On the skeletal maturation of Japanese-American White hybrids.

The skeletal maturation of Japanese-American White hybrids is discussed in relation to that of Japanese and Whites. Assessment of skeletal maturation was made on 323 radiographs of 57 boys and 151 of 33 girls studied semi-longitudinally from 3 to 18 years on the basis of the Tanner-Whitehouse method (62). The skeletal maturity scores show a tendency for a greater advance in childhood for the Whites than for the hybrids and the Japanese. However, the preadolescent spurt of skeletal maturity occurs earlier in the Japanese and the hybrids than in the Whites, and the hybrids show the intermediate skeletal maturity scores between those of the Japanese and the Whites at and after adolescence.     

A comparative study of neonatal skeletal development in Cebus and other primates

Comparisons of hand/wrist radiographs of neonatal Cebus albifrons (n = 14) and Cebus apella (n = 4) with those of Saimiri sciureus boliviensis (n = 9) and Macaca mulatta (n = 63) reveal that the cebid monkeys show much less skeletal ossification at birth than macaques. Differences in gestation time alone cannot account for the differences in skeletal maturity at birth in the two groups of monkeys. The skeletal precocity of the newborn macaques indicates that their ossification either begins earlier in gestation or proceeds at a more rapid rate, or both. This, in turn, raises questions about the timing of organogenesis and gestational comparability in cebid and cercopithecid monkeys. The advanced state of ossification seen in macaques at birth is not typical of other groups of anthropoid primates, including Cebus, Saimiri, Pan and Homo, and may represent an ontogenetic specialization.     

Ethnic and secular influences on the size and maturity of seven year old children living in Guatemala City

Three groups of children, those of European parentage, those of Guatemalan parentage, and those of mixed European-Guatemalan parentage were measured for height, weight, and skeletal maturity. The children were born between 1945 and 1965, they were all of high socioeconomic status, and they all attended the same private school in Guatemala City. At 7 years, the boys of the European group were significantly taller than boys of the Guatemalan group. European and mixed European-Guatemalan girls were significantly taller than Guatemalan girls. These results are maturity independent. The influence of skeletal age was removed statistically by analysis of covariance. Girls of the mixed group were significantly heavier than girls of European and Guatemalan groups. Mixed group girls also had more significantly advanced skeletal ages than European girls. When the patterns of size and maturity status are analyzed by sex, there is evidence for a relatively greater environmental influence on the boys and a relatively greater genetic influence on the girls. Dividing the data into two birth year cohorts, 1945 to 1955, and 1956 to 1965, does not provide evidence for secular trends in growth or maturation. These results are similar to those from studies in developed nations that report an end to the secular trend for the “well off” population of those countries.     

Fatness and skeletal maturity of Belgian boys 12 through 17 years of age

Relationships between fatness and skeletal maturity are considered in a nationwide sample of 14,259 Belgian boys 12 through 17 years of age (The Leuven Growth Study of Belgian Boys). Absolute fatness was estimated from four skinfolds using the Drinkwater and Ross technique and from the sum of four skinfolds, and was related to skeletal maturity assessed by the Tanner-Whitehouse method (I and II). In addition, comparisons were made between the fattest 5% and leanest 5% of the boys at each age level. Correlations between the indices of fatness and skeletal age and relative skeletal age (the difference between skeletal and chronological ages) are positive and generally low, ranging from 0.12 to 0.39. They tend to decrease with age from 12 to 17 years. Comparisons between the extreme groups indicate that the leanest boys are more delayed in skeletal maturity, by about 0.8 years, than the fattest boys are advanced, by about 0.5 years. Stature data for the same boys are consistent with the skeletal maturity data and thus suggest that the size differences between the extreme groups are due in part to maturity differences. Over the age span 12 through 20 years, the leanest boys are reduced in stature by about – 1.2 standard deviations, while the fattest boys are larger in stature by about +0.6 standard deviation units. The size differences, however, persist after skeletal maturity is attained so that there may be a specific role for fatness in influencing statural growth.     

