The aim of this paper was the comparison of the higher order nonverbal abilities, between young children and older adults. In specific, 42 kindergarten and 56 elementary school students (age range: 5 - 8 years), as well as 118 new-old adults and 27 old-old adults (age range: 61 - 88 years), were examined in the Children’s Category Test-Level 1 (CCT-1). Findings from the Confirmatory Factor Analyses that were applied to data, possibly reflect the delay of development of general abstraction and working memory in the group of kindergarten students and the decline of them in the group of old-old adults.
Researchers in the field of cognitive aging seem to agree that, on average, cognitive functioning declines with aging. Among the cognitive abilities that seem to be more affected by age is fluid intelligence (Baltes, 1997; Moraitou & Efklides, 2012; Salthouse, Pink, & Tucher-Drob, 2008) . Inference, inductive or deductive or heuristic, reflects processes that take an active part during problem solving in novel situations, independent of acquired knowledge. These processes underlie fluid intelligence (Demetriou, Spanoudis, Shayer, van der Ven, Brydges, Kroesbergen, Podjarny, & Swanson, 2014) . More specifically, according to the Dual-Process Model of Life Span Intellectual Development “the fluid cognitive mechanics are indexed by the speed and accuracy of elementary processes of information processing: information input; visual and motor memory; and basic perceptual-cognitive processes such as discrimination, comparison, categorization, as well as their application in working memory” (Baltes, 1997) . Furthermore, regarding the fluid mechanics, life span theory predicts a form of an inverted U-shape function across the life span, with decline beginning in young adulthood (see Baltes, 1997; Baltes & Lindenberger, 1997; Horn & Hofer, 1992 ), while the information processing theories propose that the developmental differences in fluid intelligence reflect differences in processing speed or working memory (see Demetriou et al., 2014 ).
Moreover, researchers have observed the general relationship between aging and development as findings in gerontological research have indicated that the collapse of intelligence in dementia patients causes retrogression to childhood and/or appears to reverse Piaget’s developmental stages (de Ajuriaguerra & Tissot, 1968; Rubial-Álvarez, de Sola, Machado, Sintas, Böhm, Sánchez-Benavides, Langohr, Muñiz, & Peña-Casanova, 2013; Shoji, Fukushima, Wakayana, Shizuka-Ikeda, Ikeda, Kawakami, Sakazume, Ikeda, Harigaya, Matsubara Kawarabayashi Murakami, Nagano, Manabe, & Abe, 2002) . As stated by the retrogenic models, there is an inverse and progressive pattern of functional and cognitive decline observed in Alzheimer’s Disease (AD) patients compared to the developmental acquisition of the corresponding capacities in children. Retrogenesis has been defined as the process by which degenerative mechanisms reverse the order of acquisition in normal development (Reinsberg, Franssen, Hasan, Monteiro, Boksay, Souren, Kenowsky, Auer, Elahi, & Kluger, 1999a; Reinsberg, Franssen, Souren, Auer, Akram, & Kenowsky, 2002; Reinsberg, Kenowsky, Franssen, Auer, & Souren, 1999b) .
The findings regarding the retrogenic models suggest that comparisons should be made between the cognitive ability of these two groups of population, namely the developing children and the retrograding elderly people. This suggestion has been taken into account in the limited use, in assessing cognition in moderate and severe AD patients, of several screening instruments available for cognitive examination in infancy and childhood. For example, the application of the adapted and modified Ordinal Scales of Psychological Developmental (OSPD), developed by Uzgiris and Hunt for cognitive testing in infants, has been found to be superior to the use of traditional tests, such as the Mini-Mental State Examination (MMSE), in evaluating the cognitive ability of patients with moderately severe and severe AD (Borza, 2012) . It was also reported that the use of test measures previously applied to infants and young children, based on Piagetian tradition, demonstrated residual cognitive capacity in subjects with severe AD previously considered untestable (Da Silva, Bueno, & Bertolucci, 2011; Reinsberg et al., 1999a) . Furthermore, childhood intelligence test measures, such as the Japanese version of the Binet scale, namely the Tanaka-Binet intelligence scale, has been found to be useful in evaluating cognition in moderate to severe AD patients (Borza, 2012) .
