Introduction:The estimate of people with clinical Alzheimer's disease (AD) and mild cognitive impairment provides an understanding of the disease burden. Methods:We estimated people with cognitive impairment using a quasibinomial regression model in 10,342 participants with cognitive test scores.
Objective: The longitudinal association of the blood biomarkers total tau (t-tau), neurofilament light (Nf-L), and glial fibrillary acidic protein (GFAP) with common sporadic Alzheimer disease (AD) and cognitive decline is not established. Methods: Using a single molecule array technology, ultrasensitive immunoassays for serum concentrations of t-tau, Nf-L, and GFAP were measured in a population sample of 1,327 participants (60% African Americans and women) who had a clinical evaluation for AD, had completed in-home cognitive assessments, and had undergone 1.5T structural magnetic resonance imaging. Results: Higher concentrations of serum biomarkers were associated with the development of clinical AD; especially, the time-specific associations were notable: t-tau 8 to 16 years, and Nf-L and GFAP 4 to 8 years prior to clinical AD. Serum biomarkers were associated with faster cognitive decline over 16 years; baseline t-tau > 0.40pg/ml had 30% faster decline, Nf-L > 25.5pg/ml had 110% faster decline, and GFAP > 232pg/ml had 130% faster decline compared to those in the lowest quartile. Participants with baseline GFAP > 232pg/ml showed 160% faster decline in hippocampal volume compared to those with values < 160pg/ml. Additionally, higher baseline t-tau was associated with faster increase in 3rd ventricular volume, and baseline Nf-L and GFAP were associated with faster decline in cortical thickness. Interpretation: Serum t-tau, Nf-L, and GFAP predict the development of sporadic AD and cognitive decline, and changes in structural brain characteristics, suggesting their usefulness not only as screening and predictive biomarkers, but also in capturing the pathogenesis of Alzheimer dementia.
The thyroid hormone plays a significant role in diverse processes related to growth, development, differentiation, and metabolism. Thyroid hormone signaling modulates energy expenditure through both central and peripheral pathways. At the cellular level, the thyroid hormone exerts its effects after concerted mechanisms facilitate binding to the thyroid hormone receptor. In the hypothalamus, signals from a range of metabolic pathways, including appetite, temperature, afferent stimuli via the autonomic nervous system, availability of energy substrates, hormones, and other biologically active molecules, converge to maintain plasma thyroid hormone at the appropriate level to preserve energy homeostasis. At the tissue level, thyroid hormone actions on metabolism are controlled by transmembrane transporters, deiodinases, and thyroid hormone receptors. In the modern environment, humans are susceptible to an energy surplus, which has resulted in an obesity epidemic and thus understanding the contribution of the thyroid hormone to cellular and organism metabolism is increasingly relevant.
In a large population study, participants using LT exhibited lower serum T:T ratios and differed in 12/52 objective and subjective measures.
The presence of brown adipose tissue (BAT) in adults has become increasingly well defined as a result of functional imaging studies of thermogenically active BAT. Findings from these studies have created a surge of scientific interest in BAT, because it represents a potential therapeutic target for obesity—a condition with profound health consequences and few successful therapies. BAT contributes to overall energy expenditure in small mammals and neonates through adaptive thermogenesis. Thyroid-hormone signalling, particularly through induction of type II deiodinase, has a central role in brown adipogenesis in vitro and BAT development in mouse embryos. Additionally, because of high intracellular expression of type II deiodinase, adult BAT has enhanced thyroid-hormone signalling with several thyroid-hormone-dependent thermogenic pathways, including expression of the genes Ppargc1a and Ucp1. BAT thermogenesis explains the essential part played by thyroid hormone in energy homoeostasis and adaptation to cold. Stimulation of BAT in adults, specifically through thyroid-hormone-mediated pathways, is a promising therapeutic target for obesity.
Thyroid hormone replacement has been used for more than a century to treat hypothyroidism. Natural thyroid preparations (thyroid extract, desiccated thyroid, or thyroglobulin), which contain both thyroxine (T4) and triiodothyronine (T3), were the first pharmacologic treatments available and dominated the market for the better part of the 20th century. Dosages were adjusted to resolve symptoms and to normalize the basal metabolic rate and/or serum protein-bound iodine level, but thyrotoxic adverse effects were not uncommon. Two major developments in the 1970s led to a transition in clinical practice: 1) The development of the serum thyroid-stimulating hormone (TSH) radioimmunoassay led to the discovery that many patients were overtreated, resulting in a dramatic reduction in thyroid hormone replacement dosage, and 2) the identification of peripheral deiodinase-mediated T4-to-T3 conversion provided a physiologic means to justify l-thyroxine monotherapy, obviating concerns about inconsistencies with desiccated thyroid. Thereafter, l-thyroxine mono-therapy at doses to normalize the serum TSH became the standard of care. Since then, a subgroup of thyroid hormone–treated patients with residual symptoms of hypothyroidism despite normalization of the serum TSH has been identified. This has brought into question the inability of l-thyroxine monotherapy to universally normalize serum T3 levels. New research suggests mechanisms for the inadequacies of l-thyroxine monotherapy and highlights the possible role for personalized medicine based on deiodinase polymorphisms. Understanding the historical events that affected clinical practice trends provides invaluable insight into formulation of an approach to help all patients achieve clinical and biochemical euthyroidism.
Levothyroxine (LT4) is a form of thyroid hormone used to treat hypothyroidism. In the brain, T4 is converted to the active form T3 by type 2 deiodinase (D2). Thus, it is intriguing that carriers of the Thr92Ala polymorphism in the D2 gene (DIO2) exhibit clinical improvement when liothyronine (LT3) is added to LT4 therapy. Here, we report that D2 is a cargo protein in ER Golgi intermediary compartment (ERGIC) vesicles, recycling between ER and Golgi. The Thr92-to-Ala substitution (Ala92-D2) caused ER stress and activated the unfolded protein response (UPR). Ala92-D2 accumulated in the trans-Golgi and generated less T3, which was restored by eliminating ER stress with the chemical chaperone 4-phenyl butyric acid (4-PBA). An Ala92-Dio2 polymorphism-carrying mouse exhibited UPR and hypothyroidism in distinct brain areas. The mouse refrained from physical activity, slept more, and required additional time to memorize objects. Enhancing T3 signaling in the brain with LT3 improved cognition, whereas restoring proteostasis with 4-PBA eliminated the Ala92-Dio2 phenotype. In contrast, primary hypothyroidism intensified the Ala92-Dio2 phenotype, with only partial response to LT4 therapy. Disruption of cellular proteostasis and reduced Ala92-D2 activity may explain the failure of LT4 therapy in carriers of Thr92Ala-DIO2.
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