Olink

Olink®
Part of Thermo Fisher Scientific

Pro‐Inflammatory Proteins Associated with Frailty and Its Progression—A Longitudinal Study in Community‐Dwelling Women

Selected publication · Journal of Bone and Mineral Research, 2023

Mitchell A., Malmgren L., Bartosch P., McGuigan F., Akesson K.

Disease areaApplication areaSample typeProducts
Aging
Pathophysiology
Serum
Olink Target 96

Olink Target 96

Editor's note

This longitudinal study used a unique population cohort where all the subjects were women enrolled at the same age (75 years) and followed up at 80 years and 85 years, enabling distinctions to be made between chronological and biological aging. The Olink Target 96 CVD II panel was ised to measure plasma proteomics at all three ages, identifying 32 protein biomarkers that were significantly associated with clinical frailty index across all ages measured. 18 of these proteins also continued to be associated with frailty status at 5- and 10-year follow ups

Longitudinal analysis of changes in protein levels over time further identified 8 “core proteins” central to observed changes in frailty index and status over time. These markers (CD4, FGF23, Gal-9, PAR-1, REN, TNFRSF10A TNFRSF11A and TNFRSF10B) reflected pathologies including the renal system, skeletal homeostasis and TRAIL-activated apoptotic signaling. which is in line with the multi-system deterioration seen during frailty.

Abstract

The complex pathophysiology underlying biological aging creates challenges for identifying biomarkers associated with frailty. This longitudinal, nontargeted proteomics study aimed to identify proteins associated with frailty, particularly the change from nonfrail to frail. The population‐based Osteoporosis Prospective Risk Assessment cohort includes women all of whom are 75 years old at inclusion (n = 1044) and reassessed at 80 years (n = 715) and 85 years (n = 382). A deficits in health frailty index (FI) and 92 plasma proteins (Olink CVD‐II panel) were available at all ages. The identical age facilitated differentiating chronological and biological aging. Bidirectional analyses, performed cross‐sectionally and longitudinally, used regression models controlled for false discovery rate (FDR), across 5‐ and 10‐year time windows and longitudinal mixed models. Frailty outcomes were frailty index, frailty status (frail defined as FI ≥ 0.25), change in frailty index, and change in frailty status, together with protein expression or change in protein expression. Elevated levels of 32 proteins were positively associated with the FI, cross‐sectionally at all ages (range: β‐coefficients 0.22–2.06; FDR 0.021–0.024), of which 18 were also associated with frailty status (range: odds ratios 1.40–5.77; FDR 0.022–0.016). Based on the accrued data, eight core proteins (CD4, FGF23, Gal‐9, PAR‐1, REN, TNFRSF10A TNFRSF11A, and TNFRSF10B) are proposed. A one‐unit change in the FI was additively associated with increased protein expression over 5 and 10 years (range: β‐coefficients 0.52–1.59; p < 0.001). Increments in baseline FI consistently associated with a change in protein expression over time (5 years, β‐range 0.05–1.35; 10 years, β‐range 0.51–1.48; all p < 0.001). A one‐unit increase in protein expression was also associated with an increased probability of being frail (FI ≥ 0.25) (β‐range: 0.14–0.61). Mirroring the multisystem deterioration that typifies frailty, the proteins and their associated biological pathways reflect pathologies, including the renal system, skeletal homeostasis, and TRAIL‐activated apoptotic signaling. The core proteins are compelling candidates for understanding the development and progression of frailty with advancing age, including the intrinsic musculoskeletal component. © 2023 The Authors. Journal of Bone and Mineral Research published by Wiley Periodicals LLC on behalf of American Society for Bone and Mineral Research (ASBMR).

Read publication ↗