Since there is a loss of cognitive abilities acquired during childhood before the appearance of clinically detectable dementia (Shoji et al., 2002) , comparisons of cognitive ability should also be made between the aforementioned groups of population, namely the developing children and the cognitively normal older adults or preclinical AD patients.
As regards the preclinical AD patients with neurological changes, it was reported that they do not demonstrate measurable cognitive decline on standard tests (Goldman, Price, Storandt, Grant, McKeel, Rubin, & Morris, 2001; Schmitt, Davis, Wekstein, Smith, Ashford, & Markesbery, 2000) . More sensitive tests to detect early or preclinical stages of AD are desired, such as the MMSE, Wechler Adult Intelligence Scale-Revised (WAIS-R) and the Wechler Memory Scale-Revised (WMS-R), which are evidence- based test batteries for memory decline and intelligence. However, these scales can be administered (have been developed and standardized) only to persons between 16 and 74 years of age (Shoji et al., 2002) .
In order for an approximate comparison between children’s and older adults’ cognitive ability to be correctly conducted, the administration of the same screening instruments to the two groups should be available (Papantoniou, Moraitou, Dinou, Katsadima, Savvidou, & Foutsitzi, 2015; Rubial-Alvarez, Machado, Sintas, de Sola, Böhm, & Peña-Casanova, 2007; Shoji et al., 2002) . In addition, throughout the many attempts that have been made to develop test batteries for the early detection of dementia, it is also possible that the detection of preclinical AD could be more accurate through neuropsychological tests focused on the detection of developmental disturbances both in young children and older adults. Therefore, simple screening instruments, available for cognitive examination in infancy and childhood, are needed to allow the assessment of the cognitive ability in older adults, in a short period of time, which would assist in early detection of cognitive impairment.
Although, there is an increase in the number of the neuropsychological tests designed to evaluate brain dysfunction in children, until recently there were few measures of novel problem-solving for children that were adequately standardized and normed. The Children’s Category Test (CCT; Boll, 1993 ) is included among them due to its age- based norms that were based on a large standardization sample that was representative in the U.S. population.
The CCT is an instrument originally created from short forms of the child versions of the Halstead Category Test (HCT; Halstead, 1947 ) in an effort to reduce lengthy administration times of the original versions, providing a more efficient and user-friendly version of the HCT, which has established sensitivity to acquired cerebral impairment (Allen, Caron, & Goldstein, 2006) . The CCT is an instrument designed to assess non- verbal learning and memory, concept formation and problem-solving abilities with novel material. It provides information on the child’s ability to develop alternative solutions, to change problem-solving strategies, to benefit from experience, and to develop, test, and modify hypotheses. This constellation of cognitive processes is highly related to fluid intelligence. The CCT may be used to determine whether or not a child is able to perform the aforementioned processes despite the existence of learning disorders, verbal or motor deficits, neurological deficits, or emotional handicaps (Boll, 1993) . The Children’s Category Test consists of two levels. Level one (CCT-1) was developed for children of 5 - 8 years of age, and Level two (CCT-2) was intended for ages 9 - 16. Both levels require from the child to create and modify strategies of responding to visual stimuli based on corrective feedback.
Studies of the standardization sample indicate that CCT-1 has adequate internal consistency and criterion validity (Boll, 1993) . However, research with the standardization sample has suggested that the CCT-1 may be a multifactorial task that measures various aspects of abstraction and problem-solving abilities, rather than one more general abstraction construct. Factor analytic studies have provided evidence for the multidimensional nature of the CCT-1. For example, an exploratory factor analysis of the standardization sample indicated that the CCT-1 was composed of two factors, with moderate loadings of subtests II and III on one factor, and high loadings of subtests IV and V on another one. No formal names were assigned to the factors, although both factors were thought to assess reasoning abilities, with second factor requiring “…a relatively higher level of concrete operational reasoning” (Donders, 1999: p. 281) . More recently, a study by Moore, Donders, & Thompson (2004) indicated that the CCT-1 subtests are differentially sensitive to the severity of brain injury. In specific, Moore et al. (2004) found subtests III and V to be sensitive to brain damage, but in the standardization sample these two subtests loaded on separate factors. Therefore, the factor structure of the CCT-1 suggested by Donders (1999) and Moore et al. (2004) is different. Since it is not unusual for psychometric measures to have a different latent structure in a clinical sample, than in the standardization sample (Woodward & Donders, 1998) , it seems that the factor structure of the CCT-1 differs in children with brain dysfunction, compared to those without.
