Your search keyword '"Brain metabolism"' showing total 6,663 results

1. Metabolic and vascular imaging markers for investigating Alzheimer's disease complicated by sleep fragmentation in mice.

Author

Han, Xiaoning, Liu, Guanshu, Lee, Sang Soo, Yang, Xiuli, Wu, Mark N., Lu, Hanzhang, and Wei, Zhiliang

Subjects

SLEEP, CEREBRAL circulation, ALZHEIMER'S disease, HISTOLOGICAL techniques, BRAIN metabolism

Abstract

Background: Sleep problem is a common complication of Alzheimer's disease (AD). Extensive preclinical studies have been performed to investigate the AD pathology. However, the pathophysiological consequence of AD complicated by sleep problem remains to be further determined. Purpose: To investigate brain metabolism and perfusion in an AD mouse model complicated by sleep problem, and subsequently identify potential imaging markers to better understand the associated pathophysiology. Methods: We examined the oxygen extraction fraction (OEF), cerebral metabolic rate of oxygen (CMRO2), and cerebral blood flow (CBF) using state-of-the-art MRI techniques in a cohort of 5xFAD model mice. Additionally, neuroinflammation, indicated by activated microglia, was assessed using histology techniques. Sleep fragmentation (SF) was utilized as a representative for sleep problems. Results: SF was associated with significant increases in OEF (P = 0.023) and CMRO2 (P = 0.029), indicating a state of hypermetabolism. CBF showed a significant genotype-by-sleep interaction effect (P = 0.026), particularly in the deep brain regions such as the hippocampus and thalamus. Neuroinflammation was primarily driven by genotype rather than SF, especially in regions with significant interaction effect in CBF measurements. Conclusion: These results suggest that brain metabolism and perfusion measurements are promising markers for studying the co-pathogenesis of AD and SF. [ABSTRACT FROM AUTHOR]

Published

2024

2. An in-depth review of the function of RNA-binding protein FXR1 in neurodevelopment.

Author

Méndez-Albelo, Natasha M., Sandoval, Soraya O., Xu, Zhiyan, and Zhao, Xinyu

Subjects

*RNA-binding proteins, *NEONATAL death, *NEURAL development, *MENTAL illness, BRAIN metabolism

Abstract

FMR1 autosomal homolog 1 (FXR1) is an RNA-binding protein that belongs to the Fragile X-related protein (FXR) family. FXR1 is critical for development, as its loss of function is intolerant in humans and results in neonatal death in mice. Although FXR1 is expressed widely including the brain, functional studies on FXR1 have been mostly performed in cancer cells. Limited studies have demonstrated the importance of FXR1 in the brain. In this review, we will focus on the roles of FXR1 in brain development and pathogenesis of brain disorders. We will summarize the current knowledge in FXR1 in the context of neural biology, including structural features, isoform diversity and nomenclature, expression patterns, post-translational modifications, regulatory mechanisms, and molecular functions. Overall, FXR1 emerges as an important regulator of RNA metabolism in the brain, with strong implications in neurodevelopmental and psychiatric disorders. [ABSTRACT FROM AUTHOR]

Published

2024

3. Role of cholesterol in modulating brain hyperexcitability.

Author

Wheless, James W. and Rho, Jong M.

Subjects

*EXCITATORY amino acids, *CHOLESTEROL metabolism, *CENTRAL nervous system, *METHYL aspartate receptors, BRAIN metabolism

Abstract

Cholesterol is a critical molecule in the central nervous system, and imbalances in the synthesis and metabolism of brain cholesterol can result in a range of pathologies, including those related to hyperexcitability. The impact of cholesterol on disorders of epilepsy and developmental and epileptic encephalopathies is an area of growing interest. Cholesterol cannot cross the blood–brain barrier, and thus the brain synthesizes and metabolizes its own pool of cholesterol. The primary metabolic enzyme for brain cholesterol is cholesterol 24‐hydroxylase (CH24H), which metabolizes cholesterol into 24S‐hydroxycholesterol (24HC). Dysregulation of CH24H and 24HC can affect neuronal excitability through a range of mechanisms. 24HC is a positive allosteric modulator of N‐methyl‐D‐aspartate (NMDA) receptors and can increase glutamate release via tumor necrosis factor‐α‐dependent pathways. Increasing cholesterol metabolism can lead to dysfunction of excitatory amino acid transporter 2 and impair glutamate reuptake. Finally, overstimulation of NMDA receptors can further activate metabolism of cholesterol, leading to a vicious cycle of overactivation. All of these mechanisms increase extracellular glutamate and can lead to hyperexcitability. For these reasons, the cholesterol pathway represents a new potential mechanistic target for antiseizure medications. CH24H inhibition has been shown to decrease seizure behavior and improve survival in multiple animal models of epilepsy and could be a promising new mechanism of action for the treatment of neuronal hyperexcitability and developmental and epileptic encephalopathies. [ABSTRACT FROM AUTHOR]

Published

2024

4. The impact of brain tissue oxygenation monitoring on the Glasgow Outcome Scale/Glasgow Outcome Scale Extended in patients with moderate to severe traumatic brain injury: A systematic review.