Skeletal maturity of Japanese children in Western Kyushu

This paper describes the skeletal maturity status of Japanese children in Western Kyushu and its variation within Japanese populations. Hand-wrist skeletal maturity was assessed by the Tanner-Whitehouse (1975) (TW2) method from radiographs of 500 boys and 485 girls aged from 4 to 15 years. Western Kyushu children showed retarded skeletal maturity scores (RUS, carpals, and 20-bone) under the age of 12 years for boys and 10 years for girls, and thereafter they were advanced in relation to the British standard. Within Japanese populations the present sample showed delayed maturity compared to Tokyo children, but was close to that of Sapporo children throughout the age range studied. However, the expected effect of secular trend suggested skeletal maturity more advanced for Tokyo children and somewhat advanced one for Sapporo children compared to that of Western Kyushu children.     

Timing and genetic rapport between growth in skeletal maturity and height around puberty: similarities and differences between girls and boys.

We have analyzed longitudinal twin data by using a multivariate normal model to identify and quantify genetic effects over time on two main aspects of growth, height and skeletal maturity. The largest genetic contribution to the variance in both height and skeletal maturity coincided with the respective ages of peak growth velocity. The highest genetic covariance between these two traits coincided with the age of greatest acceleration of growth in height. These findings imply the existence of regulatory or structural genes that influence growth in both height and skeletal maturity. We also found sex differences in the rapport between velocities for height and skeletal maturity. These are consistent with a predominant role of estrogen in accelerating skeletal maturation in females, and the existence of additional mechanisms in males which may promote growth in height independently of the effects of gonadal sex steroids.     

Relative dental maturity and associated skeletal maturity in prehistoric native Americans of the Ohio valley area

Estimation of age-at-death of subadults in prehistoric skeletal samples based on modern reference standards rests on a number of assumptions of which many are untestable. If these assumptions are not met error of unknown magnitude and direction will be introduced to the subadult age estimates. This situation suggests that an independent estimate or estimates of age-related features, free of most of the assumptions made when using modern reference standards may be useful supplements in evaluating the age of subadults in prehistoric samples. The present study provides an internally consistent, population-specific measure of maturity for prehistoric Ohio valley Native Americans based on the seriation of dental development that may be used as a supplement to age-estimation. The developing dentition of 581 subadults from eight Ohio valley prehistoric-protohistoric groups was seriated within and among individuals resulting in a sequence of tooth development and a sequence of individuals from least to most mature. Dental maturity stages or sorting categories were then defined based on exclusive, easily observable, and highly repeatable tooth-formation stages. Tooth eruption (into occlusion), bone lengths, and fusion of skeletal elements are summarized by dental maturity stage. This procedure provides maturity estimates for skeletal features ordered by dental maturity stages derived from the same sample thus making explicit the relationship between dental and skeletal maturity.     

Scoring system for estimating age in the foot skeleton

This study assesses chronological age of immature individuals from the degree of ossification evident in the foot skeleton. We considered all tarsal and ray bones in various combinations to determine the most sensitive indicators of chronological age. Skeletal maturity was rated according to a subjective but simple scoring system applied to radiographs of normal feet of children of known chronological age. Scales for assessing the primary center of ossification, secondary center of ossification, and state of fusion are defined. In general, as expected, females show earlier onset of skeletal maturity than males; in particular, females in our sample are skeletally mature in most elements beginning 48 months prior to the earliest incidence of skeletal maturity in males for the same bones. Females in our sample show a marked tendency toward skeletal maturity of all elements by 150 months of age, while males do not show the same tendency until approximately 200 months of age. In general within each sex, consecutive states of fusion show broad overlap in range of chronological age within each bone. Combining scores from several different bones enables a reasonable estimate of potential age in a test application of the model.     