Taking into account the aforementioned findings, Allen, Knatz, & Mayfield (2006) used Confirmatory Factor Analysis (CFA) in order to examine the construct validity of the CCT-1, in a clinical sample with heterogeneous forms of brain dysfunction, by contrasting the factor structure reported in the standardization sample (Donders, 1999) , to the one indirectly suggested by Moore et al. (2004) . The factor structure found in Allen et al.’s (2006) clinical sample, using CFA, was similar to the one found in the standardization sample (Donders, 1999) , with subtests II and III forming one factor, and subtests IV and V forming another. Allen et al.’s (2006) results support viewing CCT-1 as a multidimensional procedure that assesses two distinct but related constructs (factors). The first construct, “Conceptual Discrimination”, is consistent with the view that the CCT-1 is a measure of problem solving and reasoning. The second, “Conceptual Memory”, appears to assess learning and memory, and as such departs from what might be traditionally thought of as a test of reasoning ability (Allen et al., 2006) .
Based, firstly, on findings in the field of cognitive aging, supporting that fluid intelligence increases rapidly in the early years of life and declines with aging (Baltes, 1997; Moraitou & Efklides, 2012; Salthouse et al., 2008) , and, secondly, on the hypothesis of “retrogenesis”, the aim of the present study was the comparison of the, related with fluid intelligence, higher order thinking abilities such as general abstraction and reasoning, between the developing children and the cognitively healthy older adults. The comparison has been conducted through the investigation of the qualitative changes in the latent structure of the CCT-1, from age to age, using CFA.
Comparing pair-wise the four groups of our sample (first- to second-grade elementary school students with new-old adults, & kindergarten students with old-old adults), the latent structure of the CCT-1 was expected to differentiate between first- to second-grade elementary school students and new-old adults, on the one hand and kindergarten students and old-old adults, on the other (Hypothesis 1).
In specific, we expected to find similar latent structure of the CCT-1 for first- to second-grade elementary school students and new-old adults (Hypothesis 2a), and similar latent structure of the CCT-1 for kindergarten students and old-old adults (Hypothesis 2b).
The total sample consisted of four groups of individuals: a group of kindergarten students, a group of first- to second-grade elementary school students, a group of new-old adults, and a group of old-old adults.
The first group comprised 42 kindergarten students 5 to 6 years old (mean age = 68.1 months, age range: 61 - 75 months). Of the 42 participants, 16 were boys (38.1%) and 26 were girls (61.9%). The second group included 56 first- to second-grade elementary school students 6 to 8 years old (mean age = 85.45 months, age range: 74 - 98 months). Of the 56 participants, 22 were boys (39.3%) and 34 were girls (60.7%). None of the children had a history of learning difficulties (based on the school records and student reports) and they all attended the regular curriculum in two preschool institutions (one public and one private) and three primary schools (two public and one private) of medium and high socioeconomic status, in the city of Ioannina in Epirus (a province in the West of Greece).
Furthermore, two groups of older adults were tested. In specific, one group comprised 118 new-old adults (mean age = 71.33 years, age range: 61 - 79 years). Of the 118 participants, 45 were men (38.1%) and 73 were women (61.9%). The second group of older adults included 27 old-old adults (mean age = 83.04 years, age range: 80 - 88 years). Of the 27 participants, 10 were men (37.0%) and 17 were women (63.0%). Exclusion criteria for both groups were a history of neurological conditions or psychiatric diseases, alcohol or drug abuse, severe head trauma, profound visual impairments, and verbal incomprehension. None of the participants had been diagnosed as meeting the diagnostic criteria for possible dementia, by consultant neurologists and psychiatrists. All the participants were community dwelling adults-volunteers recruited by the researchers from seniors’ day-care centers. They were residents of Thessaloniki and Kozani (a town in the province of West Macedonia in Greece). It should be noted that the subsample of older adults included an over representation (57.2%) of persons with 9 years of formal education or fewer.