Author

Shanahan, Ruth, Avsar, Pinar, Watson, Chanel, Moore, Zena, Patton, Declan, McEvoy, Natalie L., Curley, Ger, and O'Connor, Tom

Subjects

*BRAIN anatomy, *MEDICAL information storage & retrieval systems, *FUNCTIONAL assessment, *CINAHL database, *INTRACRANIAL pressure, *DESCRIPTIVE statistics, *FUNCTIONAL status, *REACTIVE oxygen species, *OXYGEN in the body, *SYSTEMATIC reviews, *MEDLINE, *INTENSIVE care units, *BRAIN injuries, *PATIENT monitoring, *LENGTH of stay in hospitals, *ONLINE information services, BRAIN metabolism

Abstract

Background: Traumatic brain injuries (TBIs) are one of the leading causes of death or long‐term disability around the world. As a result of improvements in supportive care, patients are surviving more severe insults with more pronounced dependency on their families, hospitals, and long‐term care facilities. The introduction of brain tissue oxygenation (PbtO2) monitoring aims to recognize episodes of reduced cerebral perfusion with and without associated increased intracranial pressure (ICP). Aim: The aim of this review is to determine the impact of PbtO2 on the Glasgow Outcome Scale/Glasgow Outcome Scale Extended (GOS/GOSE) in patients with moderate to severe TBI. Study Design: Systematic review with narrative and meta‐analysis. All original research in which adult patients undergoing PbtO2 were compared with a control group of traditional ICP/cerebral perfusion pressure (CPP) monitoring. Both randomized controlled trials and observational studies were included in this review. Methods: Databases were searched in September 2022. The primary outcome of the review was the impact of PbtO2 monitoring on GOS/GOSE, while secondary outcomes were mortality and length of stay (LOS) in the intensive care unit (ICU). Results: Seven studies with a combined number of 770 patients were included in the review. These patients were adults ≥16 years of age. Only two of the studies included found a statistically significant association between PbtO2 monitoring and improved long‐term neurological outcomes in patients with TBI (p =.01, p <.01). A meta‐analysis of the secondary outcomes identified an associated reduction of mortality in favour of the group treated with PbtO2 monitoring (p <.0001). Results from studies examining LOS in ICU have demonstrated an associated increase of LOS in ICU in patients treated with PbtO2‐guided therapy. Conclusion: From the studies included in this review, only two found a statistically significant association between PbtO2 monitoring and long‐term outcomes. It is unclear whether PbtO2 goal‐directed therapy has a positive impact on the long‐term neurological functions and mortality of patients suffering from TBI. A multicentre randomized controlled trial may provide further evidence, but not necessarily conclusive. Relevance to Clinical Practice: Further research is warranted to determine the efficacy of the introduction of this new monitoring system to guide local policy change. [ABSTRACT FROM AUTHOR]

Published

2024

5. Iron overload regulates cognitive function in rats with minimal hepatic encephalopathy by inducing an increase in frontal butyrylcholinesterase activity.

Author

Hua Lan, Xuhong Yang, Minxing Wang, Minglei Wang, Xueying Huang, and Xiaodong Wang

Subjects

BRAIN metabolism, IRON metabolism, CHOLINESTERASES, BIOLOGICAL models, PEARSON correlation (Statistics), COGNITIVE testing, PHYSIOLOGIC salines, T-test (Statistics), DATA analysis, RESEARCH funding, IRON overload, STATISTICAL sampling, ENZYME-linked immunosorbent assay, LEARNING, MAGNETIC resonance imaging, AMIDES, DESCRIPTIVE statistics, MANN Whitney U Test, HEPATIC encephalopathy, RATS, FRONTAL lobe, ANIMAL experimentation, COGNITION disorders, MEMORY, ANIMAL behavior, STATISTICS, SPACE perception, COMPARATIVE studies, COLLECTION & preservation of biological specimens, DATA analysis software, STAINS & staining (Microscopy)

Abstract

Background and aims: This study aimed to investigate the eect of iron overload on acetylcholinesterase activity in the frontal lobe tissue of rats with minimal hepatic encephalopathy (MHE) and its relation to cognitive ability. By elucidating the potential mechanisms of cognitive impairment, this study may oer insights into novel therapeutic targets for MHE. Materials and methods: Twelve Sprague-Dawley rats were purchased and randomly assigned to either the experimental or control group with six rats in each group. Following the induction of MHE, the Morris Water Maze (MWM) was utilized to assess spatial orientation and memory capacity. Subsequently, Magnetic Resonance Imaging (MRI) scans were performed to capture Quantitative Susceptibility Mapping (QSM) images of all rats’ heads. Results: Compared to the control group rats, the MHE model rats showed significantly reduced learning and memory capabilities as well as spatial orientation abilities (P < 0.05). Furthermore, the susceptibility values in the frontal lobe tissue of MHE model rats was significantly higher than that of the control group rats (P < 0.05), and the corresponding BuChE activity in the frontal lobe extract of model rats was significantly increased while BuChE activity in the peripheral blood serum was significantly decreased compared to the control group rats (P < 0.05). Meanwhile, our findings indicate a significant positive correlation between latency period and BuChE activity with susceptibility values in the MHE group. Conclusion: The changes in BuChE activity in frontal lobe extract may be related to changes in spatial orientation and behavioral changes in MHE, and iron overload in the frontal lobe tissue may regulate changes in BuChE activity, BuChE levels appear to be iron-dependen [ABSTRACT FROM AUTHOR]

Published

2024

6. “Monitoring inflammatory, immune system mediators, and mitochondrial changes related to brain metabolism during space flight”.

