How do we store information in the brain? Is memory a thing in a place, like a specific molecule in a particular cell? Or does learning require a process in a population, like neurons firing in a specific pattern for each experience? This combination of memoir and history tells the story of how the mechanisms of memory were gradually revealed, through biographical vignettes of the scientists who set out to solve the riddle of memory, including the author’s own efforts as he was coming of age as a scientist. It shows how individual goals intertwine with the technologies at hand to push scientific knowledge forward, often erratically, and always in the context of social forces and private ups and downs. Not only a compelling personal story with the war in Vietnam, civil rights movement, and downfall of two presidents as backdrop, this is a lucid explanation of brain function for the nonscientist and valuable contribution to the history of science in the decades that saw neuroscience join molecular biology as the marquee biomedical accomplishments of the twentieth century
This book chronicles the apparent discovery of “memory molecules” in 1965, the loss of credibility that plagued those findings, and the subsequent triumphant discovery of the neuroactive peptides, including endorphins. The story is told through a series of biographical vignettes and the author’s own experiences that unfolded from the plains of West Texas, through Kansas, Houston, New York, Detroit, and Boston. This seminal episode in the early history of neuroscience flows smoothly for the lay reader as an engaging story of the clash between personalities, conventional wisdom, and unconventional explanations. The book is well documented for the scientist and historian, providing a definitive account of early attempts to understand memory at the molecular level.
In Cosmic Biology, Louis Irwin and Dirk Schulze-Makuch guide readers through the range of planetary habitats found in our Solar System and those likely to be found throughout the universe. Based on our current knowledge of chemistry, energy, and evolutionary tendencies, the authors envision a variety of possible life forms. These range from the familiar species found on Earth to increasingly exotic examples possible under the different conditions of other planets and their satellites. Discussions of the great variety of life forms that could evolve in these diverse environments have become particularly relevant in recent years with the discovery of around 300 exoplanets in orbit around other stars and the possibilities for the existence of life in these planetary systems. The book also posits a taxonomic classification of the various forms of life that might be found, including speculation on the relative abundance of different forms and the generic fate of living systems. The fate and future of life on Earth will also be considered. The closing passages address the Fermi Paradox, and conclude with philosophical reflections on the possible place of Homo sapiens in the potentially vast stream of life across the galaxies.
Examines each of these parameters in crucial depth and makes the argument that life forms we would recognize may be more common in our solar system than many assume. Considers exotic forms of life that would not have to rely on carbon as the basic chemical element, solar energy as the main energy source, or water as the primary solvent and the question of detecting bio- and geosignatures of such life forms, ranging from earth environments to deep space. Seeks an operational definition of life and investigate the realm of possibilities that nature offers to realize this very special state of matter. Avoids scientific jargon wherever possible to make this intrinsically interdisciplinary subject understandable to a broad range of readers.
The Evolutionary Imperative provides a unifying perspective on the evolution of the universe in all its physical and biological detail, with a call to action for redirecting the evolutionary trajectory of human society. The book’s thesis is that change is inevitable, driven by resolution of energy gradients through the Principle of Least Action and the Second Law of Thermodynamics. This energy dissipation model of the evolutionary imperative accounts for all the organization of matter and energy that has ever come about, and offers a transcendent view of the world, and the place and fate of the human species within it.
Examines each of these parameters in crucial depth and makes the argument that life forms we would recognize may be more common in our solar system than many assume. Considers exotic forms of life that would not have to rely on carbon as the basic chemical element, solar energy as the main energy source, or water as the primary solvent and the question of detecting bio- and geosignatures of such life forms, ranging from earth environments to deep space. Seeks an operational definition of life and investigate the realm of possibilities that nature offers to realize this very special state of matter. Avoids scientific jargon wherever possible to make this intrinsically interdisciplinary subject understandable to a broad range of readers.
How do we store information in the brain? Is memory a thing in a place, like a specific molecule in a particular cell? Or does learning require a process in a population, like neurons firing in a specific pattern for each experience? This combination of memoir and history tells the story of how the mechanisms of memory were gradually revealed, through biographical vignettes of the scientists who set out to solve the riddle of memory, including the author’s own efforts as he was coming of age as a scientist. It shows how individual goals intertwine with the technologies at hand to push scientific knowledge forward, often erratically, and always in the context of social forces and private ups and downs. Not only a compelling personal story with the war in Vietnam, civil rights movement, and downfall of two presidents as backdrop, this is a lucid explanation of brain function for the nonscientist and valuable contribution to the history of science in the decades that saw neuroscience join molecular biology as the marquee biomedical accomplishments of the twentieth century
In Cosmic Biology, Louis Irwin and Dirk Schulze-Makuch guide readers through the range of planetary habitats found in our Solar System and those likely to be found throughout the universe. Based on our current knowledge of chemistry, energy, and evolutionary tendencies, the authors envision a variety of possible life forms. These range from the familiar species found on Earth to increasingly exotic examples possible under the different conditions of other planets and their satellites. Discussions of the great variety of life forms that could evolve in these diverse environments have become particularly relevant in recent years with the discovery of around 300 exoplanets in orbit around other stars and the possibilities for the existence of life in these planetary systems. The book also posits a taxonomic classification of the various forms of life that might be found, including speculation on the relative abundance of different forms and the generic fate of living systems. The fate and future of life on Earth will also be considered. The closing passages address the Fermi Paradox, and conclude with philosophical reflections on the possible place of Homo sapiens in the potentially vast stream of life across the galaxies.
The Evolutionary Imperative provides a unifying perspective on the evolution of the universe in all its physical and biological detail, with a call to action for redirecting the evolutionary trajectory of human society. The book’s thesis is that change is inevitable, driven by resolution of energy gradients through the Principle of Least Action and the Second Law of Thermodynamics. This energy dissipation model of the evolutionary imperative accounts for all the organization of matter and energy that has ever come about, and offers a transcendent view of the world, and the place and fate of the human species within it.
This book chronicles the apparent discovery of “memory molecules” in 1965, the loss of credibility that plagued those findings, and the subsequent triumphant discovery of the neuroactive peptides, including endorphins. The story is told through a series of biographical vignettes and the author’s own experiences that unfolded from the plains of West Texas, through Kansas, Houston, New York, Detroit, and Boston. This seminal episode in the early history of neuroscience flows smoothly for the lay reader as an engaging story of the clash between personalities, conventional wisdom, and unconventional explanations. The book is well documented for the scientist and historian, providing a definitive account of early attempts to understand memory at the molecular level.
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