Children’s Category Test-Level 1 (CCT-1): The CCT-1 (Boll, 1993) is an individually administered test designed for children between the ages of 5 to 8 years. It is presented in booklet form and consists of 80 items distributed across 5 subtests. Each of the subtests I and V comprises 10 items while each of the subtests II, III and IV comprises 20 items.
The items comprising each subtest are connected by a single principle which varies across the subtests. The test requires the child to identify the conceptual rule that underlies each subtest and apply that concept to answering each item correctly. The child is shown a series of pictures that is intended to suggest a particular color and it has to respond by pointing to (or verbally identifying) one of four colors printed in a response card. The child receives immediate feedback as to the correctness of each response and it is expected to use this feedback to determine the conceptual rule underlying the subtest. Subtest I can be employed as a practice test to determine if the child understands the task and is able to provide appropriate responses, while subtest V requires the child to remember and apply the principles of the previous subtests. The conceptual rules underlying the subtests include the following: color recognition (subtest I), determination of the relative quantity of a specific color (subtest II), identification of the oddity in shape or size (subtest III), identification of the missing color (subtest IV), and review of the principles presented in subtests I through IV (subtest V).
As regards CCT-1 reliability, averaged coefficient, based on Fisher’s z transformation, is 0.88 demonstrating that CCT-1 possesses a high degree of internal consistency. The averaged test-retest reliability for the total error T score is 0.79 indicating that scores on the CCT-1 possess adequate stability across short time of periods. In specific, higher reliability coefficients are expected as the time between testing increases to 2 to 6 months (Boll, 1993) .
As regards the participation of the kindergarten and elementary school students in the study, in collaboration with the school committees, their parents were asked to give a written statement of consent prior to the testing and then they completed an individual-demographics form. Children’s testing in CCT-1 was performed at an individual basis, in their school environment. No time limit was assigned for the completion of the tests and all young participants were informed that they were free to withdraw from testing at any time.
Older adults were also examined at an individual basis, either at the center from which they had been recruited, or in their own home. No time limit was assigned for the completion of the examination and the participants were informed that they were free to withdraw from testing at any time. All the participants signed an informed consent and then they completed an individual-demographics form.
The test was administered according to standard procedures by a psychologist and doctoral practicum students who were trained to the reliable and valid administration of the test.
According to the introduction section, previous empirical works have implied two alternative two-factor models for the CCT-1 dimensionality. The aforementioned two- factor models were a priori competing with each other, as well as with a one-factor model in which subtests II, III, IV, and V were specified to load on a single factor (Allen et al., 2006) . Hence, taking into account findings supporting that factor structure of neurocognitive measures may vary from one population to the next (Woodward & Donders, 1998) , we used CFA in order to investigate possible qualitative changes in the latent structure of the CCT-1, between developing children and cognitively healthy older adults.
Since the CCT-1 manual does not provide normative data per subtest and because of the relatively small sample size of each group, the total raw numbers of errors per subtest on CCT-1 were used in the analysis of the present study. Subtest I was not included in the CFA because only 20 (8.2%) participants (4 kindergarten students, 6 elementary school students, and 10 new-old adults) made errors on subtest I and the rest (including all of the old-old adults) had completely flawless performance. As a result the distribution of error scores for subtest I did not meet assumptions of multivariate normality, which is desirable for factor analyses (see Allen et al., 2006; Moore et al., 2004 ). Therefore, each covariance matrix was based on four total scores (measured variables), namely, total raw score for subtest II, total raw score for subset III, total raw score for subset IV, and total raw score for subset V.