Author

Tocci, Darcy, Ducai, Tomas, Barry Stoute, C. A., Hopkins, Gabrielle, Sabbir, Mohammad G., Beheshti, Afshin, and Albensi, Benedict C.

Subjects

NF-kappa B, SPACE flight, BRAIN metabolism, EXTREME environments, ASTROPHYSICAL radiation

Abstract

The possibility of impaired cognitive function during deep space flight missions or while living on a Martian colony is a critical point of concern and pleads for further research. In addition, a fundamental gap exists both in our understanding and application of countermeasures for the consequences of long duration space travel and/or living in an extreme environment such as on the Moon or Mars. Previous studies, while heavily analyzing pre-and post-flight conditions, mostly fail to appreciate the cognitive stressors associated with space radiation, microgravity, confinement, hostile or closed environments, and the long distances from earth. A specific understanding of factors that affect cognition as well as structural and/or physiological changes in the brains of those on a space mission in addition to new countermeasures should result in improved health of our astronauts and reduce risks. At the core of cognitive changes are mechanisms we typically associate with aging, such as inflammatory responses, changes in brain metabolism, depression, and memory impairments. In fact, space flight appears to accelerate aging. In this review, we will discuss the importance of monitoring inflammatory and immune system mediators such as nuclear factor kappa B (NF-kB), and mitochondrial changes related to brain metabolism. We conclude with our recommended countermeasures that include pharmacological, metabolic, and nutritional considerations for the risks on cognition during space missions. [ABSTRACT FROM AUTHOR]

Published

2024

7. Assessing the metabolism of the olfactory circuit by use of 18F-FDG PET-CT imaging in patients suspected of suffering from Alzheimer's disease or frontotemporal dementia.

Author

Loewenstein, Daniël S. L., van Grinsven, Max, de Pont, Cécile, Dautzenberg, Paul L. J., van Strien, Astrid M., and Henssen, Dylan

Subjects

*POSITRON emission tomography, *ALZHEIMER'S disease, *FRONTOTEMPORAL dementia, *POSITRON emission tomography computed tomography, BRAIN metabolism

Abstract

Purpose: The loss of olfactory function is known to occur in patients suffering from (behavioral variant) frontotemporal dementia ((bv)FTD) and Alzheimer's disease (AD), although different pathophysiological mechanisms underpin this clinical symptom in both disorders. This study assessed whether brain metabolism of the olfactory circuit as assessed by positron emission tomography (PET) imaging with 2-[fluorine-18]fluoro-2-deoxy-d-glucose ([18F]-FDG) can distinguish these entities in different subsets of patients. Methods: Patients presenting with cognitive decline were included from a prospectively kept database: (1) bvFTD patients, (2) AD patients and (3) patients with logopenic primary progressive aphasia (PPA). Metabolic rates were calculated for different regions of the olfactory circuit for each subgroup and compared with a cohort of subjects with normal brain metabolism. Additionally, in patients with a logopenic PPA pattern on PET-imaging, statistical parametric mapping (SPM) analysis was performed. Results: The metabolism of subdivisions of the olfactory circuit as assessed by [18F]-FDG PET brain imaging to bvFTD and AD from control subjects resulted in sensitivity/specificity rates of 95/87.5% and 80/83.3%, respectively. A sensitivity/specificity rate of 100/87.5% was achieved when used to differentiate AD from bvFTD. In patients with the PPA pattern on imaging, the underlying cause (either FTD or AD) could be determined with a sensitivity/specificity rate of 88/82%. SPM analysis concurred that different regions of the olfactory circuit were affected in patients suffering from AD PPA or bvFTD PPA. Conclusion: Metabolic dysfunction in the olfactory circuit is different in various neurodegenerative disorders. Further investigation of the correlations between the cerebral metabolism and the mechanisms which drive olfactory dysfunction is needed. [ABSTRACT FROM AUTHOR]

Published

2024

8. Systolic blood pressure variability in late-life predicts cognitive trajectory and risk of Alzheimer's disease.

Author

Xiao-Lu Li, Ruo-Tong Wang, Chen-Chen Tan, Lan Tan, and Wei Xu

Subjects

ALZHEIMER'S disease risk factors, BRAIN metabolism, COGNITION disorder risk factors, RISK assessment, ALZHEIMER'S disease, COGNITIVE testing, RESEARCH funding, RADIOPHARMACEUTICALS, LOGISTIC regression analysis, MULTIPLE regression analysis, DEOXY sugars, KRUSKAL-Wallis Test, DESCRIPTIVE statistics, POSITRON emission tomography, MAGNETIC resonance imaging, CHI-squared test, LONGITUDINAL method, KAPLAN-Meier estimator, LOG-rank test, AMYLOID plaque, WHITE matter (Nerve tissue), NEUROPSYCHOLOGICAL tests, ONE-way analysis of variance, SYSTOLIC blood pressure, DATA analysis software, FACTOR analysis, CONFIDENCE intervals, BLOOD pressure measurement, BIOMARKERS, DISEASE incidence, PROPORTIONAL hazards models

