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#biological — Public Fediverse posts

Live and recent posts from across the Fediverse tagged #biological, aggregated by home.social.

  1. Existing suggests that inter-basin may have , , hydrological, and implications for both the donor and recipient basins. basins have distinct characteristics, including acidity, turbidity, , and chemical content of , as well as the various that reside within and near the aquatic .

    3/24

  2. Existing #literature suggests that inter-basin #water #transfers may have #physical, #chemical, hydrological, and #biological implications for both the donor and recipient basins. #River basins have distinct characteristics, including acidity, turbidity, #temperature, and chemical content of #water, as well as the various #species that reside within and near the aquatic #environment.

    3/24

  3. Existing #literature suggests that inter-basin #water #transfers may have #physical, #chemical, hydrological, and #biological implications for both the donor and recipient basins. #River basins have distinct characteristics, including acidity, turbidity, #temperature, and chemical content of #water, as well as the various #species that reside within and near the aquatic #environment.

    3/24

  4. Existing #literature suggests that inter-basin #water #transfers may have #physical, #chemical, hydrological, and #biological implications for both the donor and recipient basins. #River basins have distinct characteristics, including acidity, turbidity, #temperature, and chemical content of #water, as well as the various #species that reside within and near the aquatic #environment.

    3/24

  5. Existing #literature suggests that inter-basin #water #transfers may have #physical, #chemical, hydrological, and #biological implications for both the donor and recipient basins. #River basins have distinct characteristics, including acidity, turbidity, #temperature, and chemical content of #water, as well as the various #species that reside within and near the aquatic #environment.

    3/24

  6. Reading the dissertation was fascinating because it reveals a side of #Helmholtz that is rarely discussed today. Long before his work on #EnergyConservation, #electrodynamics, and #WavePhysics, he was already deeply engaged with #anatomical and #biological questions.

    It also shows that some core ideas about the comparative structure of nervous systems were already being articulated in the early 19th century.

    #Neuroscience #Physics #ScienceHistory

  7. Reading the dissertation was fascinating because it reveals a side of #Helmholtz that is rarely discussed today. Long before his work on #EnergyConservation, #electrodynamics, and #WavePhysics, he was already deeply engaged with #anatomical and #biological questions.

    It also shows that some core ideas about the comparative structure of nervous systems were already being articulated in the early 19th century.

    #Neuroscience #Physics #ScienceHistory

  8. Reading the dissertation was fascinating because it reveals a side of #Helmholtz that is rarely discussed today. Long before his work on #EnergyConservation, #electrodynamics, and #WavePhysics, he was already deeply engaged with #anatomical and #biological questions.

    It also shows that some core ideas about the comparative structure of nervous systems were already being articulated in the early 19th century.

    #Neuroscience #Physics #ScienceHistory

  9. Reading the dissertation was fascinating because it reveals a side of #Helmholtz that is rarely discussed today. Long before his work on #EnergyConservation, #electrodynamics, and #WavePhysics, he was already deeply engaged with #anatomical and #biological questions.

    It also shows that some core ideas about the comparative structure of nervous systems were already being articulated in the early 19th century.

    #Neuroscience #Physics #ScienceHistory

  10. Reading the dissertation was fascinating because it reveals a side of #Helmholtz that is rarely discussed today. Long before his work on #EnergyConservation, #electrodynamics, and #WavePhysics, he was already deeply engaged with #anatomical and #biological questions.

    It also shows that some core ideas about the comparative structure of nervous systems were already being articulated in the early 19th century.