CFA was conducted in EQS Version 6.1 (Bentler, 2005) and performed on the five covariance matrices, which stemmed from the total sample and each one of the four groups of participants, using the Maximum Likelihood (ML or ML ROBUST) estimation method. The Wald test was used to test the need for the estimated parameters and to suggest a more restricted model.
Initially, we compared the three following factor structures, in the total sample (Models A): Model A1 [the one-factor model in which all four measured variables loaded on a single latent variable], Model A2 [the two-factor model which proposed a factor consisting of subtests II and IV, and a second factor consisted of subtests III and V, with interrelations between the two factors] and Model A3 [the two-factor model which proposed a factor consisting of subtests II and III, and a second factor consisted of subtests IV and V, with interrelations between the two factors]. Goodness-of-Fit Indexes for the CFA Models A are presented in
As shown in
Model (factor) | χ2 | P | CFI | χ2/df | SRMR | RMSEA |
---|---|---|---|---|---|---|
Model A1 (Single factor) | χ2(2, N = 243) = 17.59 | <0.001 | 0.96 | 8.79 | 0.04 | 0.18 (CI90% 0.11 - 0.26) |
Model A2 (Two-factors: one consisted of subtests II and IV & one of subtests III and V + interrelation between factors) | χ2(1, N = 243) = 13.68 | <0.001 | 0.97 | 13.68 | 0.03 | 0.23 (CI90% 0.13 - 0.34) |
Model A3 (Two-factors: one consisted of subtests II and III & one of subtests IV and V + interrelation between factors) | χ2(1, N = 243) = 0.04 | =0.83 | 1.00 | 0.04 | 0.00 | 0.00 (CI90% 0.00 - 0.10) |
In order to compare the latent structure in CCT-1 between elementary school students and new-old adults, we tested the three aforementioned factor structures, in the group of first- to second-grade elementary school students (Models B). Due to the statistically significant excess kurtosis of this group of the sample, Models B1, B2 and B3 were computed using the Maximum Likelihood (ML ROBUST) estimation method. Goodness-of-Fit Indexes for the CFA Models B are presented in
As can be seen in
Model (factor) | Satorra-Bentler scaled χ2 | P | CFI | χ2/df | SRMR | RMSEA* |
---|---|---|---|---|---|---|
Model B1 (Single factor) | χ2(2, n = 56) = 2.48 | =0.29 | 0.97 | 1.24 | - | 0.07 (CI90% 0.00 - 0.28) |
Model B2 (Two-factors: one consisted of subtests II and IV & one of subtests III and V + interrelation between factors) | χ2(1, n = 56) = 0.57 | =0.45 | 1.00 | 0.57 | - | 0.00 (CI90% 0.00 - 0.32) |
Model B3 (Two-factors: one consisted of subtests II and III & one of subtests IV and V + interrelation between factors) | χ2(1, n = 56) = 0.49 | =0.48 | 1.00 | 0.49 | - | 0.00 (CI90% 0.00 - 0.31) |
Model (factor) | χ2 | P | CFI | χ2/df | SRMR | RMSEA |
---|---|---|---|---|---|---|
Model C1 (Single factor) | χ2(2, n = 118) = 19.94 | <0.001 | 0.94 | 9.97 | 0.04 | 0.28 (CI90% 0.17 - 0.39) |
Model C2 (Two-factors: one consisted of subtests II and IV & one of subtests III and V + interrelation between factors) | χ2(1, n = 118) = 14.34 | <0.001 | 0.96 | 14.34 | 0.03 | 0.34 (CI90% 0.20 - 0.50) |
Model C3 (Two-factors: one consisted of subtests II and III & one of subtests IV and V + interrelation between factors) | χ2(1, n = 118) = 0.01 | =0.92 | 1.00 | 0.01 | 0.00 | 0.00 (CI90% 0.00 - 0.08) |
*Given that additional support for the fit of the solution would be evidenced by a 90% confidence interval (CI) of the RMSEA whose upper limit is below the cutoff values of 0.08 - 0.10 (see Brown, 2006 ), at this point it should be mentioned that the width of the CI for RMSEA is affected by sample size (e.g., when N < 100) and the number of freely estimated parameters. Thus, in such cases the values and the width of the 90% CI for RMSEA should be treated cautiously and with less concern if all other indices are strongly in a range supporting “good” model fit ( Bollen, 1990; Brown, 2006 ).