Abstract

Background: The relationship of systolic blood pressure variability (SBPV) with Alzheimer's disease (AD) remains controversial. We aimed to explore the roles of SBPV in predicting AD incidence and to test the pathways that mediated the relationship of SBPV with cognitive functions. Methods: Longitudinal data across 96 months (T0 to T4) were derived from the Alzheimer's disease Neuroimaging Initiative cohort. SBPV for each participant was calculated based on the four measurements of SBP across 24 months (T0 to T3). At T3, logistic regression models were used to test the SBPV difference between 86 new-onset AD and 743 controls. Linear regression models were used to test the associations of SBPV with cognition and AD imaging endophenotypes for 743 non-demented participants (median age = 77.0, female = 42%). Causal mediation analyses were conducted to explore the effects of imaging endophenotypes in mediating the relationships of SBPV with cognitive function. Finally, Cox proportional hazard model was utilized to explore the association of SBPV with incident risk of AD (T3 to T4, mean follow-up = 3.5 years). Results: Participants with new-onset AD at T3 had significantly higher SBPV compared to their controls (p = 0.018). Higher SBPV was associated with lower scores of cognitive function (p = 0.005 for general cognition, p = 0.029 for memory, and p = 0.016 for executive function), higher cerebral burden of amyloid deposition by AV45 PET (p = 0.044), lower brain metabolism by FDG PET (p = 0.052), and higher burden of white matter hyperintensities (WMH) (p = 0.012). Amyloid pathology, brain metabolism, and WMH partially (ranging from 17.44% to 36.10%) mediated the associations of SBPV with cognition. Higher SBPV was significantly associated with elevated risk of developing AD (hazard ratio = 1.29, 95% confidence interval = 1.07 to 1.57, p = 0.008). Conclusion: These findings supported that maintaining stable SBP in late life helped lower the risk of AD, partially by modulating amyloid pathology, cerebral metabolism, and cerebrovascular health. [ABSTRACT FROM AUTHOR]

Published

2024

9. Positron emission tomography neuroimaging of [18F]fluorodeoxyglucose uptake and related behavior in the Pink1-/- rat model of Parkinson disease.

Author

Converse, Alexander K., Krasko, Maryann N., Rudisch, Denis Michael, Lunaris, Charlie Lenell, Nisbet, Alex F., Slesarev, Maxim S., Szot, John C., Hoerst, Andrew G., Leverson, Glen E., Gallagher, Catherine L., and Ciucci, Michelle R.

Subjects

LABORATORY rats, POSITRON emission tomography, BRAIN metabolism, REPEATED measures design, LOCUS coeruleus

Abstract

Introduction: Parkinson disease (PD) is a neurodegenerative condition affecting multiple sensorimotor and cognitive systems. The Pink1-/- rat model exhibits vocal, cognitive, and limb use deficits seen in idiopathic PD. We sought to measure glucose metabolism in brain regions in Pink1-/- and wild type (WT) rats, and to associate these to measures of ultrasonic vocalization, cognition, and limb use behavior. Methods: Pink1-/- (n"="12) and WT (n"="14) rats were imaged by [18F]fluorodeoxyglucose (FDG) positron emission tomography (PET) in a repeated measures design at approximately 10"months of age and 6"weeks later. Relative regional glucose metabolism was indexed by whole brain normalized FDG uptake, which was calculated for 18 regions identified a priori for comparison. Behavioral measures included tests of communication via ultrasonic vocalization, cognition with 5-Choice Serial Reaction Time Test (5-CSRTT), and limb use with Cylinder Test and Challenge Beam. Results: Relative glucose metabolism was significantly different in Pink1-/- rats in prelimbic area, striatum, nucleus ambiguus, globus pallidus, and posterior parietal association cortex compared to WT controls. For behavioral measures, Pink1-/- rats demonstrated quieter vocalizations with a restricted frequency range, and they showed increased number of foot-faults and hindlimb steps (shuffling) in limb motor tests. Significant behavior vs. brain correlations included associations of ultrasonic vocalization parameters with glucose metabolism indices in locus coeruleus and substantia nigra. Conclusion: FDG PET reveals abnormalities in relative regional brain glucose metabolism in Pink1-/- rats in brain regions that are important to cognition, vocalization, and limb motor control that are also impacted by Parkinson disease. This method may be useful for mechanistic studies of behavioral deficits and therapeutic interventions in translational studies in the Pink1-/- PD model. [ABSTRACT FROM AUTHOR]

Published

2024

10. Transient equilibrium determination of dopamine D2/D3 receptor densities and affinities in brain.

Author

Phan, Jenny-Ann, Wong, Dean F., Chang, Natalie H. S., Yoshitaka Kumakura, Bauer, William R., and Gjedde, Albert

