Modern stereological methods provide precise and reliable estimates of the number of neurons in specific regions of the brain. We decided to estimate the total number of neocortical neurons in the normal human brain and to analyze it with respect to the major macro- and microscopical structural components, to study the internal relationships of these components, and to quantitate the influence of important physiological variables on brain structure. The 94 brains reported represent a consecutive collection of brains from the general Danish population. The average numbers of neocortical neurons were 19 billion in female brains and 23 billion in male brains, a 16% difference. In our study, which covered the age range from 20 years to 90 years, approximately 10% of all neocortical neurons are lost over the life span in both sexes. Sex and age were the main determinants of the total number of neurons in the human neocortex, whereas body size, per se, had no influence on neuron number. Some of the data presented have been analyzed by using new mathematical designs. An equation predicting the total neocortical neuron number in any individual in which sex and age are known is provided.
Using an unbiased stereological technique, the total numbers of pigmented and non-pigmented neurons were estimated in the substantia nigra of seven patients with Parkinson's disease and seven control patients. Compared with the controls, in which the average total number of pigmented neurons was 550 000, the number of neurons was reduced by 66% in the patients. The average total number of non-pigmented neurons was 260 000 in controls and reduced by 24% in the patients. A significant correlation (r = 0-81) existed between the total numbers of pigmented and non-pigmented neurons in the controls, whereas a similar correlation (r = 0 72) in the patients fell just short of statistical significance. The Exclusion criteria common to the two groups were primary and secondary tumours, infection of the CNS, or a history of alcohol or drug abuse. Also excluded were brains from patients who had been comatose for more than 24 hours before death and those not removed within 72 hours of death. All brains were analysed blindly by one investigator.
Axonal conduction velocity, which ensures efficient function of the brain network, is related to axon diameter. Noninvasive, in vivo axon diameter estimates can be made with diffusion magnetic resonance imaging, but the technique requires three-dimensional (3D) validation. Here, high-resolution, 3D synchrotron X-ray nano-holotomography images of white matter samples from the corpus callosum of a monkey brain reveal that blood vessels, cells, and vacuoles affect axonal diameter and trajectory. Within single axons, we find that the variation in diameter and conduction velocity correlates with the mean diameter, contesting the value of precise diameter determination in larger axons. These complex 3D axon morphologies drive previously reported 2D trends in axon diameter and g-ratio. Furthermore, we find that these morphologies bias the estimates of axon diameter with diffusion magnetic resonance imaging and, ultimately, impact the investigation and formulation of the axon structure–function relationship.
In a stereological study of the human substantia nigra (SN), the total number of melanin-positive and melanin-negative neurones from 28 male subjects aged 19-92 years was estimated using a uniform sampling design and optical disectors. There was a significant decrease in the total number of melanin-positive neurones as a function of age (r(2)=0.18, residual-CV=0.35, 2P=0.032). Using the rotator method, the size distribution of the melanin-positive neurones was estimated and showed a significant difference in mean cell volume of melanin-positive neurones between the seven youngest (21,077 microm(3)) and the seven oldest individuals (32,011 microm(3)), 2P=0.022. Using a combination of the total number of melanin-positive neurones and their size distribution, the total perikaryon volume of melanin-positive neurones could be estimated and showed no decrease with increasing age (r(2)=0.01, residual-CV=0.41, 2P=0.62). Age-related decline in dopamine-transporter neurones within the SN might explain the occurrence of extrapyramidal symptoms in many elderly individuals. Although age-related cell hypertrophy is usually considered to be an indication of cell degeneration or necrosis, this might not always be the case. The fact that motor symptoms, although present in many of the elderly, are of a limited nature despite the high percentage of lost neurones could be due to a compensatory increase in the cell body of dopamine-producing SN neurones. Thus, the total amount of cell substance capable of producing the essential transmitters might not be reduced to a critically low level as a result of ageing.
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