Therefore, the two-factor Model B3 provided the best fit of the data when compared to Models B1 and B2. For Model B3, the Goodness-of-Fit Indexes were excellent (Brown, 2006) . According to the suggestions of the Wald test all the parameters’ loadings of Model B3 were statistically significant except for the measurement error of the indicator that represented the raw total error score of subtest V (p = 0.93). The Model B3 is displayed in
Then, we tested the three aforementioned factor structures, in the group of new-old adults (Models C). Goodness-of-Fit Indexes for the CFA Models C are presented in
As shown in
The comparison of the CFA Model B3 with the Model C3 indicates a similar latent structure in CCT-1 for first- to second-grade elementary school students and new-old adults and verified Hypothesis 2a.
In order to compare the latent structure in CCT-1 between kindergarten students and old-old adults, we tested the three aforementioned factor structures, in the group of kindergarten students (Models D). Goodness-of-Fit Indexes for the CFA Models D are presented in
As can be seen in
It should be noted here, that according to the suggestions of the Wald test all the parameters’ loadings of Models D1, D2, and D3 were statistically significant except for the measurement error of the indicator that represented the raw total error score of subtest V, both for the Model D2 (p = 0.33) and Model D3 (p = 0.80). For the group of kindergarten students, Cronbach’s α coefficient was 0.65 for a scale consisted of all four measured variables loaded on the single latent variable. The Model D3 is displayed in
Finally, we tested the three aforementioned factor structures, in the group of old-old
Model (factor) | χ2 | P | CFI | χ2/df | SRMR | RMSEA* |
---|---|---|---|---|---|---|
Model D1 (Single factor) | χ2(3, n = 42) = 2.59 | =0.46 | 1.00 | 0.86 | 0.08 | 0.00 (CI90% 0.00 - 0.25) |
Model D2 (Two-factors: one consisted of subtests II and IV & one of subtests III and V + interrelation between factors) | χ2(1, n = 42) = 0.28 | =0.60 | 1.00 | 0.28 | 0.02 | 0.00 (CI90% 0.00 - 0.33) |
Model D3 (Two-factors: one consisted of subtests II and III & one of subtests IV and V + interrelation between factors) | χ2(1, n = 42) = 0.04 | =0.85 | 1.00 | 0.04 | 0.01 | 0.00 (CI90% 0.00 - 0.23) |
Model (factor) | χ2 | P | CFI | χ2/df | SRMR | RMSEA* |
---|---|---|---|---|---|---|
Model E1 (Single factor) | χ2(2, n = 27) = 1.61 | =0.45 | 1.00 | 0.80 | 0.04 | 0.00 (CI90% 0.00 - 0.36) |
Model E2 (Two-factors: one consisted of subtests II and IV & one of subtests III and V + interrelation between factors) | χ2(1, n = 27) = 0.00 | =0.96 | 1.00 | 0.00 | 0.00 | 0.00 (CI90% cannot be computed) |
Model E3 (Two-factors: one consisted of subtests II and III & one of subtests IV and V + interrelation between factors) | χ2(1, n = 27) = 1.48 | =0.23 | 0.99 | 1.48 | 0.03 | 0.13 (CI90% 0.00 - 0.55) |
*Given that additional support for the fit of the solution would be evidenced by a 90% confidence interval (CI) of the RMSEA whose upper limit is below the cutoff values of 0.08 - 0.10 (see Brown, 2006 ), at this point it should be mentioned that the width of the CI for RMSEA is affected by sample size (e.g., when N < 100) and the number of freely estimated parameters. Thus, in such cases the values and the width of the 90% CI for RMSEA should be treated cautiously and with less concern if all other indices are strongly in a range supporting “good” model fit (Bollen, 1990; Brown, 2006) .
