Hostname: page-component-cd9895bd7-gxg78 Total loading time: 0 Render date: 2024-12-25T13:12:28.308Z Has data issue: false hasContentIssue false

Twin Database of the Secondary School Attached to the Faculty of Education of the University of Tokyo: Lifecourse Database of Twins

Published online by Cambridge University Press:  06 November 2012

Syuichi Ooki*
Affiliation:
Department of Health Science, Ishikawa Prefectural Nursing University, Japan
*
address for correspondence: Syuichi Ooki, Department of Health Science, Ishikawa Prefectural Nursing University, 1-1 Gakuendai, Kahoku, Ishikawa 929-1210, Japan. E-mail: [email protected]

Abstract

This article profiles the historical twin databases of the secondary education school attached to the Faculty of Education at the University of Tokyo. The school was established in 1948. Every year, about 50 pairs of twins of all sex and zygosity combinations and aged 11–12 years take an examination, and about 10–20 pairs are admitted based on the results. Three data sets exist: one for applicants (11–12 years), one for junior and senior high school students (12–18 years), and one for graduates (18–79 years). Record linkage of these three databases should facilitate several important research projects; for example, the lifecourse genetic epidemiologic studies and verification of so-called developmental origin of health and disease hypothesis.

Type
Articles
Copyright
Copyright © The Authors 2012

The secondary education school of the University of Tokyo is known in Japan because many twins study at the school. The school was established in 1948. When the school was established, twin studies were burgeoning in Japan. Since its establishment, the school has adopted a unique entrance system. The school gathers applications from twins in addition to applications from the general student population. About 50 pairs of twins aged 11–12 years, of all sex and zygosity combinations, and living in the Tokyo metropolitan area, take an entrance examination. From the results, about 10–20 twin pairs are admitted each year (Ooki & Asaka, Reference Ooki and Asaka2006; Ooki et al., Reference Ooki, Okazaki and Asaka2004). The school provides ongoing education for the 6 years of junior and senior high school. Of the 120 students in each grade, there are about 20–40 twins (10–20 pairs). During their 6 years of enrolment, the twins participate in observational studies for educational and related projects.

As shown in Figure 1, three data sets exist: one for school applicants (age 11–12 years), one for enrolled students (12–18 years), and one for graduates (18–79 years). Theoretically, all applicants include students, and students include graduates. Although an extraordinarily large amount of data on twin pairs exists in these databases, the same items were not necessarily gathered or obtained. Not all of the data have been exhaustively and effectively combined as yet; however, part of this database has been analyzed. All data from the retrospective perinatal and neonatal periods through childhood, school age, and adulthood are theoretically linkable using individual specific identification numbers, though in practice the linkage has only been partially completed thus far.

FIGURE 1 The relationship of the three databases.

Database of the Junior High School Applicants (1948–2012)

Applicants and their parents are the subjects of this database. Mothers of all of the twin applicants complete and return a Twins Protocol Questionnaire, the format of which has remained fairly constant especially since 1981. The questionnaire gathers information on family structure, obstetrical findings, the twins’ physical growth, zygosity and placentation, and motor and mental development from birth through 11–12 years of age. Information on socioeconomic status has recently been excluded because of privacy concerns. One parent of each applicant, usually the mother, or both parents, participates in a medical interview conducted by two or three interviewers, in which responses to the questionnaire are checked carefully. A total of 1,205 parents of applicants have returned questionnaires to date. Moreover, data from the Maternal and Child Health Handbook have been obtained since 1992. This handbook is presented by the Ministry of Health and Welfare to all pregnant women, and includes detailed obstetric records written by obstetricians and a detailed record of the child's general growth until 6 years, written by the parents at home or by medical staff at regular mass health examinations. We can use this data as a standard for questions regarding the growth and development of Japanese children. Zygosity has been determined by means of questionnaire (Ooki & Asaka, Reference Ooki and Asaka2004). All same-sexed twins and their mothers completed the zygosity questionnaire, on the basis of which twins’ zygosity was determined with greater than 95% accuracy. No subjects showed apparent growth retardation at 11–12 years of age. This data set undoubtedly represents one of the largest and most thorough sets of accurate growth data on twins in Japan (Ooki & Asaka, Reference Ooki and Asaka2005), especially since zygosity testing is very rare in Japan. The basic characteristics of the database are presented in Table 1. Growth and development features of twins in childhood were extensively analyzed for maternal and child health (Ooki, Reference Ooki2005a, Reference Ooki2006; Ooki & Yokoyama, Reference Ooki and Yokoyama2003, Reference Ooki and Yokoyama2004) and were found to not be markedly different from that of the general Japanese twin population (Kato, Reference Kato2004), at least regarding physical growth within the normal range. Several genetic studies have also been performed (Ooki, Reference Ooki2005b, Reference Ooki2005c, Reference Ooki2005d, Reference Ooki2008). The data on 1948–1980 applicants have not yet been analyzed.

