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Of mice and men: Unique electrical properties of human nerve cells make a difference
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Of mice and men: Unique electrical properties of human nerve cells make a difference

Of mice and men: Unique electrical properties of human nerve cells make a difference
News

Of mice and men: Unique electrical properties of human nerve cells make a difference

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First direct evidence that human neocortical neurons have unique membrane properties that enhance signal processing -


The human brain's advanced cognitive capabilities are often attributed to our recently evolved neocortex. Comparison of human and rodent brains shows that the human cortex is thicker, contains more white matter, has larger neurons, and its abundant pyramidal cells (formerly called "psychic" neurons) have more synaptic connections per cell as compared to rodents.


See Also: Researchers decode patterns that make our brains human


However, scientists have yet to determine whether there are important differences at the biophysical level of the basic building blocks of the human neocortex, the pyramidal neurons. Do these cells possess unique biophysical properties that might impact on cortical computations?


To answer this question, a theoretical team led by Prof. Idan Segev from the Hebrew University of Jerusalem, working with experimental colleagues at Vrije Universiteit Amsterdam and Instituto Cajal in Madrid, built detailed 3D models of pyramidal cells from the human temporal neocortex. These first-ever detailed models of human neurons were based on in vitro intracellular physiological and anatomical data from human cells.


To collect this data, fresh cortical tissue was obtained from brain operations at a neurosurgical department in Amsterdam, and additional data was obtained from light-microscope studies in pyramidal cells from post mortem studies at the Cajal Institute in Madrid.


Learn More: Human brains evolved to be more responsive to environmental influences


The theoretical study predicted that layer 2/3 pyramidal neurons from the human temporal cortex would have a specific membrane capacitance that is half of the commonly accepted "universal" value for biological membranes (~0.5 μF/cm2 vs. ~1 μF/cm2). Since membrane capacitance affects how quickly a cell can respond to its synaptic inputs, this finding has important implications for the transmission of signals within and between cells. The theoretical prediction regarding the specific membrane capacitance was then validated experimentally by direct measurements of membrane capacitance in human pyramidal neurons.


"This is the first direct evidence for the unique electrical properties of human neurons," said researcher Guy Eyal, a PhD student at the Hebrew University's Department of Neurobiology. "Our finding shows that low membrane capacitance significantly improves the efficacy of signal processing and the speed of communication within and between cortical neurons in the human neocortex, as compared to rodents."


"The results of this work imply that human cortical neurons are efficient electrical microchips, compensating for the larger brain and large cells in humans, and processing sensory information more effectively," said Prof. Idan Segev from the Department of Neurobiology and the Edmond and Lily Safra Center for Brain Sciences at the Hebrew University. "Indeed, the study shows that already at the level of the individual building blocks of the nervous system (the nerve cells), humans are distinct as compared to rodents. More research should be performed in this direction on non-human primates."


Read Next: Intertwined evolution of human brain and brawn


The researchers suggest the distinctive biophysical membrane properties of human pyramidal neurons are an outcome of evolutionary pressure to compensate for the increase in size and distances in the human brain.


Note: Material may have been edited for length and content. For further information, please contact the cited source.


The Hebrew University of Jerusalem


Publication

Eyal G et al. Unique membrane properties and enhanced signal processing in human neocortical neurons.  eLife, Published October 6 2016. doi: 10.7554/eLife.16553


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