adults (Models E). Goodness-of-Fit Indexes for the CFA Models E are presented in
As can be seen in
Therefore, the one-factor Model E1 in which all four measured variables loaded on a single latent variable provided the best fit of the data when compared to Models E2 and E3. For Model E1, the Goodness-of-Fit Indexes were excellent (Brown, 2006) . According to the suggestions of the Wald test all the parameters’ loadings of Model E1 were statistically significant. For the group of old-old adults, Cronbach’s α coefficient was .75 for a scale consisted of all four measured variables loaded on the single latent variable. The Model E1 is displayed in
The comparison of the CFA Models D1, D2, and D3, on the one hand, with the Model E1, on the other, does not indicate a quite similar pattern of structure in CCT-1 for kindergarten students and old-old adults and does not fully verify Hypothesis 2b.
To summarize, the aforementioned findings confirm Hypothesis 1 and support the existence of a different factor structure in CCT-1 between first- to second-grade elementary school students and new-old adults, on the one hand, and kindergarten students and old-old adults, on the other.
The aim of the present study was the comparison of the higher order thinking abilities, which are related to fluid intelligence, between the developing children and the retrograding older adults through the investigation of the qualitative changes in the latent structure of the CCT-1, from age to age, using CFA. For the groups of elementary school students and new-old adults, the results of CFA seem to support the existence of two factors measured by the CCT-1, namely a “Conceptual Discrimination” factor, and a “Conceptual Memory” factor. These results are consistent with previous findings (see Allen et al., 2006; Donders, 1999 ) regarding the factor structure of the CCT-1.
On the contrary, for the groups of kindergarten students and old-old adults, the existence of the aforementioned two-factor structure of the CCT-1 was not fully confirmed. In specific, for the group of kindergarten students, CFA verified all three testing models: one which was similar to the aforementioned two factors model, a second model in which two measured variables (subtest II and subtest IV) loaded on one underlying factor and the other two variables (subtest III and subtest V), loaded on a second underlying factor, as well as a third single-factor model in which all four measured variables loaded on a general abstraction factor.
The simultaneous verification of all three a priori competing models, for the group of kindergarten students, is consistent with previous findings (Fajgelj, Bala, & Katic, 2010; Papantoniou et al., 2015) , indicating that the factor solutions of the [R] Educational CPM test are stabilized after the age of 5 - 6, and reflects a delay of differentiation in general abstraction and reasoning of kindergarten students. A possible explanation for this delay could be that abstraction is possible to start as a unitary cognitive operation and only later to develop into conceptual discrimination and conceptual memory. Some researchers (Fajgelj et al., 2010) provided another explanation, taking also into account a possible component of complex reasoning, namely the executive functioning. According to them, the delay of stabilization of the CCT-1 factor structure at earlier ages could reflect lack of metacognitive and self-regulative processes―two of the main components of executive functioning―and could be attributed to the inflexible solving strategy, the poor management of goal activity and the weak mechanisms of control (Anderson & Reidy, 2012; Carlson, Davis, & Leach, 2005; Miyake, Friedman, Emerson, Witzki, Howerter, & Wager, 2000) .
An additional explanation could be provided taking into account Demetriou, Spanoudis, Shayer, Mouyi, Kazi, & Platsidou’s (2013) finding that the relations between speed, working memory and fluid intelligence vary with growth. According to Demetriou et al. (2014: p. 109) , “Fluid intelligence evolves along a reconceptualization sequence (ReConceP) where changes in the nature of representations alternate with changes in the command and interlinking of representations constructed earlier”. This sequence involves four reconceptualization cycles with transition from symbol-based mental representations (2nd cycle) to inference-based concepts (3rd cycle) at 6 years. Demetriou et al. (2013 , 2014) also found that changes in fluid intelligence were predicted by working memory at the second phase (i.e. at 4 - 6 years) of the second cycle (symbol-based mental representations) and by speed at the first phase (i.e. at 6 - 8 years) of the third cycle (inference-based concepts). Since the group of kindergarten students of our study comprised children 5 to 6 years old (mean age = 68.1 months), who were at the age boundary between the second phase of the symbol-based mental representations cycle and the first phase of the inference-based concepts cycle, and given that according to Demetriou et al. (2014) , the age boundary are approximate, the simultaneous verification of all three a priori competing models could reflect the young participants’ individual differences, either in working memory, or in speed of pro- cessing. More specifically, the verification of the two-factors measured by the CCT-1, namely a “Conceptual Discrimination” factor, and a “Conceptual Memory” factor could reflect the early start of speed to operate as the predictive construct of fluid intelligence, while the confirmation of the single-factor model in which all four measured variables loaded on a general abstraction factor could reflect the still developing working memory as the predictive construct of fluid intelligence.