Subjects

BRAIN metabolism, BRAIN anatomy, STATISTICAL models, DIAGNOSTIC imaging, RESEARCH funding, DATA analysis, T-test (Statistics), BRAIN, DOPAMINERGIC imaging, POSITRON emission tomography, RADIOISOTOPES, DESCRIPTIVE statistics, BASAL ganglia, ONE-way analysis of variance, STATISTICS, DRUGS, DATA analysis software, NEUROTRANSMITTERS

Abstract

Long-term alteration of dopaminergic neurotransmission is known to modulate the D2/D3 receptor expression in the brain. The modulation can occur as a response to pathological processes or pharmacological intervention. The receptor density can be monitored by in vivo positron emission tomography (PET) of [11C] raclopride. To obtain accurate measurements of receptor-ligand interaction, it is essential to estimate binding parameters at true (if transient) equilibrium of bound and unbound ligand quantities. We designed this study as a comparison of two quantitative approaches to transient equilibrium, the TRansient EquilibriuM BoLus Estimation (TREMBLE) method and the Transient Equilibrium Model (TEM) method, to determine binding parameters at transient equilibrium with bolus injection of the radioligand. The data demonstrates that TREMBLE unlike TEM identified the time at which equilibrium existed. TREMBLE revealed that equilibrium prevailed at one or more times after bolus injection and identified differences of receptor density among regions such as putamen and caudate nucleus. We demonstrated that TREMBLE is a quantitative approach suitable for the study of pathophysiological conditions of certain types of neurotransmission the brain. [ABSTRACT FROM AUTHOR]

Published

2024

11. Astrocytic GLUT1 reduction paradoxically improves central and peripheral glucose homeostasis.

Author

Ardanaz, Carlos G., de la Cruz, Aida, Minhas, Paras S., Hernández-Martín, Nira, Ángel Pozo, Miguel, Valdecantos, M. Pilar, Valverde, Ángela M., Villa-Valverde, Palmira, Elizalde-Horcada, Marcos, Puerta, Elena, Ramírez, María J., Ortega, Jorge E., Urbiola, Ainhoa, Ederra, Cristina, Ariz, Mikel, Ortiz-de-Solórzano, Carlos, Fernández-Irigoyen, Joaquín, Santamaría, Enrique, Karsenty, Gerard, and Brüning, Jens C.

Subjects

*GLUCOSE metabolism, *GLUCOSE transporters, *HOMEOSTASIS, *COGNITIVE ability, *PURINERGIC receptors, BRAIN metabolism

Abstract

Astrocytes are considered an essential source of blood-borne glucose or its metabolites to neurons. Nonetheless, the necessity of the main astrocyte glucose transporter, i.e., GLUT1, for brain glucose metabolism has not been defined. Unexpectedly, we found that brain glucose metabolism was paradoxically augmented in mice with astrocytic GLUT1 reduction (GLUT1ΔGFAP mice). These mice also exhibited improved peripheral glucose metabolism especially in obesity, rendering them metabolically healthier. Mechanistically, we observed that GLUT1-deficient astrocytes exhibited increased insulin receptor-dependent ATP release, and that both astrocyte insulin signaling and brain purinergic signaling are essential for improved brain function and systemic glucose metabolism. Collectively, we demonstrate that astrocytic GLUT1 is central to the regulation of brain energetics, yet its depletion triggers a reprogramming of brain metabolism sufficient to sustain energy requirements, peripheral glucose homeostasis, and cognitive function. [ABSTRACT FROM AUTHOR]

Published

2024

12. Brain Metabolism in Health and Neurodegeneration: The iInterplay Among Neurons and Astrocytes.

Author

Shichkova, Polina, Coggan, Jay S., Markram, Henry, and Keller, Daniel

Subjects

*ENERGY consumption, *ENERGY metabolism, *BLOOD vessels, *SUPPLY & demand, BRAIN metabolism

Abstract

The regulation of energy in the brain has garnered substantial attention in recent years due to its significant implications in various disorders and aging. The brain's energy metabolism is a dynamic and tightly regulated network that balances energy demand and supply by engaging complementary molecular pathways. The crosstalk among these pathways enables the system to switch its preferred fuel source based on substrate availability, activity levels, and cell state-related factors such as redox balance. Brain energy production relies on multi-cellular cooperation and is continuously supplied by fuel from the blood due to limited internal energy stores. Astrocytes, which interface with neurons and blood vessels, play a crucial role in coordinating the brain's metabolic activity, and their dysfunction can have detrimental effects on brain health. This review characterizes the major energy substrates (glucose, lactate, glycogen, ketones and lipids) in astrocyte metabolism and their role in brain health, focusing on recent developments in the field. [ABSTRACT FROM AUTHOR]

Published

2024

13. Role of ACSBG1 in Brain Lipid Metabolism and X-Linked Adrenoleukodystrophy Pathogenesis: Insights from a Knockout Mouse Model.

Author

Ye, Xiaoli, Li, Yuanyuan, González-Lamuño, Domingo, Pei, Zhengtong, Moser, Ann B., Smith, Kirby D., and Watkins, Paul A.

