Principles of tissue engineering. / Robert Lanza.

Format:

Book

Contributor:

Lanza, Robert, 1956- editor.

Language:

English

Subjects (All):

Tissue engineering.

Physical Description:

1 online resource

Edition:

5th ed.

Place of Publication:

Waltham, Massachusetts : Elsevier, [2020]

Summary:

Now in its fifth edition, Principles of Tissue Engineering has been the definite resource in the field of tissue engineering for more than a decade.The fifth edition provides an update on this rapidly progressing field, combining the prerequisites for a general understanding of tissue growth and development, the tools and theoretical information.

Contents:

Front Cover

Principles of Tissue Engineering

Copyright Page

Contents

List of contributors

Preface

1 Tissue engineering: current status and future perspectives

Clinical need

Current state of the field

Smart biomaterials

Cell sources

Embryonic stem cells

Induced pluripotent stem cells

Adult stem cells

Whole organ engineering

Biofabrication technologies

Electrospinning

Inkjet three-dimensional bioprinting

Extrusion three-dimensional bioprinting

Spheroids and organoids

Imaging technologies

Tissue neovascularization

Bioreactors

Organ-on-a-chip and body-on-a-chip

Integration of nanotechnology

Current challenges

Future directions

Tissue neovasculatization

Conclusions and future challenges

References

Further reading

2 From mathematical modeling and machine learning to clinical reality

Introduction

Modeling stem cell dynamics

Positive feedback-based molecular switches

Variability in stem cell populations

Modeling tissue growth and development

Monolayer tissue growth in vitro

Tissue growth on complex surfaces in vitro

Three-dimensional tissue growth in vitro

Pattern formation

Machine learning in tissue engineering

Supervised methods

Unsupervised methods

Machine learning of cellular dynamics

Regulatory network inference

From mathematical models to clinical reality

3 Moving into the clinic

Current state of tissue engineering

Pathway for clinical translation

Regulatory considerations for tissue engineering

Conclusion

Acknowledgment

References.

Further reading

One: The basis of growth and differentiation

4 Molecular biology of the cell

The cell nucleus

Control of gene expression

Transcription factors

Other controls of gene activity

The cytoplasm

The cytoskeleton

Microtubules

Microfilaments

Small GTPases

The cell surface

Cell adhesion molecules

Extracellular matrix

Signal transduction

Growth and death

Culture media

Cells in tissues and organs

Cell types

Tissues

Organs

Reference

General

Chromatin

Signaling, general

Cytoskeleton, adhesion molecules and extracellular matrix

5 Molecular organization of cells

Molecules that organize cells

Changes in cell-cell adhesion

Changes in celleextracellular matrix adhesion

Changes in cell polarity and stimulation of cell motility

Invasion of the basal lamina

The epithelial-mesenchymal transition transcriptional program

Transcription factors that regulate epithelial-mesenchymal transition

Regulation at the promoter level

Posttranscriptional regulation of epithelial-mesenchymal transition transcription factors

Molecular control of the epithelial-mesenchymal transition

Ligand-receptor signaling

Growth factor-β pathway

Wnt pathway

Signaling by receptor tyrosine kinase ligands

Notch pathway

Hedgehog pathway

Additional signaling pathways

A model for epithelial-mesenchymal transition induction

List of acronyms and abbreviations

Glossary

6 The dynamics of cell-extracellular matrix interactions, with implications for tissue engineering

Historical background

Extracellular matrix composition

Receptors for extracellular matrix molecules

Cell-extracellular matrix interactions

Development

Adhesion and migration

Proliferation.