Regarding the group of old-old adults, the results of CFA support the existence of a single general abstraction factor measured by the CCT-1, although previous findings (Allen et al., 2006; Donders, 1999; Moore et al., 2004) , in both normal and clinical population, support viewing the CCT-1 as a multidimensional measure, rather than one more general abstraction construct.
The start of uniformity of conceptual discrimination (problem solving and reasoning) and conceptual memory (learning and memory) reflecting in the unidimensional structure of the CCT-1 test that was observed for the group of old-old adults, is possible to indicate a qualitative change, perhaps a start of disorganization in the abstraction and reasoning of the old-old adults comparing to those of the new-old adults (Anderson & Reidy, 2012; Carlson et al., 2005; Miyake et al., 2000; Salthouse, 2005; Savvidou, Papantoniou, Moraitou, Dinou, Katsadima, Foutsitzi, & Tsentidou, 2016; Zelazo & Carlson, 2012) . This finding is consistent with the general admission in the field of cognitive aging, stating that cognitive functioning declines with aging and fluid intelligence―which is highly related to general reasoning―is among the cognitive abilities that seem to be more affected by age (Baltes, 1997; Moraitou & Efklides, 2012; Salthouse et al., 2008) . Taking into account, that the comparison of the CFA models, which were confirmed in the present study, for kindergarten students and old-old adults, indicate a similar pattern in the structure of the CCT-1 as regards the existence of a single general abstraction factor measured by it, on the one hand, and that working memory seems to act as the predictive construct of kindergarten students’ fluid intelligence (Demetriou et al., 2013, 2014) , on the other, the uniformity of conceptual discrimination and conceptual memory, that was found for the old-old adults, could be attributed to a deficit in their working memory. It should be also noted that the disorganization of these higher order thinking abilities, which are related to fluid intelligence, was found to be present before the appearance of clinically detectable dementia in the participants in the sample of old-old adults. This result seems to be in line with findings indicating that a large proportion of healthy old-old adults shows memory decline which may represent the early stages of a potentially more severe cognitive impairment (Goldman et al., 2001; Shoji et al., 2002; Schmitt et al., 2000) .
In general terms, the different pattern in the latent factor structure of the CCT-1, that was found in the present study, between the groups of kindergarten students and old-old adults, on the one hand, and the groups of first- to second-grade elementary school students and new-old adults, on the other, supports the hypothesis of “retrogenesis”. However, our research findings must be interpreted with a few limitations in mind. The restricted nature of the sample should be noted with regard to the number of participants in each age group as well as to the comparative uniformity of 1) the educational status in the groups of the older adults and 2) the socioeconomic status in the groups of students. More research is also needed to further validate and refine, in other cultural contexts, the different pattern in the structure of the higher order thinking abilities, as they are measured by the CCT-1, that was found among the various groups of the present study.
Nevertheless, the results of our study conducted in a Greek population, with the size of the sample used, support the usefulness of the CCT-1 as a sensitive neuropsychological test for the detection, in old-old adults, of the differentiation and/or the decline of general abstraction and reasoning acquired during childhood.
Papantoniou, G., Moraitou, D., Dinou, M., Katsadima, E., Savvidou, E., & Foutsitzi, E. (2016). Comparing the Latent Structure of the Children’s Category Test-Level 1 among Young Children and Older Adults: A Preliminary Study. Psychology, 7, 1352-1368. http://dx.doi.org/10.4236/psych.2016.711137