Subjects

*ADRENOLEUKODYSTROPHY, *FATTY acids, *LIPID metabolism, *EICOSANOIDS, *MEMBRANE lipids, BRAIN metabolism

Abstract

"Bubblegum" acyl-CoA synthetase (ACSBG1) is a pivotal player in lipid metabolism during mouse brain development, facilitating the activation of long-chain fatty acids (LCFA) and their incorporation into lipid species that are crucial for brain function. ACSBG1 converts LCFA into acyl-CoA derivatives, supporting vital metabolic processes. Fruit fly mutants lacking ACSBG1 exhibited neurodegeneration and had elevated levels of very long-chain fatty acids (VLCFA), characteristics of human X-linked adrenoleukodystrophy (XALD). To explore ACSBG1's function and potential as a therapeutic target in XALD, we created an ACSBG1 knockout (Acsbg1−/−) mouse and examined the effects on brain FA metabolism during development. Phenotypically, Acsbg1−/− mice resembled wild type (w.t.) mice. ACSBG1 expression was found mainly in tissue affected pathologically in XALD, namely the brain, adrenal gland and testis. ACSBG1 depletion did not significantly reduce the total ACS enzyme activity in these tissue types. In adult mouse brain, ACSBG1 expression was highest in the cerebellum; the low levels detected during the first week of life dramatically increased thereafter. Unexpectedly, lower, rather than higher, saturated VLCFA levels were found in cerebella from Acsbg1−/− vs. w.t. mice, especially after one week of age. Developmental changes in monounsaturated ω9 FA and polyunsaturated ω3 FA levels also differed between w.t. and Acsbg1−/− mice. ACSBG1 deficiency impacted the developmental expression of several cerebellar FA metabolism enzymes, including those required for the synthesis of ω3 polyunsaturated FA, precursors of bioactive signaling molecules like eicosanoids and docosanoids. These changes in membrane lipid FA composition likely affect membrane fluidity and may thus influence the body's response to inflammation. We conclude that, despite compelling circumstantial evidence, it is unlikely that ACSBG1 directly contributes to the pathology of XALD, decreasing its potential as a therapeutic target. Instead, the effects of ACSBG1 knockout on processes regulated by eicosanoids and/or docosanoids should be further investigated. [ABSTRACT FROM AUTHOR]

Published

2024

14. Small Molecules, α-Synuclein Pathology, and the Search for Effective Treatments in Parkinson's Disease.

Author

Sechi, Gian Pietro and Sechi, M. Margherita

Subjects

*PARKINSON'S disease, *SMALL molecules, *DOPAMINERGIC neurons, *NEURODEGENERATION, *DEEP brain stimulation, *VITAMIN B1, BRAIN metabolism

Abstract

Parkinson's disease (PD) is a progressive age-related neurodegenerative disorder affecting millions of people worldwide. Essentially, it is characterised by selective degeneration of dopamine neurons of the nigro-striatal pathway and intraneuronal aggregation of misfolded α-synuclein with formation of Lewy bodies and Lewy neurites. Moreover, specific small molecules of intermediary metabolism may have a definite pathophysiological role in PD. These include dopamine, levodopa, reduced glutathione, glutathione disulfide/oxidised glutathione, and the micronutrients thiamine and ß-Hydroxybutyrate. Recent research indicates that these small molecules can interact with α-synuclein and regulate its folding and potential aggregation. In this review, we discuss the current knowledge on interactions between α-synuclein and both the small molecules of intermediary metabolism in the brain relevant to PD, and many other natural and synthetic small molecules that regulate α-synuclein aggregation. Additionally, we analyse some of the relevant molecular mechanisms potentially involved. A better understanding of these interactions may have relevance for the development of rational future therapies. In particular, our observations suggest that the micronutrients ß-Hydroxybutyrate and thiamine might have a synergistic therapeutic role in halting or reversing the progression of PD and other neuronal α-synuclein disorders. [ABSTRACT FROM AUTHOR]

Published

2024

15. Physiological and behavioural implications of the portosystemic shunt in C57Bl/6J mice.

Author

Lehtimäki, Kimmo K., Rytkönen, Jussi, Pussinen, Raimo, Shatillo, Artem, Bragge, Timo, Heikkinen, Taneli, Fischer, David F., Kopanitsa, Maksym V., Sweeney, Patrick, Nurmi, Antti, and Puoliväli, Jukka

