more general model, which was then applied to data from Åland Islands (1750-1939), Nîmes (1790-1875), Stuttgart (about 1790-1900) and Utah (1850-1900). The product of the mean sibship size and the total twinning rate can be considered as a crude estimate of the expected number of sets of twins in a sibship. The same can be said about the twinning parameter in our model. These estimates are in good agreement. If we consider twinning data only, we obtain the geometric distribution, and log (Nk), where Nk is the number of mothers with k twin maternities, is a linear function of the number of recurrences. Graphically, this property can easily be checked. For sibships containing three or more sets of twins, all four populations show higher values than expected, particularly the populations from Stuttgart and Utah, which data also show poor agreement according to a χ2-test. A more exact model would demand more detailed demographic information, such as distribution of sibship sizes, age-specific twinning rates and temporal variations in twinning.

The osberved number of mothers in Åland with several recurrences of multiple maternities shows a considerable excess over the expected number as predicted by Peller's rule. The parameters in our model can be estimated by the maximum likelihood method and the obtained model fits the data better then Peller's model.

Type
Research Article
Copyright
Copyright © The International Society for Twin Studies 1990

References

REFERENCES

1.Bulmer, MG (1970): The Biology of Twinning in Man. Oxford: Clarendon Press.Google Scholar
2.Cannelli, D, Hasstedt, S, Anderson, S (1981): Demography and genetics of human twinning in the Utah Mormon genealogy. In Gedda, L, Parisi, P, Nance, WE (eds): Twin Research 3. Part A: Twin Biology and Multiple Pregnancy. New York: Alan R Liss, pp 8193.Google Scholar
3.Eriksson, AW (1973): Human twinning in and around the Åland Islands. Comment Biol 64: 1159.Google Scholar
4.Eriksson, AW, Fellman, J, Forsius, H (1973): The value of genealogical data in population studies in Sweden and Finland. In Morton, NE (ed): Genetic Structure of Populations. Honolulu: Univ of Hawaii Press, pp 102118.Google Scholar
5.Hellin, D (1895): Die Ursache der Multiparität der uniparen Tiere überhaupt und der Zwillingsschwangerschaft beim Menschen insbesondere. München: Seitz & Schauer, p 70.Google Scholar
6.Peller, S (1946): A new rule for predicting the occurrence of multiple births. Amer J Phys Anthropol 4:99105.CrossRefGoogle ScholarPubMed
7.Puech, A (1877): De la répétition des accouchements multiples. Ann Gynecol Obstet 2:264282.Google Scholar
8.Weinberg, W (1901): Beiträge zur Physiologie und Pathologie der Mehrlingsgeburten beim Menschen. Arch Ges Physiol 88:346430.CrossRefGoogle Scholar