Improving fraction understanding in sixth graders with mathematics difficulties: Effects of a number line approach combined with cognitive learning strategies.

Barbieri, Christina; Rodrigues, Jessica; Dyson, Nancy; Jordan, Nancy C.

doi:10.1037/edu0000384

Cited by 57 publications

(53 citation statements)

References 98 publications

(140 reference statements)

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“…Similar to previous studies applying NLE training to children, we expected the training to improve participants' conceptual knowledge of fraction magnitude on a behavioral level [20,21]. In particular, we expected significant improvements in NLE performance over the fiveday training sessions.…”

Section: The Present Studysupporting

confidence: 64%

“…The aim of the present study was to investigate potential neuro-functional changes of brain activation in adult participants through a five-day consecutive NLE training on fraction magnitude. While there already exist a number of studies indicating the effectiveness of NLE training on the behavioral level [20][21][22]60] and some few studies investigating the neural correlates of fraction and proportion processing [41,42,44,45], little is still known about the neural correlates of fraction learning.…”

Section: Discussionmentioning

confidence: 99%

“…Moreover, Barbieri and colleagues [21] used a number line-based intervention to improve fraction understanding in children with poor conceptual knowledge of fractions and compared the number line intervention group to a standard mathematics curriculum group. The number line intervention group showed significantly larger learning gains than the control group.…”

Section: Number Line Estimation As Predictor For Fraction Magnitude Lmentioning

confidence: 99%

See 2 more Smart Citations

Neurofunctional plasticity in fraction learning: An fMRI training study

Wortha

Bloechle

Ninaus

et al. 2020

Trends in Neuroscience and Education

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Background: Fractions are known to be difficult for children and adults. Behavioral studies suggest that magnitude processing of fractions can be improved via number line estimation (NLE) trainings, but little is known about the neural correlates of fraction learning. Method: To examine the neuro-cognitive foundations of fraction learning, behavioral performance and neural correlates were measured before and after a five-day NLE training. Results: In all evaluation tasks behavioral performance increased after training. We observed a fronto-parietal network associated with number magnitude processing to be recruited in all tasks as indicated by a numerical distance effect. For symbolic fractions, the distance effect on intraparietal activation was only observed after training. Conclusion: The absence of a distance effect of symbolic fractions before the training could indicate an initially less automatic access to their overall magnitude. NLE training facilitates processing of overall fraction magnitude as indicated by the distance effect in neural activation.

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Section: The Present Studysupporting

confidence: 64%

Section: Discussionmentioning

confidence: 99%

Section: Number Line Estimation As Predictor For Fraction Magnitude Lmentioning

confidence: 99%

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Neurofunctional plasticity in fraction learning: An fMRI training study

Wortha

Bloechle

Ninaus

et al. 2020

Trends in Neuroscience and Education

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“…Importantly, math-specific language is a necessary skill that supports connecting fraction symbols and fraction representations. Students in grades 4 and 6 were compared because previous research has shown that this is a critical time period for students to consolidate their fraction knowledge (Barbieri et al, 2019;Hansen et al, 2017;Jordan et al, 2017). In addition, the students in the present research were first taught fraction symbols in grade 4; by grade 6, students were expected to have had a reasonable amount of practice using fraction symbols and thus their fraction knowledge should be more advanced.…”

Section: The Current Researchmentioning

confidence: 99%

Fraction Symbols and their Relation to Conceptual Knowledge

Douglas¹

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“…Yet, if prior knowledge or the capabilities and motivation to integrate new knowledge into existing knowledge structures are lacking, these cognitively activating instructional methods are unlikely to produce significant knowledge gains [ 22 ]. Instruction involving representational gestures, physical movement, and systematic feedback, for instance, has proven effective in sixth graders with mathematics difficulties [ 29 ]. Students with non-beneficial cognitive potential—i.e., with low content-specific and strategic prior knowledge, motivation, or less developed reasoning abilities—seem to particularly profit from tablet-based mathematics instruction featuring animations, adaptive tasks, and guidance during practice [ 22 , 30 ].…”

Section: Introductionmentioning

confidence: 99%

Digital support principles for sustained mathematics learning in disadvantaged students

Reinhold

Hofer²,

Hoch

et al. 2020

PLoS ONE

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This study addresses the pressing issue of how to raise the performance of disadvantaged students in mathematics. We combined established findings on effective instruction with emerging research addressing the specific needs of disadvantaged students. A sample of N = 260 disadvantaged 6th-graders received 4 weeks (15 lessons) of fraction instruction either as usual or evidence-based instruction, with and without digital learning support (i.e., interactivity, adaptivity, and immediate explanatory feedback). To examine the sustainability of effects, we assessed students’ fraction knowledge immediately after the 4 weeks and once again after a period of additional 8 weeks. Generalized linear mixed models revealed that students only benefitted from evidence-based instruction if digital support was available in addition. Digital support principles implemented in evidence-based instruction helped disadvantaged students to acquire mathematics knowledge—and to maintain this knowledge.

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Improving fraction understanding in sixth graders with mathematics difficulties: Effects of a number line approach combined with cognitive learning strategies.

Cited by 57 publications

References 98 publications

Neurofunctional plasticity in fraction learning: An fMRI training study

Neurofunctional plasticity in fraction learning: An fMRI training study

Fraction Symbols and their Relation to Conceptual Knowledge

Digital support principles for sustained mathematics learning in disadvantaged students

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