Abstract
Fourier Transform Infrared Spectroscopy (FTIR) is a non-destructive analytical technique that has been employed in this research to characterize the biochemical make-up of various rat brain regions. The sensorimotor cortex, caudate putamen, thalamus, and the hippocampus were found to have higher olefinic content—an indicator of a higher degree of unsaturated fatty acids—rich in short-chain fatty acids, and low in ester and lipid contents. While the regions of the corpus callosum, internal, and external capsule were found to contain long-chained and higher-esterified saturated fatty acids. These molecular differences may reflect the roles of the specific regions in information processing and can provide a unique biochemical platform for future studies on the earlier detection of pathology development in the brain, as a consequence of disease or injury. Laser Ablation Inductively Coupled Plasma Mass Spectroscopy (LA-ICP-MS) is another vital analytical technique that was used in this work to analyze the elements’ distribution patterns in various regions of the brain. The complementary data sets allowed the characterization of the brain regions, the chemical dominating groups, and the elemental composition. This set-up may be used for the investigation of changes in the brain caused by diseases and help create a deeper understanding of the interactions between the organic and elemental composition.
Highlights
The mammalian brain is sub-divided into numerous regions, each with a specific physiological function
The numerical were collected from each rat for the Fourier Transform Infrared Spectroscopy (FTIR), LA-ICP-multiple sclerosis (MS), and the hematoxylin and eosin (H&E) analyses
The FTIR spectroscopy is a good platform to reveal, examine, and investigate bio-chemical alterations associated with functional disorders in brain tissue
Summary
The mammalian brain is sub-divided into numerous regions, each with a specific physiological function. Dissection down the midline identifies the two most visible features—an interior core of white matter (WM), composed of phospholipid rich myelinated axons, and an exterior layer of. Sci. 2018, 8, 2436 gray matter (GM), composed of arborized neurons with un-myelinated axons [1]. Due to the brain’s complexity, there remains an important need for novel technologies that further delineate the (sub-). Cellular components, in order to monitor and characterize the bio-chemical changes associated with neurological dysfunctions. The drawbacks of the current bio-diagnostic technologies are that they are too time-consuming, provide low resolution, and alter tissue integrity
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