Appendicular skeletal morphology in minute salamanders,genus Thorius (amphibia: Plethodontidae): Growth regulation,adult size determination,and natural variation

Patterns of growth and variation of the appendicular skeleton were examined in Thorius, a speciose genus of minute terrestrial plethodontid salamanders from southern Mexico. Observations were based primarily on ontogenetic series of each of five species that collectively span the range of adult body size in the genus; samples of adults of each of seven additional species provided supplemental estimates of the full range of variation of limb skeletal morphology. Limbs are generally reduced, i.e., pedomorphic, in both overall size and development, and they are characterized by a pattern of extreme variation in the composition of the limb skeleton, especially mesopodial elements, both within and between species. Fifteen different combinations of fused carpal or tarsal elements are variably present in the genus, producing at least 18 different overall carpal or tarsal arrangements, many of which occur in no other plethodontid genus. As many as four carpal or tarsal arrangements were observed in single population samples of each of several; five tarsal arrangements were observed in one population of T. minutissimus. Left-right asymmetry of mesopodial arrangement in a given specimen is also common. In contrast, several unique, nonpedomorphic features of the limb skeleton, including ossification of the typically cartilaginous adult mesopodial elements and ontogenetic increase in the degree of ossification of long bones, are characteristic of all species and distinguish Thorius from most related genera. They form part of a mechanism of determinate skeletal growth that restricts skeletal growth after sexual maturity. Interspecific differences in the timing of the processes of appendicular skeletal maturation relative to body size are well correlated with interspecific differences in mean adult size and size at sexual maturity, suggesting that shifts in the timing of skeletal maturation provide a mechanism of achieving adult size differentiation among species. Processes of skeletal maturation that confer determinate skeletal growth in Thorius are analogous to those typical of most amniotes – both groups exhibit ontogenetic reduction and eventual disappearance of the complex of stratified layers of proliferating and maturing cartilage in long bone epiphyses – but, unlike most amniotes, Thorius lacks secondary ossification centers. Thus, the presence of secondary ossification centers cannot be used as a criterion for establishing determinate skeletal growth in all vertebrates.     

Sesamoid bones in tuatara (Sphenodon punctatus) investigated with X‐ray microtomography,and implications for sesamoid evolution in Lepidosauria

Sesamoids bones are small intra‐tendinous (or ligamentous) ossifications found near joints and are often variable between individuals. Related bones, lunulae, are found within the menisci of certain joints. Several studies have described sesamoids and lunulae in lizards and their close relatives (Squamata) as potentially useful characters in phylogenetic analysis, but their status in the extant outgroup to Squamata, tuatara (Sphenodon ), remains unclear. Sphenodon is the only living rhynchocephalian, but museum specimens are valuable and difficult to replace. Here, we use non‐destructive X‐ray microtomography to investigate the distribution of sesamoids and lunulae in 19 Sphenodon specimens and trace the evolution of these bones in Lepidosauria (Rhynchocephalia + Squamata). We find adult Sphenodon to possess a sesamoid and lunula complement different from any known squamate, but also some variation within Sphenodon specimens. The penultimate phalangeal sesamoids and tibial lunula appear to mineralize prior to skeletal maturity, followed by mineralization of a sesamoid between metatarsal I and the astragalocalcaneum (MTI‐AC), the palmar sesamoids, and tibiofemoral lunulae around attainment of skeletal maturity. The tibial patella, ulnar, and plantar sesamoids mineralize late in maturity or variably. Ancestral state reconstruction indicates that the ulnar patella and tibiofemoral lunulae are synapomophies of Squamata, and the palmar sesamoid, tibial patella, tibial lunula, and MTI‐AC may be synapomorphies of Lepidosauria. J. Morphol. 278:62–72, 2017. ©© 2016 Wiley Periodicals,Inc.     

The measurement of skeletal maturity

A new approach to the measurement of skeletal maturity has been described. This was applied to the distal end of the femur in boys aged one month to four years. It is planned to extend this study to girls and to other ages and sites and to other bones in the knee area. The study began with the testing of reported indicators of skeletal maturity in respect of replicability, validity, discrimination and universality. As a result, seven qualitative graded indicators and three quantitative ratios were selected for further investigation. Maturity scores based on each qualitative indicator can be estimated using parameters from a simple probit analysis with chronological age as the independent variable. The statistical factors that influence the usefulness of these indicators have been discussed. The quantitative indicators investigated appear very useful as measures of maturity although some are redundant. The planned extension of the present study should allow the formulation of an appropriate model for the measurement of skeletal maturity by combining qualitative and quantitative data.     