TABLE 1 Basic Characteristics of the Applicants Database

aFour missing values, b14 missing values, c15 missing values. SD = standard deviation; M = male; F = female.

Database of the Junior and Senior High School Students (All Students After 1975)

Once twin applicants are admitted to the school, twins and their parents take a medical examination, which gathers detailed anthropometric and physical measurements. The blood pressure of twins and their parents is also measured. Blood specimens are taken, but these are permitted to be used only for the purposes of zygosity diagnosis and medical checks at present. These examinations, including zygosity diagnosis based on DNA/genetic markers, are performed by the twins’ medical examination committee (Ooki & Asaka, Reference Ooki and Asaka2004).

We gather predominantly longitudinal data on physical growth and development and medical conditions — for example, eyesight and allergic disease — through the results of the health examination performed each year at the Japanese School of Health Law. These results as a whole are presented as school health statistics by the Ministry of Education, Culture, Sports, Science and Technology. Information on singleton students is gathered as control data. The number of subjects is shown in Table 2. This is basically longitudinal data; students of the first grade are followed for 6 years.

TABLE 2 Numbers of Subjects According to Sex Combination and School Grade of Students

Birth year of twin pairs ranges from 1962 to 1987. First grade students are followed longitudinally. The data on 2000–2012 enrollees have not yet entered. MZM = monozygotic males; MZF = monozygotic females; DZM = dizygotic males; DZF = dizygotic females; DZOS = dizygotic opposite sex.

Adult Twin Database of High School Graduates

The information on all graduates of the school has been updated regularly. The distribution of birth year and sex-zygosity combinations of this cohort is shown in Table 3. A total of 841 pairs of twins, consisting of 673 monozygotic (MZ; 319 male–male and 354 female–female) and 168 dizygotic (DZ; 53 male–male, 54 female–female, and 61 opposite-sex), have graduated from this school through March 2012. Cumulative frequencies according to the combination of sex and zygosity are increasing almost proportionally year by year. Zygosity is diagnosed strictly by the best method available, given the year of entrance. For example, many anthropometric characteristics and blood groups were used in the early years. More recently, genetic markers and DNA polymorphisms are used (Ooki et al., Reference Ooki, Okazaki and Asaka2004).

TABLE 3 Numbers of Subjects in the Graduates Database According to Birth Year and Sex-Zygosity Combination

MZM = monozygotic males; MZF = monozygotic females; DZM = dizygotic males; DZF = dizygotic females; DZOS = dizygotic opposite sex.

Twins are followed longitudinally (Ooki et al., Reference Ooki, Okazaki and Asaka2004), and three follow-up studies have been performed (Ooki & Asaka, Reference Ooki and Asaka2006). All three surveys included questions about occupation, marital status, number of children, body weight and height, drinking habits, smoking habits, food preferences, medical history, especially for lifestyle-related diseases, and so forth. The database was reconstructed for future studies. Family data have also been collected. The fourth follow-up survey is planned any time soon.

Ethical Issues

The statistical analysis of the data was clearly written in the application document, and the detailed explanations concerning data collection by questionnaire and interview, and blood sampling for zygosity examination and health checks were added as another paper from 1999. Moreover, informed consent was obtained from each twin and his or her parents in writing from 2001 on. The data analysis was also permitted by the ethical committee of this school. Zygosity diagnosis using DNA sample was permitted through the ethical committee of the Graduate School of Medicine, University of Tokyo.

Limitations

The greatest limitation of this cohort is its selection bias based on the sampling process itself. The subjects lived in the Tokyo metropolitan area when they were enrolled at the school, and all took the entrance examination. Thus, they are not representative of Japanese children in general with regards to socioeconomic status and abilities. This selection bias would be deleterious to some study designs. Moreover, the zygosity imbalance in favor of MZ twins, in contrast to the small sample size of DZ pairs, especially in the students and graduates group, clearly differs from the MZ/DZ ratio of the twin population in Japan (Imaizumi & Nonaka, Reference Imaizumi and Nonaka1997). This difference may be as a result of the entrance process. It is, however, difficult to estimate the long-term effects of this selection bias.

Perspective

The main focus of each database is shown in Table 4. This school is no doubt one of the most important sources in the history of Japanese twins. Numerous data is in existence as a result of over 60-year-old history of the school, not all of which are organized or established as databases as yet for systematic analysis from the same platform, unfortunately. Record linkage of the present three databases would make several important research projects possible; for example, the lifecourse genetic epidemiologic study and verification of so-called fetal origin of adult disease hypothesis (Barker, Reference Barker1998), or developmental origin of health and disease hypothesis (Gluckman & Hanson, Reference Gluckman and Hanson2006). It is very difficult to perform lifetime follow-up studies, especially for twins; the existing datasets exceptionally permit this type of pioneering twin research in Japan, although the sample size and data quality are insufficient for many studies. Considering these characteristics and limitations, we need to maintain and make the most use of this historically important cohort in Japan.

