• View the Talks
• 11 min
  1. On the utility of a mechanistic approach to physiology - descriptive vs. mechanistic biology

  • Prof. John S. Torday
• 33 min
  2. On the utility of a mechanistic approach to physiology - the evolutionary origin of endothermy

  • Prof. John S. Torday
• 24 min
  3. A brief history of evolutionary biology

  • Prof. Neil Blackstone
• 26 min
  4. Major transitions in the history of life

  • Prof. Neil Blackstone
• 47 min
  5. On the origins of life

  • Dr. William B. Miller Jr.
• 29 min
  6. The origin of eukaryotes

  • Prof. Neil Blackstone
• 38 min
  7. Trichoplax and the origin of animal complexity

  • Prof. Bernd Schierwater
• 35 min
  8. On the value of comparative physiology

  • Prof. Karen L. Sweazea
• 11 min
  9. How to ‘deconvolute’ lung evolution - vertebrate ontogeny - the ‘short history’ of evolution

  • Prof. John S. Torday
• 25 min
  10. How to ‘deconvolute’ lung evolution - the evolutionary origins of pulmonary physiology

  • Prof. John S. Torday
• 15 min
  11. How to ‘deconvolute’ lung evolution - evolutionary lessons from cell culture

  • Prof. John S. Torday
• 18 min
  12. Using lung evolution as a cipher for physiology - pathophysiology

  • Prof. John S. Torday
• 19 min
  13. The unicellular origins of complex physiology

  • Prof. John S. Torday
• 16 min
  14. Pleiotropy - cellular-molecular evolution in action

  • Prof. John S. Torday
• 16 min
  15. The dynamic interactions between cellular-molecular physiology and the environment - the cellular-molecular approach to evolution as niche construction

  • Prof. John S. Torday
• 10 min
  16. The dynamic interactions between cellular-molecular physiology and the environment - The unicellular state as the level of selection - epigenetics

  • Prof. John S. Torday
• 8 min
  17. The dynamic interactions between cellular-molecular physiology and the environment - case studies in pathophysiology - how to exploit cellular-molecular evolution

  • Prof. John S. Torday
• 5 min
  18. The dynamic interactions between cellular-molecular physiology and the environment - future directions in cellular-molecular evolutionary biology

  • Prof. John S. Torday

Printable Handouts

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Navigable Slide Index

1. Introduction
2. Sterols and membrane fluidity
3. Role of cholesterol in eukaryotic cell membranes
4. Epistatic balance between lipids and calcium
5. Integration of cholesterol in vertebrate evolution
6. The unicellular phenotypes
7. Life cycle and evolution
8. Unicellular organisms
9. Serial functional homologies
10. Surfactant phospholipid lowers surface tension
11. Homologies in skin and lung cell physiology
12. Surface-tension lowering effect of surfactant
13. Chemistry of phosphatidylcholine surface film
14. Effect of temperature on surface activity
15. The subphase of the alveolar lining liquid
16. Photomicrograph of tubular myelin
17. Skin-brain homology
18. Evolution of whole animal physiology
19. The cell as a fractal
20. Fractal (repetition of a self-similar form)
21. The cell as the first fractal of vertebrate evolution
22. Levels of structural organization
23. Fractal physiology & the effects of cholesterol
24. Fractal physiology & vertebrate adaptation to land

Topics Covered

• Cholesterol’s critical role in the evolution of eukaryotes
• Vertical integration of calcium/lipid epistasis throughout vertebrate physiology
• The unicellular perspective: aspects of physiology simplified
• Simplification of physiology: homologies unseen by descriptive physiology
• Physiology as fractal expressions of the unicellular state
• The fractal principle: functional integration of physiology from first principles

Links

Series:

• Evolutionary Physiology

Categories:

• Cell Biology
• Clinical Practice

Talk Citation

Publication History

• Published on November 30, 2016

Financial Disclosures

• Prof. John S. Torday has not informed HSTalks of any commercial/financial relationship that it is appropriate to disclose.