Parkinson’s disease (PD) is considered one of the most frequent neurological brain diseases in the world. There is a need to study the early and efficient biomarkers of PD, such as changes in structural disorders like DNA/chromatin, especially at the subcellular level in the human brain. We used mesoscopic-physics-based techniques, partial wave spectroscopy (PWS), and inverse participation ratio (IPR) to probe structural alteration in the human brain tissue samples and DNA/chromatin in brain cell nuclei. Results show an increase in the structural disorder in tissues and DNA/chromatin. The rise in mass density fluctuations in the nuclei components, such as DNA/chromatin, can be linked to the aggregation of alpha-synuclein in the substantia nigra of the brain. This protein deposition is considered a significant cause of neuronal death in the brains of PD patients. We also did a histological analysis of brain tissues, which supports our results from dual photonics techniques.

Photonics/light localization techniques are essential in understanding the structural changes in biological cells/tissues at the nano- to sub-micron scale. It is now known that structural alteration starts at the nanoscale at the beginning of cancer progression. This photonics study examines the molecular-specific nano-structural alterations of chronic alcoholism and probiotic effects on colon cancer using a mouse model of colon cancer. We assessed alcohol-treated and azoxymethane (AOM) with dextran sulfate sodium (DSS)-induced colitis models, including ethanol (EtOH) and probiotic ( L.Casei) treatments separately and together. The confocal images were analyzed using the mesoscopic physics-based Inverse Participation Ratio (IPR) technique to quantify the structural alterations at nano-to submicron scales. Significant enhancement of cancer progression was observed in the alcohol-treated group, and probiotics treatment with alcohol showed substantial reversal of these changes in colon cancer, underscoring the potential of the IPR technique in detecting and monitoring cancer progression.