TABLE 4 Summary of the Database

Acknowledgments

The author would like to thank the many collaborators of the secondary school attached to the Faculty of Education at the University of Tokyo. The author also would like to thank Prof Katsushi Tokunaga of Tokyo University, the present Director of the Twins’ Medical Examination Committee, Akio Asaka, M.D., and many other researchers who have been maintaining this historically important cohort. The author gratefully acknowledges the help of Toshimi Ooma and Yuko Sugiura regarding data management. This work was supported in part by a Grant-in-Aid for Challenging Exploratory Research (Grant Number 23659356) and Grant-in-Aid for Scientific Research (B) (Grant Number 24390167) from Japan Society for the Promotion of Science.

References

Barker, D. J. P. (1998). Mothers, babies and health in later life (2nd ed.). Edinburgh: Churchill Livingstone.Google Scholar
Gluckman, P., & Hanson, M. (Eds.) (2006). Developmental origins of health and disease. Cambridge: Cambridge University Press.10.1017/CBO9780511544699CrossRefGoogle Scholar
Imaizumi, Y., & Nonaka, K. (1997). The twinning rates by zygosity in Japan, 1975–1994. Acta Geneticae Medica et Gemellologiae, 46, 922.10.1017/S0001566000000714CrossRefGoogle Scholar
Kato, N. (2004). Reference birthweight range for multiple birth neonates in Japan. BMC Pregnancy and Childbirth, 4, 2.10.1186/1471-2393-4-2CrossRefGoogle ScholarPubMed
Ooki, S. (2005a). Language development of Japanese twins in childhood based on maternal reports. Japanese Journal of Health and Human Ecology, 71, 1224.10.3861/jshhe.71.12CrossRefGoogle Scholar
Ooki, S. (2005b). Genetic and environmental influences on stuttering and tics in Japanese twin children. Twin Research and Human Genetics, 8, 6975.10.1375/twin.8.1.69CrossRefGoogle ScholarPubMed
Ooki, S. (2005c). Genetic and environmental influences on finger-sucking and nail-biting in Japanese twin children. Twin Research and Human Genetics, 8, 320327.10.1375/twin.8.4.320CrossRefGoogle ScholarPubMed
Ooki, S. (2005d). Genetic and environmental influences on the handedness and footedness in Japanese twin children. Twin Research and Human Genetics, 8, 649656.10.1375/twin.8.6.649CrossRefGoogle ScholarPubMed
Ooki, S. (2006). Motor development of Japanese twins in childhood as reported by mothers. Environmental Health and Preventive Medicine, 11, 5564.10.1007/BF02898143CrossRefGoogle ScholarPubMed
Ooki, S. (2008). Genetic and environmental influences on sleeptalking, half-sleeping, night terrors, and nocturnal enuresis in childhood — a study of two Japanese twin samples. The Japanese Journal of Health and Human Ecology, 74, 130145.CrossRefGoogle Scholar
Ooki, S., & Asaka, A. (2004). Zygosity diagnosis in young twins by questionnaire for twins’ mothers and twins’ self-reports. Twin Research, 7, 512.10.1375/13690520460741381CrossRefGoogle ScholarPubMed
Ooki, S., & Asaka, A. (2005). Comparison of obstetric and birthweight characteristics between the two largest databases of Japanese twins measured in childhood. Twin Research and Human Genetics, 8, 6368.10.1375/twin.8.1.63CrossRefGoogle ScholarPubMed
Ooki, S., & Asaka, A. (2006). Twin database of the secondary school attached to the Faculty of Education of the University of Tokyo. Twin Research and Human Genetics, 9, 827831.10.1375/twin.9.6.827CrossRefGoogle Scholar
Ooki, S., Okazaki, Y., & Asaka, A. (2004). Characteristics of a Japanese adult twin database of high school graduates. Twin Research, 7, 430434.CrossRefGoogle ScholarPubMed
Ooki, S., & Yokoyama, Y. (2003). Reference birth weight, length, chest circumference, and head circumference by gestational age in Japanese twins. Journal of Epidemiology, 13, 333341.10.2188/jea.13.333CrossRefGoogle ScholarPubMed
Ooki, S., & Yokoyama, Y. (2004). Physical growth charts from birth to six years of age in Japanese twins. Journal of Epidemiology, 14, 151160.10.2188/jea.14.151CrossRefGoogle ScholarPubMed
Figure 0

FIGURE 1 The relationship of the three databases.

Figure 1

TABLE 1 Basic Characteristics of the Applicants Database

Figure 2

TABLE 2 Numbers of Subjects According to Sex Combination and School Grade of Students

Figure 3

TABLE 3 Numbers of Subjects in the Graduates Database According to Birth Year and Sex-Zygosity Combination

Figure 4

TABLE 4 Summary of the Database