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Organ regeneration based on developmental biology / edited by Takashi Tsuji, editor.

Tsuji, Takashi, editor.
2017
R857.T55
Available Online
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Title
Organ regeneration based on developmental biology / edited by Takashi Tsuji, editor.
ISBN
9789811037689 (electronic book)
981103768X (electronic book)
9789811037665
9811037663
DOI
https://doi.org/10.1007/978-981-10-3768-9
Published
Singapore : Springer, 2017.
Language
English
Description
1 online resource (xiii, 257 pages) : illustrations.
Item Number
10.1007/978-981-10-3768-9 doi
Call Number
R857.T55
Dewey Decimal Classification
610.28
Summary
This book reviews three-dimensional (3D) stem cell culture and proof of concept for organ regeneration. The chapters present studies based on developmental biology but not tissue engineering using bio-degradative scaffolds. The ultimate goal of regenerative therapy, the next generation of regenerative therapy, is to develop fully functioning bioengineered 3D organs that can replace lost or damaged organs following disease, injury, or aging. Next-generation regenerative therapy will consist of organ-replacement regenerative therapy, which aims to reproduce reciprocal epithelial and epithelial interactions and epithelial and mesenchymal interactions that occur during embryogenesis. The book then discusses the generation of several 3D functional organs and organoids such as brain, inner ear, tooth, hair, salivary glands, lacrimal glands, gastrointestinal organs, kidney, liver, and lung. This work will appeal to a wide readership such as medical scientists, developmental biologists, clinicians, and patients. The volume provides valuable information and ideas to form a next-generation field of science.
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Access limited to authorized users.
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text file PDF
Source of Description
Online resource; title from PDF title page (SpringerLink, viewed April 7, 2017).
Added Author
Tsuji, Takashi, editor.
Available in Other Form
Organ regeneration based on developmental biology.
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Dedication; Preface; Contents; List of Contributors; Chapter 1: Telencephalic Tissue Formation inß3D Stem Cell Culture; 1.1 Introduction; 1.2 The Cerebral Cortex; 1.2.1 Development ofßtheßCerebral Cortex InßVivo; 1.2.2 3D Cortical Tissue Generation InßVitro; 1.3 Ventralizing Telencephalic Tissues; 1.3.1 Development ofßtheßVentral Telencephalon InßVivo; 1.3.2 Development ofßtheßVentral Telencephalon InßVitro; 1.4 Dorsalizing Telencephalic Tissues; 1.4.1 Development ofßDorsomedial Telencephalic Structure InßVivo; 1.4.2 Generation ofßDorsomedial Telencephalic Tissues InßVitro.

1.5 Closing Remarks andßFuture PerspectiveReferences; Chapter 2: Self-Organized Cerebellar Tissue fromßHuman Pluripotent Stem Cells andßIts Application toßClinical Medicine; 2.1 Introduction; 2.2 Self-Organization ofßCerebellar Tissue fromßhPSCs inß3D Culture; 2.2.1 Development ofßMammalian Cerebellum; 2.2.2 Attempt toßGenerate Cerebellar Neurons fromßPSCs; 2.2.3 Self-Induction ofßCerebellar Neurons fromßhPSCs; 2.2.4 Self-Formation ofßPolarized Cerebellar Structure; 2.3 Construction ofßHuman Cerebellar Disease Models withßPatient-Derived iPSCs; 2.4 Conclusion; References.

Chapter 3: Functional Pituitary Tissue Formation Recapitulating Hypothalamus andßPituitary Development Using ES/iPS Cells3.1 Introduction; 3.2 A Need forßHypothalamus andßAdenohypophysis Regenerative Medicine; 3.3 Mouse Embryonic Stem Cells; 3.4 Pituitary Gland Embryology; 3.5 Three-Dimensional ES Cell Culture; 3.6 Induction ofßHypothalamic Neurons fromßMouse ES Cells; 3.7 Two-Layer Formation InßVitro Is theßFirst Step ofßAdenohypophysis Differentiation; 3.8 Self-Formation ofßRathke's Pouch; 3.9 Differentiation into Hormone-Producing Endocrine Cells; 3.10 Functionality ofßInduced ACTH+ Cells.

3.11 Effect ofßTransplantation intoßHypophysectomized Model Animals3.12 Adaptation toßHuman ES/iPS Cell Culture; 3.13 Future Perspectives; References; Chapter 4: Inner Ear Organoids: Recapitulating Inner Ear Development inß3D Culture; 4.1 Introduction; 4.2 Inner Ear Development; 4.2.1 Formation ofßtheßPreplacodal Region; 4.2.2 Formation ofßtheßOtic Epibranchial Placode Domain; 4.2.3 Formation ofßtheßOtic Placode; 4.3 Generation ofßInner Ear Organoids; 4.3.1 Formation ofßNonneural Ectoderm (NNE); 4.3.2 Formation ofßtheßPreplacodal Region (PPR); 4.3.3 Formation ofßtheßOtic Placode.

4.3.4 Self-Guided Differentiation toßtheßInner Ear Sensory Epithelium4.3.5 Morphologic andßFunctional Analysis ofßInner Ear Sensory Epithelia; 4.4 Potential Applications andßLimitations; References; Chapter 5: Functional Tooth Regeneration; 5.1 Introduction; 5.2 Tooth Organogenesis; 5.3 Tissue Repair andßEngineering byßUsing Dental Tissue-ƯDerived Stem Cells andßCytokines; 5.3.1 Stem-Cell Therapy; 5.3.1.1 Dentin-Pulp Tissue Repair; 5.3.1.2 Periodontal Tissue Repair; 5.3.2 Cytokine Approach; 5.3.3 Bioengineered Root Regeneration byßTissue Engineering Technology.

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