Problems in combining skeletal age for an individual

Maturity imbalance between bones from different areas of the body, or between different bones in the same area or even between different centers within the same bones, are not an infrequent experience in doing radiographic assessment of skeletal maturation. Data from previous works have demonstrated tremendous variation concerning the pattern, degree, and causes of the imbalance. In view of the incomplete and contradictory knowledge concerning the mechanism producing such imbalance, it was only recommended to obtain the unweighted arithmetic mean of all the separately assessed bones as the overall skeletal age for an individual. It was hoped, however, that enthusiastic collection of new data on multiple bone assessments would soon take place which would facilitate a further recognition of the significance in skeletal maturity imbalance.     

Skeletal elements within teleost eyes and a discussion of their homology

Scleral ossicles and scleral cartilages form part of the craniofacial skeleton of many vertebrates. Some vertebrates, including all birds and most reptiles, but excluding most mammals, have scleral cartilages as well as scleral ossicles supporting their eyes. The teleost equivalent of these elements has received little attention in the literature. From radiographic and whole-mount analyses of over 400 individuals from 376 teleost species, we conclude that the teleost scleral skeletal elements (ossicles and cartilage) differ significantly from those of reptiles (including birds). Scleral ossicles in teleosts have different developmental origins, different positions within the eyeball, and different relationships with the scleral cartilaginous element than those in reptiles. From whole-mount staining of a growth series of four species of teleost (Danio rerio, Salmo salar, Esox lucius, and Alosa pseudoharengus), we interpret the development of these elements and show that they arise from within an Alcian blue-staining cartilaginous ring that develops around the eye earlier in development. We present possible scenarios on the evolution of these scleral skeletal elements from a common gnathostome ancestor, and consider that teleost scleral skeletal elements may not be homologous to those in reptiles. Our study indicates that homology cannot be assumed for these elements, despite the fact that they share the same name, scleral ossicles.     

The Relationship of Rapid Weight Gain in Infancy to Obesity and Skeletal Maturity in Childhood

Objective: Children with birth weight appropriate for gestational age (AGA) who also demonstrate rapid weight gain in infancy have a greater risk of being overweight or obese during childhood. A concurrent advancement in skeletal maturity would account for their greater size and would, therefore, not necessarily pose a threat of greater risk during adolescence and early adulthood. This study aims to determine whether children with rapid weight gain during infancy have advanced skeletal maturity during childhood. Research Methods and Procedures: One hundred and ninety‐three African children (boys = 108; girls = 85) of normal birth weight and gestational age were assessed from birth to 9 years. Body composition was assessed at 9 years of age by whole‐body DXA, and skeletal maturity was assessed using the Tanner‐Whitehouse II technique. Rapid weight gain in infancy was defined as a +0.67 change in weight‐for‐age Z‐score between birth and 2 years. Results: Rapid weight gain was experienced by over 20% of the sample. Children with rapid weight gain were significantly lighter at birth and significantly taller, heavier, and fatter throughout childhood. Chronological age and Tanner‐Whitehouse II technique skeletal ages at 9 years were not significantly different between groups or between sexes within groups. Discussion: Because AGA children with rapid weight gain have a greater risk of overweight and obesity but are not advanced in skeletal maturity, later adolescent adjustments toward average weight and fatness values are unlikely. The identification and monitoring of such children is of importance in reducing their risk of morbidity.     

Comparability in skeletal maturation research

Comparability is a fundamental issue in skeletal maturation research. Since the introduction of the first edition of the Greulich-Pyle Atlas and the Tanner-Whitehouse method, a number of methodologic reports have appeared regarding potential sources of error, reliability and replicability in the assessment of skeletal maturity from hand-wrist radiographs. Some of these reports are mentioned and two recent examples of methodologic studies are cited. Maximum reliability of skeletal assessments can be expected only when there is strict adherence to carefully standardized investigative procedures. Technical as well as human factors must be taken into account to insure minimal variation in findings within and between laboratories over time. Single or serial skeletal radiographs uniformly taken on properly identified subjects constitute a valuable permanent record of biologic maturation. while the film image can be considered as objective evidence of skeletal maturity, a subjective element is introduced in observing and reporting the presence or absence of particular ossification centers, or rating an ossification pattern against a standard. Intra- and interobserver skeletal maturity assessment replicability relates to such factors as motivation, training, assessment method, and quality control procedures. Suggestions are presented to facilitate comparability in skeletal maturation research, including the possibility of preparation and distribution of sets of standardized skeletal radiographs for periodic determination and improvement of assessor reliability.     