Subjects

*PHYSIOLOGY, *HEPATIC encephalopathy, *BILE acids, *GLUCOSE, BRAIN metabolism

Abstract

A significant fraction of the popular inbred C57Bl/6J mice show structural and biochemical features of the congenital portosystemic shunt (PSS). How this hepatic abnormality affects physiological and behavioural parameters has not been explored in detail. Here, we confirmed the frequent occurrence of the PSS in C57Bl/6J mice by three different methods. We screened a cohort of 119 C57Bl/6J mice for total bile acids (TBA) in plasma, identified 11 animals (9.2%) with high TBA (>11 µm; 171.1 ± 76.8 µm), and confirmed PSS presence in that subset by magnetic resonance angiography and 1H‐magnetic resonance spectroscopy of brain metabolites in the hippocampal area. In addition to the high glutamine and low myo‐inositol levels, we detected lower levels of several neurotransmitters and metabolites in the hippocampus, higher brain weight and volume, as well as enhanced brain glucose utilisation in the PSS mice. We also observed differences in peripheral organ weights, haematological cell counts and clinical chemistry parameters in C57Bl/6J mice with and without PSS. Animals with PSS were slightly hyperlocomotive, had better balance on the rotarod, showed altered gait properties, and displayed attenuated fear memory in the fear conditioning test. Furthermore, we revealed a significant alteration of the pharmacokinetic profile of diazepam in C57Bl/6J mice with PSS. Our data support previous reports of hepatic disturbances and demonstrate an altered neurobiological phenotype in C57Bl/6J mice with PSS. Such congenital differences between inbred C57Bl/6J littermates may significantly distort experimental outcomes of pharmacological, behavioural and genetic studies. Key points: A significant proportion of C57Bl/6J mice, an inbred strain popular in preclinical research, have congenital portosystemic shunts (PSS) that allow venous blood to enter systemic circulation bypassing the liver.In this study, we extended existing knowledge of PSS consequences, particularly with respect to the effects on brain structure and function.We demonstrated that C57Bl/6J mice with PSS differ from their normal counterparts in brain size and contents of several neuroactive substances, as well as in peripheral organ weights, rate of glucose utilisation, blood cell counts and blood clinical chemistry parameters.C57Bl/6J mice with PSS showed altered locomotor behaviour, performed worse in a memory test and had abnormal blood pharmacokinetics of a benzodiazepine drug after a single administration.PSS presence may significantly complicate the interpretation of experiments in C57Bl/6J mice; therefore, we propose that before their use in biomedical studies, these mice should be screened with a simple blood test. [ABSTRACT FROM AUTHOR]

Published

2024

16. Exploring the role of mitochondrial uncoupling protein 4 in brain metabolism: implications for Alzheimer's disease.

Author

Crivelli, Simone M., Gaifullina, Aisylu, and Chatton, Jean-Yves

Subjects

UNCOUPLING proteins, ALZHEIMER'S disease, BRAIN metabolism, MITOCHONDRIAL proteins, REACTIVE oxygen species

Abstract

The brain's high demand for energy necessitates tightly regulated metabolic pathways to sustain physiological activity. Glucose, the primary energy substrate, undergoes complex metabolic transformations, with mitochondria playing a central role in ATP production via oxidative phosphorylation. Dysregulation of this metabolic interplay is implicated in Alzheimer's disease (AD), where compromised glucose metabolism, oxidative stress, and mitochondrial dysfunction contribute to disease progression. This review explores the intricate bioenergetic crosstalk between astrocytes and neurons, highlighting the function of mitochondrial uncoupling proteins (UCPs), particularly UCP4, as important regulators of brain metabolism and neuronal function. Predominantly expressed in the brain, UCP4 reduces the membrane potential in the inner mitochondrial membrane, thereby potentially decreasing the generation of reactive oxygen species. Furthermore, UCP4 mitigates mitochondrial calcium overload and sustains cellular ATP levels through a metabolic shift from mitochondrial respiration to glycolysis. Interestingly, the levels of the neuronal UCPs, UCP2, 4 and 5 are significantly reduced in AD brain tissue and a specific UCP4 variant has been associated to an increased risk of developing AD. Few studies modulating the expression of UCP4 in astrocytes or neurons have highlighted protective effects against neurodegeneration and aging, suggesting that pharmacological strategies aimed at activating UCPs, such as protonophoric uncouplers, hold promise for therapeutic interventions in AD and other neurodegenerative diseases. Despite significant advances, our understanding of UCPs in brain metabolism remains in its early stages, emphasizing the need for further research to unravel their biological functions in the brain and their therapeutic potential. [ABSTRACT FROM AUTHOR]

Published

2024

17. Impaired brain glucose metabolism in glucagon-like peptide-1 receptor knockout mice.

Author

Li, Hui, Fang, Yujiao, Wang, Da, Shi, Bowen, and Thompson, Garth J.

Subjects

GLUCAGON-like peptide-1 receptor, POSITRON emission tomography, BRAIN metabolism, NUCLEAR magnetic resonance spectroscopy, GLUCOSE metabolism disorders

