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9780471984511

On Growth and Form Spatio-temporal Pattern Formation in Biology

by ; ;
  • ISBN13:

    9780471984511

  • ISBN10:

    0471984515

  • Edition: 1st
  • Format: Hardcover
  • Copyright: 2000-01-04
  • Publisher: WILEY
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Summary

Spatio-temporal pattern formation is a major area of research within the subject of mathematical biology. The topic involves the use of mathematical modelling to analyse how patterns in biology are created and develop. For example, the growth, over time, of the intricate and beautiful patterns on certain sea-shells or the striped markings on a tiger can be modelled and their development predicted in terms of nonlinear mathematical processes. The current volume captures the breadth of recent research into various aspects of spatio-temporal pattern and form, such as development biology, reaction-diffusion systems and morphometrics. Brings the ideas of the classic On Growth and Form by D'Arcy Thompson, the founding classic of mathematical biology, fully up to date and looks to future developments in the subject. * Foreword provided by Professor John Tyler Bonner, Princeton University. * World class collection of internationally renowned contributors from both experimental and theoretical backgrounds Taking its inspiration from D'Arcy Thompson's classic and still influential volume On Growth and Form, this new volume presents a collection of 21 articles from the Plenary Speakers of the recent D'Arcy Thompson Conference, held at the University of Dundee, 20-24 September 1998. The topics covered include pattern formation in development biology, reaction-diffusion systems, intercellular systems and morphometrics, offering the reader a stimulating blend of theory and experiment. This book will be of particular interest to bio-mathematicians and development biologists. Paediatric clinicians, evolutionary biologists, orthodontists, anatomists, physiologists and many other members of the biology community will also benefit greatly from it.

Author Biography

M.A.J. Chaplain is Co-Chief Editor, Journal of Theoretical Biology and works with the School of Mathematics and Statistics, University of St Andrews, St Andrews, Scotland. He received his PhD in Applied Mathematics from the University of Dundee in 1990, and then took up a lectureship position at the University of Bath.

