Higher education in gerontology: A comparison of master's programs in Japan, Taiwan, and Turkey.

As of 2015, there is only one master's program of gerontology acknowledged by each of the following countries: Japan, Taiwan, and Turkey. All three programs have fewer than 15 years of history. These three countries differ in society types based on the proportion of older adults, rate of population aging, and population size. However, in terms of gerontological education, they seem to share great commonalities. Common challenges are a lack of awareness of the field of gerontology, insufficient numbers of gerontology programs and faculty members to produce trained gerontologists within society, and the inadequacy of opportunities for trained gerontologists to play an active role in various fields. This study intends not only to compare the differences and similarities among three countries and programs, but also to elucidate characteristics of a unique gerontology program in each country and identify challenges and possibilities from the perspective of gerontological educators.

Necessity to measure PCBs and organochlorine pesticide concentrations in human umbilical cords for fetal exposure assessment.

Three types of tissue samples--umbilical cord (UC), umbilical cord serum (CS), and maternal serum (MS)--have often been used to assess fetal exposure to chemicals. In order to know the relationship of contamination between mothers and fetuses, we measured persistent chemicals in comparable sets of the three tissue samples. Also, we analyzed the association between the chemicals in maternal and fetal tissues to know which tissue is the best sample for fetal exposure assessment. On a wet basis, the chemical concentrations were of the order MS > CS > UC, except for some chemicals such as cis-chlordane and endosulfan. On a lipid basis, the concentrations in UC were nearly equal or often higher than in MS, but the concentrations in CS were usually lower than in others. Hexachlorocyclohexanes and penta-, hexa-, and heptachlorinated biphenyls showed an association between the concentrations in UC versus MS, and UC versus CS. These chemicals also showed high correlation coefficients between the chemical concentrations in UC of first babies and maternal age. These chemicals were closely related to each other when grouped on the basis of their concentrations using cluster analysis. In conclusion, we insist that UC is the best sample to assess fetal contamination status of persistent chemicals. There is a possibility that the assessment based on the contamination levels in CS result in an underestimation.

Application of lung volume measurement by three-dimensional ultrasonography for clinical assessment of fetal lung development.

OBJECTIVE: To prepare nomograms for normal fetal lung volume using three-dimensional ultrasonography and to evaluate the possibility of clinical applications of this procedure. METHODS: One hundred twenty-five healthy neonates with birth weights within +/-1.5 SD (group A), 9 neonates with intrauterine growth restriction (birth weight less than -1.5 SD) but no severe respiratory disturbance at birth (group B), and 10 neonates with severe respiratory disturbance but no intrauterine growth restriction (group C) were studied. With the use of a three-dimensional ultrasonographic device, continuous B-mode images centering on the fetal thorax were acquired as volume data. Analytical software was used to repeatedly trace the contours of bilateral fetal lungs on transverse slices to calculate the lung volume. RESULTS: In group A, the total volume of normal fetal lungs can be expressed by the second-degree regression equation: 0.08 x (gestational week - 30.1)2 + 3.28 x gestational week - 67.2 (R = 0.909; P < .001). The lung volumes of groups B and C were below the 25th and 2.5th percentiles, respectively, of this regression curve. For the same case, the lung volume increased with gestational week in group B but remained unchanged or even decreased in group C. The total volume of normal fetal lungs can also be expressed by the linear regression equation: 0.02 x estimated fetal weight + 0.29 (R = 0.902). The lung volumes of groups B and C were distributed below and above, respectively, the 2.5th percentile of the regression line. CONCLUSIONS: This analytical method may be applied to evaluate lung development.