Turing Equation Explains how Leopard Spots Develop

BilZ0r writes "A slight modification of an equation developed by Alan Turing in 1952 has been used to show how the patterns of big cats change from kitten to adult markings. Sy-Sang Liaw of National Chung-Hsing University in Taichung, Taiwan, and colleagues set out to replicate these patterns using Turing's equations. But they found they had to do more than just tweak the parameters of the reaction-diffusion equation. Instead they had to assume two stages of spot growth with different rules: the first to get the baby cats their spots, and the second to create the final configurations. It took them a year to find a final solution."

Link to article?

[pacc]

As interesting as the link may be it does not mention any of the new findings in the header.

Re:Tweaking parameters...

[QuantumFTL]

These types of nonlinear differential equations are usually very simple in form, and, most importantly, very local, as that is how most biological interaction is mediated. The parameter tweaking should not be considered too alarming when one considers that the number of biological parameters, in the sense of genetic material, involves thousands of degrees of freedom.

A short (but good) web site about this can be found here. The interpretation of these formulas is fairly trivial, as they describe a diffusion process (common in all biological systems) with a somewhat more complex reactive process, which could be mediated through all kinds of channels.

This is not akin to fitting a polynomial to the shape of a bone and calling that a "model" - there are obvious interpretations which correspond to very well known processes.

Sounds like

[Black+Parrot]

cellular automata.

Re:Sounds like

[VoidEngineer]

cellular automata.

Actually, it's the precursor to cellular autonoma. There's a period of Alan Turrings life, that most people don't study and know about, which involves him studying a number of biological models. His 1952 paper 'On the Chemical Basis of Biological Morphogenesis' contains the foundations of what Wolfram would later go on and call 'cellular autonoma'. Go check it out, and form your own opinion. Having read both Wolfram and Turing, I have to give clear credit to Turing for coming up with the idea of cellular autonoma before Wolfram. That being said, Turing appears to have been interested in it and studying those concepts from a particularly oblique angle than how Wolfram approached them. Wolfram certainly went off and made a study of cellular autonoma unto itself. But Turing came up with the models before Wolfram; Turing just didn't call them 'cellular autonoma' and perhaps didn't view them quite as generically as Wolfram envisioned them.

This is no big deal

[crush]

Since at least 1989 (with Dictyostelium) developmental and evolutionary biologists have used Turing's mechanism to explain pattern formation. Good site here

Re:The point is, you never know.

[Kj0n]

Come on!

Everyone knows that Velcro was a Vulcan invention.

Re:Extracting Sunlight from Cucumbers

[wambaugh]

Considering that reaction-diffusion equations are thought describe (among many, many other things) the propagation of electric waves in the heart, I'd say research understanding the patterns they form is highly worthwhile even if you have no intellectual curiousity whatsoever.

Turing's Paper

[SirClicksalot]

For those of you that don't know what this is about:

This isn't related to Turing's work on early computer science, but concerns research he did shortly before his death.
Turing proposed that under certain conditions diffusion can destabilize a chemical system and cause spatial patterns.

His original paper on the subject can be found at the Turing Archive.

Mathematical biologists have been using these equations to model biological pattern formation for some time. If you want to read up on it, try googling for research by Gierer and Meinhardt on pattern formation

Re:The point is, you never know.

[Elemenope]

anyhow, i believe you ment bread mold, not orange mold.

Penicillium is a genus of what are called 'bread molds' which grow, eponymously, on most yeasted breads. However, they also have a strong affinity for orange rind, and oranges make a nearly ideal culture medium for its growth. Penicillin's antibacteriological properties were discovered in a lab when an orange was accidentally exposed to penicillium and then left in contact with a bacteria culture. Hence, for the story about serendipity and science, its affinity for oranges was more pertinent. Oddly enough, this genus provdes us with some of the molds that make some of the tastiest cheese around (esp. Gorgonzola).

i know the best place to store rubber, place it skin tight on hot girls :D

I, too, like rubber and girls. ;)

In this case, it is a Turing Space

[RidiculousPie]

A Turing Space rather than a Turing machine. Turing was an excellent mathematician, and although currently most famous for his ideas on computation and the Halting Problem, this was a seperate area of research.

This area of study (colourations on animals) is based on Reaction Diffusion Equations, of which a canonical example is the Belousov-Zhabotinskii equation derived from a chemical experiment, and a simpler one is the Heat Equation. These take the form of partial differential equations.

As to simulations of the world or parts on a computer, there is the problem of Heisenberg's Uncertainty Principle, meaning you can never form a complete 'image' of any part of the world.

Re:This should be added to nethack

[bmo]

Modded troll? Ahahaha, I have metamoderation! Moderator gets spanking!

This _should_ be seriously added to NH.

--
BMO