Biomarker-guided decision making in clinical drug development for neurodegenerative disorders

Shed Syndecans (1-3), ELA-32, BDNF, NLR, and hs-CRP in Parkinson's Disease: Appropriate Diagnostic and Prognostic Biomarkers When Combined in a Unique Panel

Currently, the management of Parkinson's disease (PD), the second most common neurodegenerative disease, is challenging due to the lack of consensus on blood biomarkers for diagnostic, prognostic, and outcome purposes. The identification of specific and sensitive biomarkers could contribute to an early diagnosis and, consequently, facilitate management and improve prognosis. Several molecules are emerging as potential biomarkers, although current data seem preliminary and need further validation. Further, their combination in a panel seems to strengthen their diagnostic power, allowing them to identify PD cases with greater specificity and sensitivity. In this study, we evaluated the association of a panel of molecules, including shed syndecans, ELA peptides, CD141, VEGF, BDNF, and systemic inflammatory indices, in 30 PD cases and 30 matched healthy controls. Significant differences in the systemic levels of all the molecules studied were detected in the PD group when compared to the healthy participants. Univariate and multivariate regression analyses, as well as correlations with clinical indicators, including PD severity expressed by the Hoehn and Yahr (H&Y) scale, highlighted the key role of the studied molecules as independent risk factors. Finally, the use of receiver operating characteristic (ROC) curves demonstrated the diagnostic value of hs-CRP, NLR, BDNF, shed syndecans (1-3), and ELA-32 in PD. Interestingly, their diagnostic performance significantly improved when combined in a panel. Overall, our results suggest that hs-CRP, NLR, BDNF, shed syndecans (1-3), and ELA-32 are significantly associated with PD and could likely serve as appropriate diagnostic and prognostic biomarkers, especially if combined in a panel.

Role of sirtuins in cerebral ischemia-reperfusion injury: Mechanisms and therapeutic potential

The high incidence and mortality rate of cardiac arrest (CA) establishes it as a critical clinical challenge in emergency medicine globally. Despite continuous advances in advanced life support (ALS) technology, the prognosis for patients experiencing cardiac arrest remains poor, with cerebral ischemia and reperfusion injury (CIRI) being a significant determinant of adverse neurological outcomes and increased mortality. Sirtuins (SIRTs) are a class of highly evolutionarily conserved NAD+-dependent histone deacylenzymes capable of regulating the expression of various cytoprotective genes to play a neuroprotective role in CIRI. SIRTs mainly regulate the levels of downstream proteins such as PGC 1-α, Nrf 2, NLRP 3, FoxOs, and PINK 1 to inhibit inflammatory response, attenuate oxidative stress, improve mitochondrial dysfunction, promote angiogenesis, and inhibit apoptosis while reducing CIRI. Natural active ingredients are widely used in regulating the protein level of SIRTs in the body because of their multi-components, multi-pathway, multi-target, and minimal toxic side effects. However, these naturally active ingredients still face many challenges related to drug targeting, pharmacokinetic properties, and drug delivery. The emergence and vigorous development of new drug delivery systems, such as nanoparticles, micromilk, and exosomes, provide strong support for solving the above problems. In the context of the rapid development of molecular biology technology, non-coding RNA (NcRNA), represented by miRNA and LncRNA, offers great potential for achieving gene-level precision medicine. In the context of multidisciplinary integration, combining SIRTs proteins with biotechnology, omics technologies, artificial intelligence, and material science will strongly promote the deepening of their basic research and expand their clinical application. This review describes the major signaling pathways of targeting SIRTs to mitigate CIRI, as well as the current research status of Chinese and Western medicine and medical means for the intervention level of SIRTs. Meanwhile, the challenges and possible solutions in the clinical application of targeted drugs are summarized. In the context of medical and industrial crossover, the development direction of SIRTs in the future is discussed to provide valuable reference for basic medical researchers and clinicians to improve the clinical diagnosis and treatment effects of CIRI.