    #Neuroscience #Physics #ScienceHistory

  11. @sflorg #Structuralbiology is an important #basicresearch direction that aims to gain information about dynamics and interactions of #biological molecules. This research relies on high-tech, including #cryoelectronmicroscopy (EM), nuclear magnetic resonance (#NMR) spectroscopy, and X-ray #crystallography. Goals are a better understanding and e.g. the creation of #molecular #dynamicssimulations.
    StefanFWirth

    reading

    humantechnopole.it/en/research

    H. Schwalbe et al. (2024)
    doi.org/10.1016/j.str.2024.08.

  12. @sflorg #Structuralbiology is an important #basicresearch direction that aims to gain information about dynamics and interactions of #biological molecules. This research relies on high-tech, including #cryoelectronmicroscopy (EM), nuclear magnetic resonance (#NMR) spectroscopy, and X-ray #crystallography. Goals are a better understanding and e.g. the creation of #molecular #dynamicssimulations.
    StefanFWirth

    reading

    humantechnopole.it/en/research

    H. Schwalbe et al. (2024)
    doi.org/10.1016/j.str.2024.08.

  13. @sflorg #Structuralbiology is an important #basicresearch direction that aims to gain information about dynamics and interactions of #biological molecules. This research relies on high-tech, including #cryoelectronmicroscopy (EM), nuclear magnetic resonance (#NMR) spectroscopy, and X-ray #crystallography. Goals are a better understanding and e.g. the creation of #molecular #dynamicssimulations.
    StefanFWirth

    reading

    humantechnopole.it/en/research

    H. Schwalbe et al. (2024)
    doi.org/10.1016/j.str.2024.08.

  14. @sflorg #Structuralbiology is an important #basicresearch direction that aims to gain information about dynamics and interactions of #biological molecules. This research relies on high-tech, including #cryoelectronmicroscopy (EM), nuclear magnetic resonance (#NMR) spectroscopy, and X-ray #crystallography. Goals are a better understanding and e.g. the creation of #molecular #dynamicssimulations.
    StefanFWirth

    reading

    humantechnopole.it/en/research

    H. Schwalbe et al. (2024)
    doi.org/10.1016/j.str.2024.08.

  15. @sflorg #Structuralbiology is an important #basicresearch direction that aims to gain information about dynamics and interactions of #biological molecules. This research relies on high-tech, including #cryoelectronmicroscopy (EM), nuclear magnetic resonance (#NMR) spectroscopy, and X-ray #crystallography. Goals are a better understanding and e.g. the creation of #molecular #dynamicssimulations.
    StefanFWirth

    reading

    humantechnopole.it/en/research

    H. Schwalbe et al. (2024)
    doi.org/10.1016/j.str.2024.08.

  16. A #Biological #Clock is an innate timing device composed of specific proteins that interact with cells throughout the body.

    These internal mechanisms regulate the timing of various functions, such as sleep-wake cycles, by responding to environmental cues like light and temperature.

    knowledgezone.co.in/posts/Chro

  17. A is an innate timing device composed of specific proteins that interact with cells throughout the body.

    These internal mechanisms regulate the timing of various functions, such as sleep-wake cycles, by responding to environmental cues like light and temperature.

    knowledgezone.co.in/posts/Chro

  18. A #Biological #Clock is an innate timing device composed of specific proteins that interact with cells throughout the body.

    These internal mechanisms regulate the timing of various functions, such as sleep-wake cycles, by responding to environmental cues like light and temperature.

    knowledgezone.co.in/posts/Chro

  19. #Archaeology is a driver of scientific innovation. Rather than being a perceived financial burden, it is actually a high-value investment that can improve human health and environmental sustainability.
    We can use ancient #genomes to understand the genetic origins of diseases like MS or the evolution of the plague to develop new treatments.
    Sequencing ancient plant #DNA to identify crop varieties that survived extreme heat or drought in the past, can help secure future food supplies.
    Tracking how #diseases jump from animals to humans (zoonosis) to predict and prevent future #pandemics is critical to #publichealth.
    Physical artifacts can be used to improve life satisfaction for hospital patients and those living with #dementia.
    Archaeological #archives are a treasure-house of #biological and #environmental data that cannot be replicated in a lab. These materials provide a unique natural experiment that can play their part in solving modern global crises.

    See the recent article in issue 71
    Barney Sloane 2026 'Legacy and Springboard: The Untapped Potential of Archaeological Archives for Scientific Innovation', Internet Archaeology 72. doi.org/10.11141/ia.72.11