Human prenatal palatal closure related to skeletal maturity of the jaws

The purpose of the present study was to elucidate the stages of skeletal maturation of the maxilla and the mandible at the time of soft tissue palatal closure. Similar studies were not found in the literature. This investigation was based on maxillae and mandibles from 19 human embryos/fetuses selected by visual inspection of palatal structures, eight fetuses "just before palatal closure," and 11 fetuses "just after palatal closure." The findings are related to formerly described skeletal developmental stages in the maxilla, to stages in the symphysis menti region, and to development in the mandibular condylar region. The present study revealed that elevation of the palatal shelves takes place at a specific stage of maxillary skeletal maturity (stage Max III), at a time of mandibular development characterized by absence of condylar cartilage and by constancy in symphysis menti maturity (stage SM I). Knowledge of the normal sequence of prenatal skeletal development is considered essential for understanding the abnormal sequence of skeletal development.     

Of Lichens,Caribou and Tuna

Delayed skeletal maturation has been long accepted as a correlate of mental retardation. Three hundred mentally retarded children were examined for skeletal age and failed to show any overall delay of bone age as compared to chronological age. Further, birth weight was found to be unrelated to bone age maturity. Children with severe levels of retardation displayed significant delay in bone development only when profound physical disability was also present. In eight diagnostic categories of mental retardation, only those with metabolic syndromes showed any significant delay in skeletal system maturation. Conversely, mongoloid children showed a larger-than-chance percentage of advanced bone maturation. Skeletal measures therefore are perhaps more reflective of etiological states than of diagnostic classifications in mental retardation.     

男性青少年脂肪组织分布与相对骨龄的关系——Fels追踪研究

本文对Fels追踪研究中8—17岁男性青少年的相对骨龄与脂肪分布类型之间的关系做了分析。按体重/身高~2调整后,如用每个年龄的三种皮褶厚度(ST)指数的均值表示脂肪分布类型的话,8—12岁时,脂肪分布类型呈外周型分布,但13岁后开始朝向心型发展呈全身性分布。如用肩胛下ST/(肩胛下ST+肱三头肌区ST)的比例表示的话,那么14—17岁时,相对骨龄早者(简称早组)与相对骨龄晚者(简称晚组)相比,前者有较明显的向心型分布倾向。13—14岁时,早组的上述比值的年增长明显大于晚组。但是,按脂肪分布类型指数等级的基线和体重/身高~2调整之后,7、11或14岁时的相对骨龄不能预测17岁时的脂肪分布类型指数的等级。所以,我们可以得出这样的结论:如按本文的比例指数加以定量的话,脂肪分布类型与男性青少年的相对骨龄只有微弱的关系。他们的脂肪分布类型可能与其它成熟指征(如男性青春期的第二性征)有明显的关系。     

Skeletal maturation of the human fetus assessed radiographically on the basis of ossification sequences in the hand and foot

In studies of postnatal human development the skeletal maturation of the hand has been found to be a better indicator of general physical maturation than attained body height. For assessment of prenatal human development the Crown-rump length (CRL) has so far been the most commonly used measure. The object of the present study is to examine the possibility of also using the skeletal maturation of the hand as a maturity indicator in fetal development. The study is based upon a radiographic and histochemical investigation of 169 human fetuses. On the basis of counting silver-impregnated diaphyses on radiographs of the hand and foot a maturity indicator (CNO = Composite Number of Ossified bones in hand and foot) was established. Owing to the marked regularity of the recorded ossification pattern, the CNO parameter can be used for evaluating fetal maturation during the early half of the prenatal period. To supplement the assessment of skeletal maturation during the later stages of development, a classification based on the shape of some bones was included in the study. In many cases fetuses of the same size (CRL) exhibited different stages of skeletal maturation (CNO). In accordance with findings from assessment of postnatal development, a more accurate evaluation of fetal development is obtained by combining the size parameter CRL with an assessment of fetal skeletal maturation, CNO.