Table of Contents

Foreword xvii
Series Preface xix
Editors' Preface xxi
Problems of Development: The Microcosm and the Macrocosm
1(12)
Introduction: The Problem of Regional Specification Is Largely Solved
1(1)
Morphogenetic Movements
2(1)
The French Flag Problem
3(1)
Regeneration
4(1)
Size and Proportion
5(3)
Stochastic Character of Cell Differentiation
8(5)
References
11(2)
Development of the Vertebrate Limb: A Model for Growth and Patterning
13(18)
Introduction
13(1)
Chick Wing Development
14(1)
Growth and Shaping of the Limb Bud
14(4)
Tissue Patterning
18(6)
Anteroposterior patterning
18(3)
Proximodistal patterning
21(1)
Dorsoventral patterning
22(2)
Coordination of Signalling and Responses
24(1)
Other signalling interactions
25(1)
Tissue Arrangements Including Musculature
25(6)
References
26(5)
Pattern Formation on Butterfly Wings
31(16)
Introduction
31(1)
The Diversity of Colour Patterns
32(2)
The Development of Pattern Elements: Surgical Manipulation
34(3)
Eyespots: Foci, Gradients and Gene Expression
37(3)
The Development of Wing Patterns: Mechanisms and Models
40(3)
Conclusion
43(4)
References
44(3)
Pattern Formation in Cancer
47(28)
Introduction
47(1)
Tumour Encapsulation
48(9)
Formulation of the model
49(1)
Connective tissue waves
50(6)
Extension to model transcapsular spread
56(1)
Macrophage Induction of Tumour Heterogeneity
57(18)
Model development
59(3)
Spatially independent solutions
62(1)
Wave front solutions and spatial patterns
63(5)
Numerical simulations in two dimensions
68(1)
Summary of model predictions
69(1)
References
70(5)
Turing Structures of the Second Kind
75(14)
Introduction
75(1)
Pattern Formation in Reaction-Diffusion Systems
76(3)
Slowing Down the Effective Diffusion of the Self-activator
79(1)
Turing Patterns of the Second Kind
80(1)
Size Regulation of Pattern Forming Processes
81(1)
Pair-rule Patterns in Drosophila
81(2)
Clocks and Patterns from the Same Mechanism
83(2)
Conclusion
85(1)
Numerical Treatment of 3D Pattern Formation
85(4)
References
87(2)
Pattern Formation Mechanisms in Skin and Hair: Some Experimental Tests
89(22)
Introduction
89(2)
Follicles Initiation and Development
91(7)
Equidistant follicles
91(1)
Increasing density of follicles
92(1)
Spatial patterns in follicle location
93(1)
Spatial patterns produced by an RD system
94(4)
Experiments on Follicle Initiation
98(4)
Skin stretching
98(2)
Follicle density and follicle diameter
100(1)
The sweat gland and the trio group
100(1)
Patterns of mitotic activity
101(1)
Fibre Formation
102(3)
Concentric patterns of cell type
102(1)
Non-concentric patterns
102(3)
Experiments on Fibre Formation
105(3)
The relationship between pattern and follicle bulb size
105(2)
Change of pattern within a fibre
107(1)
Conclusion
108(3)
References
109(2)
Some Mathematical Models for Biological Pattern Formation
111(18)
Introduction
111(1)
Simple Models
112(4)
Chemical prepattern models
112(2)
Cell movement models
114(1)
Applications
115(1)
Coupled Models
116(4)
Feather germ formation
116(1)
Cell aggregation in slime mould
117(3)
The Role of Domain Growth
120(3)
Alligator tooth primordia
120(2)
Pigmentation patterning in fishes
122(1)
Discussion and Future Directions
123(6)
References
125(4)
On Pattern and Growth
129(20)
Introduction
129(1)
The Generation of Organizing Regions by Local Self-enhancement and Long-Range Inhibition
130(5)
Regular and Irregular Periodic Patterns
135(1)
The Wavelength Problem: Stabilization of a Monotonic Gradient by a Feedback on the Source Density
135(2)
Space-dependent Activation of Genes by a Morphogen
137(3)
Somite Formation: Sequential Conversion of a Periodic Pattern in Time into a Periodic Pattern in Space
140(2)
Patterns on Shells of Tropical Molluscs
142(2)
Formation of crossings by an additional diffusible inhibitor
143(1)
Arrangement of Leaves and Staggered Dots on Shells: Two Corresponding Patterns
144(2)
Conclusion
146(3)
References
146(3)
Diversity in Pattern and Form of Biological Systems and Evolution: A Theoretical Approach
149(8)
Introduction
149(1)
Possible Factors in Determining Pattern and Form
150(2)
Gene activity
150(1)
Physico-chemical aspect
150(1)
Ecological aspect
151(1)
Biological function
151(1)
Pioneering Work
152(1)
Shell shape
152(1)
Plant evolution
152(1)
Animal skin and insect wing
153(1)
Summary and Conclusion
153(4)
References
154(3)
Developmental Morphologies Not Directly Specified by the Genome of the Individual
157(16)
Introduction
157(2)
Physical and Mathematical Constraints
159(1)
Morphologies Arising from Non-genetic Mechanisms of Inheritance
160(1)
Environmental Specification
161(1)
Self-establishing Interactive Mechanisms
162(2)
Parental Specification
164(1)
Tissue Self-assembly
164(1)
Tissue Interaction
165(1)
Specification by Use
166(1)
Conclusions
167(6)
References
169(4)
The Role of Chemotactic Cell Movement in Dictyostelium Morphogenesis
173(28)
Introduction
173(2)
Cell Type Differentiation
175(1)
Aggregation
176(4)
Formation of Aggregation Streams
180(1)
Mounds
180(2)
Cell Movement in Slugs
182(3)
Is cAMP the Signal That Controls Cell Movement in the Slug?
185(1)
Other Possible Mechanisms Controlling Cell Movement in Slugs