Differentiation

Apoptosis

Wound healing

Proliferation

Differentiation

Signal transduction events during cell-extracellular matrix interactions

Relevance for tissue engineering

Avoiding a strong immune response that can cause chronic inflammation and/or rejection

Creating the proper substrate for cell survival and differentiation

Providing the appropriate environmental conditions for tissue maintenance

7 Matrix molecules and their ligands

Collagens

Fibrillar collagens

Fibril-associated collagens with interrupted triple helices (FACIT)

Basement membrane-associated collagens

Other collagens

Major adhesive glycoproteins

Fibronectin

Laminin

Elastic fibers and microfibrils

Other adhesive glycoproteins and multifunctional matricellular proteins

Vitronectin

Thrombospondins

Tenascins

Proteoglycans

Hyaluronan and lecticans

Perlecan

Small leucine-rich repeat proteoglycans and syndecans

8 Morphogenesis and tissue engineering

Introduction to tissue morphogenesis

Biology of tissue morphogenesis

Morphogens as bioactive signaling molecules during morphogenesis

The extracellular matrix as a key regulator of tissue morphogenesis

Cell-cell interactions during tissue morphogenesis

Tissues as integrated systems in the body

Engineering tissue morphogenesis

Cells as building units in tissue engineering

Biomaterial scaffolds as artificial extracellular matrices

Morphogens as signaling cues in tissue engineering

Tissue remodeling in healthy and diseased environments

Current focuses and future challenges

9 Gene expression, cell determination, differentiation, and regeneration

Determination and differentiation.

MyoD and the myogenic regulatory factors

Negative regulators of development

MicroRNAs-regulators of differentiation

Pax in development

Satellite cells in skeletal muscle differentiation and repair

Tissue engineering-repairing muscle and fostering regeneration by controlling determination and differentiation

Two: In vitro control of tissue development

10 Engineering functional tissues: in vitro culture parameters

Key concepts for engineering functional tissues

Fundamental parameters for engineering functional tissues

Fundamental criteria for engineering functional tissues

Importance of in vitro studies for engineering functional tissues

In vitro studies relevant to tissue engineering and regenerative medicine

In vitro platforms relevant for high throughput screening of drugs and other agents

Influence of selected in vitro culture parameters on the development and performance of engineered tissues

Culture duration

Cartilage tissue engineering

Cardiac tissue engineering

Biomaterials

Cartilage tissue-engineering biomaterials

Fiber-reinforced constructs for cartilage repair

Stratified and osteochondral constructs for cartilage repair

Bioinductive and bioactive scaffolds

Cardiac tissue-engineering biomaterials

Bioreactors and growth factors

Cell seeding

Construct cultivation

Cartilage tissue-engineering bioreactors

Cardiac tissue-engineering bioreactors

Bioreactors and mechanical forces

Effects of hydrodynamic forces

Effects of mechanical tension, compression, and shear loading

Mechanical effects on engineered cartilage tissue

Electromechanical effects on engineered myocardium

Acknowledgments

11 Principles of bioreactor design for tissue engineering.

Introduction

Macrobioreactors

Design principles

Mass transport

Physiological biomimicry cues

Cell environment

Sustainable bioreactors

Cell manufacturing quality attributes and process analytics technology

Future outlook

Microgravity bioreactor

Real-time assessment in the bioreactor

Microbioreactors

Flow rheology

Cell microenvironment

Integration of multiple compartments

Types of microreactors

Components and integration into microreactors

Applications

Drug testing and screening

Experimental models of disease

Prognostic/diagnostic tools

Summary

12 Regulation of cell behavior by extracellular proteins

Thrombospondin-1

Thrombospondin-2

Tenascin-C

Osteopontin

Secreted protein acidic and rich in cysteine

13 Cell and matrix dynamics in branching morphogenesis

The basis of branching morphogenesis

Branching morphogenesis in the lung

Branching morphogenesis in the salivary gland

Branching morphogenesis in the kidney

Contributions of other cell types

MicroRNAs in branching morphogenesis

Extracellular matrix components in branching morphogenesis

Collagen

Heparan sulfate proteoglycan

Fibronectin and integrins

Basement membrane microperforations

Mathematical and computational models

Geometry

Mechanical forces

Signaling mechanisms

14 Mechanobiology, tissue development, and tissue engineering

Mechanical forces in biological systems

Tension

Compression

Fluid shear

Cellular mechanosensing

Stretch-activated ion channels

Cell-cell adhesions

Cell-substrate adhesions

The extracellular matrix.

Cellular effects of mechanotransduction.

Notes:

Description based on print version record.

Description based on publisher supplied metadata and other sources.

ISBN:

0-12-821401-5

0-12-818422-1

OCLC:

1148934799