scholarly article | Q13442814 |
P8978 | DBLP publication ID | journals/bc/SimpsonG11 |
P356 | DOI | 10.1007/S00422-011-0417-Y |
P698 | PubMed publication ID | 21340602 |
P894 | zbMATH Open document ID | 1232.92040 |
P50 | author | Geoffrey J Goodhill | Q58827396 |
P2093 | author name string | Hugh D Simpson | |
P2860 | cites work | CHEMOAFFINITY IN THE ORDERLY GROWTH OF NERVE FIBER PATTERNS AND CONNECTIONS | Q24646898 |
A stochastic model for retinocollicular map development | Q24795420 | ||
Multiple roles of EPH receptors and ephrins in neural development | Q28205325 | ||
A link between axon guidance and axon fasciculation suggested by studies of the tyrosine kinase receptor EphA5/REK7 and its ligand ephrin-A5/AL-1 | Q28250426 | ||
Complementary gradients in expression and binding of ELF-1 and Mek4 in development of the topographic retinotectal projection map | Q28295221 | ||
Opposing gradients of ephrin-As and EphA7 in the superior colliculus are essential for topographic mapping in the mammalian visual system | Q28591937 | ||
Eph receptor signalling casts a wide net on cell behaviour | Q29619988 | ||
Formation of Topographic Maps | Q30047586 | ||
Pathfinding in a large vertebrate axon tract: isotypic interactions guide retinotectal axons at multiple choice points | Q30483950 | ||
A multi-component model of the developing retinocollicular pathway incorporating axonal and synaptic growth | Q30491857 | ||
Retinotectal maps: molecules, models and misplaced data. | Q30583491 | ||
Retinotopic order in the absence of axon competition. | Q33910484 | ||
A relative signalling model for the formation of a topographic neural map. | Q33982342 | ||
In vitro guidance of retinal ganglion cell axons by RAGS, a 25 kDa tectal protein related to ligands for Eph receptor tyrosine kinases | Q34058301 | ||
Activity-dependent mapping in the retinotectal projection | Q34542042 | ||
Insights into activity-dependent map formation from the retinotectal system: a middle-of-the-brain perspective | Q35685291 | ||
Molecular gradients and development of retinotopic maps | Q36196543 | ||
The development of retinotectal maps: a review of models based on molecular gradients. | Q36341388 | ||
Fish E587 glycoprotein, a member of the L1 family of cell adhesion molecules, participates in axonal fasciculation and the age-related order of ganglion cell axons in the goldfish retina | Q36382618 | ||
Theoretical models of neural circuit development. | Q37475582 | ||
Key roles of Ephs and ephrins in retinotectal topographic map formation. | Q37500760 | ||
Competitive and positional cues in the patterning of nerve connections | Q37910454 | ||
A marker induction mechanism for the establishment of ordered neural mappings: its application to the retinotectal problem | Q39284422 | ||
Computational modeling of retinotopic map development to define contributions of EphA-ephrinA gradients, axon-axon interactions, and patterned activity | Q40526435 | ||
Retinal axon response to ephrin-as shows a graded, concentration-dependent transition from growth promotion to inhibition | Q40548457 | ||
Topographically specific effects of ELF-1 on retinal axon guidance in vitro and retinal axon mapping in vivo | Q41168628 | ||
Topographic maps are fundamental to sensory processing | Q41590693 | ||
Topographic mapping from the retina to the midbrain is controlled by relative but not absolute levels of EphA receptor signaling | Q41752889 | ||
Expansion of the half retinal projection to the tectum in goldfish: An electrophysiological and Anatomical study | Q44657897 | ||
Development and regeneration of the retinotectal map in goldfish: a computational study | Q45804978 | ||
Normal and regenerating optic fibers in goldfish tectum: HRP-EM evidence for rapid synaptogenesis and optic fiber-fiber affinity | Q46076885 | ||
Trajectories of regenerating retinal axons in the goldfish tectum: II. Exploratory branches and growth cones on axons at early regeneration stages | Q48133629 | ||
The topographic brain: from neural connectivity to cognition | Q48187133 | ||
Progress of topographic regulation of the visual projection in the halved optic tectum of adult goldfish | Q48384165 | ||
A unifying model for activity-dependent and activity-independent mechanisms predicts complete structure of topographic maps in ephrin-A deficient mice | Q48477874 | ||
Analysis of mouse EphA knockins and knockouts suggests that retinal axons programme target cells to form ordered retinotopic maps | Q48496790 | ||
Retention of the original topographic polarity by the 180 degrees rotated tectal reimplant in young adult goldfish | Q48634968 | ||
The visual system and "neuronal specificity". | Q48752646 | ||
The extended branch-arrow model of the formation of retino-tectal connections | Q49027047 | ||
Genetic analysis of ephrin-A2 and ephrin-A5 shows their requirement in multiple aspects of retinocollicular mapping. | Q52169064 | ||
P433 | issue | 1-2 | |
P6104 | maintained by WikiProject | WikiProject Mathematics | Q8487137 |
P304 | page(s) | 9-29 | |
P577 | publication date | 2011-02-22 | |
P1433 | published in | Biological Cybernetics | Q15766256 |
P1476 | title | A simple model can unify a broad range of phenomena in retinotectal map development | |
P478 | volume | 104 |
Q48308512 | A quantitative analysis of branching, growth cone turning, and directed growth in zebrafish retinotectal axon guidance |
Q26859773 | A role for correlated spontaneous activity in the assembly of neural circuits |
Q42029492 | Genetic dissection of EphA receptor signaling dynamics during retinotopic mapping |
Q100389560 | New insights on the modeling of the molecular mechanisms underlying neural maps alignment in the midbrain |
Q34796415 | On the Importance of Countergradients for the Development of Retinotopy: Insights from a Generalised Gierer Model. |
Q41161872 | Quantitative assessment of computational models for retinotopic map formation |
Q36677781 | Regulation of ephrin-A expression in compressed retinocollicular maps |
Q38130721 | Retinocollicular mapping explained? |
Q57491095 | Theoretical Models of Neural Development |
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