185(1)
How Do the Cells in the Multicellular Stages of Development Get Their Traction?
186(1)
The Mechanism of Cell Sorting
187(1)
Culmination
188(1)
Modelling Morphogenesis
188(6)
Aggregation
189(2)
Mound formation
191(1)
Cell sorting and slug formation
191(3)
Slug migration
194(1)
Conclusion and Outlook
194(7)
References
195(6)
Angiogenesis: Experimental Data Relevant to Theoretical Analysis
201(24)
Introduction
201(1)
Vascular and Perivascular Cells Involved in Angiogenesis
202(2)
Phenotypic Heterogeneity and Lineage Relationships Amongst Vascular Cells
204(2)
Angiogenesis: A Morphogenetic process
206(3)
In Vitro Models to Study Angiogenesis: Interactions between Cytokines and Extracellular Matrix Macromolecules
209(9)
Conclusions
218(7)
References
220(5)
Modelling the Growth and Form of Capillary Networks
225(26)
Introduction
225(1)
Tumour-Induced Angiogenesis
226(2)
Mathematical Modelling of Tumour-Induced Angiogenesis
228(1)
The Continuous Mathematical Model
229(4)
Model Results
233(3)
The Discrete Mathematical Model
236(5)
Branching and anastomosis
238(1)
Cell proliferation
239(1)
Simulation process for the discrete model
239(1)
Discrete model simulation results
240(1)
Three-Dimensional Simulations
241(3)
3D Simulation Results
243(1)
Discussion and Conclusions
244(7)
References
246(5)
On the Mechanochemical Theory of Biological Pattern Formation with Applications to Wound Healing and Angiogenesis
251(36)
Introduction and Biological Background
251(4)
Theories of morphogenesis
252(3)
Mechanochemical Theory Framework
255(6)
Cell density conservation
256(2)
Conservation of matrix density
258(1)
Mechanical interaction of cell and matrix
258(3)
Model analysis
261(1)
Wound Healing
261(9)
Biological background and motivation
262(2)
Mechanochemical modeling of wound healing
264(6)
Vascular Network Formation: Angiogenesis
270(9)
Biological background and motivation
270(1)
Cell-extracellular matrix interactions for vasculogenesis
271(1)
Mechanical theory of in vitro vascular network formation
271(1)
Mathematical model
272(3)
Parameter values
275(1)
Results from the model analysis
276(2)
Results from the model mechanism
278(1)
Discussion
279(8)
References
281(6)
Statistics and Dynamics of Cellular Shape Changes
287(22)
Introduction
287(1)
Examples of Cellular Shape Changes
288(5)
Tip growth of hyphae
288(1)
Deformations of red blood cells
289(1)
Cleavage of a sand dollar egg
289(1)
Amoeboid motion
290(3)
Descriptors of Form in 2D
293(11)
Geometric shape factors
294(1)
Invariant 2D moments
295(3)
Fourier and Kahunen--Loeve expansions
298(2)
Angular-temporal autocorrelations
300(3)
Protrusion-retraction dynamics
303(1)
Discussion: Current and Future Tasks
304(5)
References
305(4)
Shape Asymmetry and Developmental Stability
309(16)
Introduction
309(1)
Nature of Asymmetries
310(1)
Nature of Characters
311(1)
Developmental Stability and Canalisation
312(2)
Shape Asymmetry
314(6)
Towards the Form Asymmetry
320(5)
References
322(3)
Invariance and Morphometrics: A Critical Appraisal of Statistical Techniques for Landmark Data
325(12)
Introduction
325(1)
Limiting Factors: Three Major Classes
326(1)
Comparison of Related Forms
327(6)
Superimposition approaches
328(1)
Transformation grid or deformation approach
329(2)
Orbits of equivalent forms
331(1)
Euclidean distance matrix analysis (EDMA)
332(1)
Non-Invariant Descriptors and Scientific Consequences
333(2)
Conclusions and Future Directions
335(2)
References
335(2)
Statistical Shape Analysis and its Applications
337(20)
Introduction
337(1)
Examples
338(1)
Bookstein Shape Coordinates
338(3)
Kendall's Shape Space and Procrustes Coordinates
341(4)
Shape Change and Deformations
345(2)
Models and Concentrated Data
347(2)
Different Approaches
349(3)
Future Perspectives
352(5)
References
353(4)
Sphenothemoidal Growth, Malgrowth, and Midfacial Profile
357(16)
Introduction
357(2)
Computerized Reconstruction of the Murine Cranial Base
359(3)
Thompsonian Grid Transformation Analysis Using Finite Element Methods
362(1)
Localizing Anatomical Form Change in the Cranial Base of Normal and Br mice
363(2)
Regionalization of Cellular Growth Activity in the Br Cranial Base
365(2)
Discussion
367(6)
References
370(3)
Ontogeny and Phylogeny: Some Morphometric Approaches to Skeletal Growth and Evolution
373(22)
Introduction
373(2)
What Can We Learn of Form Variations Using the Morphometric Toolkit?
375(3)
Motivation
375(3)
Localisation and Characterisation of Form Differences
378(1)
Shape Spaces for Registered Landmarks
378(2)
Shape Space for Interlandmark Distances
380(1)
Deformations
381(1)
Morphometrics: Models, Assumptions and Biology
382(1)
Example Studies
382(8)
Growth of the face in Cercocebus torquatus
383(4)
Comparative growth; Cercocebus torquatus vs Cebus apella
387(3)
Concluding Remarks
390(5)
References
391(4)
D'Arcy Thompson and the Problem of Biological Form
395(8)
Introduction
395(1)
Historical Narratives and Scientific Explanations
395(3)
A Generative Biology: Morphogenetic Fields
398(1)
Genetic Networks, Morphogenesis and Evolution
399(4)
References
401(2)
Index 403

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