Abstract

Background: Quantitative mapping of the brain's metabolism is a critical tool in studying and diagnosing many conditions, from obesity to neurodegenerative diseases. In particular, noninvasive approaches are urgently required. Recently, there have been promising drug development approaches for the treatment of disorders related to glucose metabolism in the brain and, therefore, against obesity-associated diseases. One of the most important drug targets to emerge has been the Glucagon-like peptide-1 (GLP-1) and its receptor (GLP-1R). GLP and GLP-1R play an important role in regulating blood sugar and maintaining energy homeostasis. However, the macroscopic effects on brain metabolism and function due to the presence of GLP-1R are unclear. Methods: To explore the physiological role of GLP-1R in mouse brain glucose metabolism, and its relationship to brain function, we used three methods. We used deuterium magnetic resonance spectroscopy (DMRS) to provide quantitative information about metabolic flux, fluorodeoxyglucose positron emission tomography (FDG-PET) to measure brain glucose metabolism, and resting state-functional MRI (rs-fMRI) to measure brain functional connectivity. We used these methods in both mice with complete GLP-1R knockout (GLP-1R KO) and wild-type C57BL/6N (WT) mice. Results: The metabolic rate of GLP-1R KO mice was significantly slower than that of WT mice (p = 0.0345, WT mice 0.02335 ± 0.057 mM/min, GLP-1R KO mice 0.01998 ± 0.07 mM/min). Quantification of the mean [18F]FDG signal in the whole brain also showed significantly reduced glucose uptake in GLP-1R KO mice versus control mice (p = 0.0314). Observing rs-fMRI, the functional brain connectivity in GLP-1R KO mice was significantly lower than that in the WT group (p = 0.0032 for gFCD, p = 0.0002 for whole-brain correlation, p < 0.0001 for ALFF). Conclusions: GLP-1R KO mice exhibit impaired brain glucose metabolism to high doses of exogenous glucose, and they also have reduced functional connectivity. This suggests that the GLP-1R KO mouse model may serve as a model for correlated metabolic and functional connectivity loss. [ABSTRACT FROM AUTHOR]

Published

2024

18. Metabolic and vascular imaging markers for investigating Alzheimer's disease complicated by sleep fragmentation in mice.

Author

Xiaoning Han, Guanshu Liu, Sang Soo Lee, Xiuli Yang, Wu, Mark N., Hanzhang Lu, and Zhiliang Wei

Subjects

SLEEP, CEREBRAL circulation, ALZHEIMER'S disease, HISTOLOGICAL techniques, BRAIN metabolism

Abstract

Background: Sleep problem is a common complication of Alzheimer's disease (AD). Extensive preclinical studies have been performed to investigate the AD pathology. However, the pathophysiological consequence of AD complicated by sleep problem remains to be further determined. Purpose: To investigate brain metabolism and perfusion in an AD mouse model complicated by sleep problem, and subsequently identify potential imaging markers to better understand the associated pathophysiology. Methods: We examined the oxygen extraction fraction (OEF), cerebral metabolic rate of oxygen (CMRO2), and cerebral blood flow(CBF) using state-of-the-art MRI techniques in a cohort of 5xFAD model mice. Additionally, neuroinflammation, indicated by activated microglia, was assessed using histology techniques. Sleep fragmentation (SF) was utilized as a representative for sleep problems. Results: SF was associated with significant increases in OEF (P = 0.023) and CMRO2 (P = 0.029), indicating a state of hypermetabolism. CBF showed a significant genotype-by-sleep interaction effect (P = 0.026), particularly in the deep brain regions such as the hippocampus and thalamus. Neuroinflammation was primarily driven by genotype rather than SF, especially in regions with significant interaction effect in CBF measurements. Conclusion: These results suggest that brain metabolism and perfusion measurements are promising markers for studying the co-pathogenesis of AD and SF. [ABSTRACT FROM AUTHOR]

Published

2024

19. Effects of 4.9 GHz Radiofrequency Field Exposure on Brain Metabolomic and Proteomic Characterization in Mice.

Author

Wang, Xing, Zhou, Guiqiang, Lin, Jiajin, Zhang, Zhaowen, Qin, Tongzhou, Guo, Ling, Wang, Haonan, Huang, Zhifei, and Ding, Guirong

Subjects

*CENTRAL nervous system, *POWER density, *LABORATORY mice, *RADIO frequency, BRAIN metabolism

Abstract

Simple Summary: The brain, as the central nervous system that controls the body's sensory, behavior, and mental symptoms, is sensitive to RF exposure, and lots of studies have explored the potential health hazards of RF-EMR with different frequencies to the brain. Our previous study found that 4.9 GHz radiofrequency radiation induced depression-like behavior in mice, but the mechanism of the behavioral changes was unclear. Studies have shown that changes in peripheral energy metabolism might affect brain lipid levels, and thereby cortical excitability, and a deregulated hippocampus proteome might influence the healthy functioning of the brain. Here, we provide evidence that 4.9 GHz RF exposure altered metabolite expression patterns in brain tissue and serum, especially glycerophospholipid metabolism. In addition, 4.9 GHz RF exposure induced an imbalance in the protein profile of brain tissue and may alter gap junction communication. Our results initially revealed the biological effects of 5G communication frequency exposure and provided a possible mechanism for electromagnetic radiation-induced behavioral changes from the perspective of metabolome and proteome. Electromagnetic exposure has become increasingly widespread, and its biological effects have received extensive attention. The purpose of this study was to explore changes in the metabolism profile of the brain and serum and to identify differentially expressed proteins in the brain after exposure to the 4.9 GHz radiofrequency (RF) field. C57BL/6 mice were randomly divided into a Sham group and an RF group, which were sham-exposed and continuously exposed to a 4.9 RF field for 35 d, 1 h/d, at an average power density (PD) of 50 W/m2. After exposure, untargeted metabolomics and Tandem Mass Tags (TMT) quantitative proteomics were performed. We found 104 and 153 up- and down-regulated differentially expressed metabolites (DEMs) in the RF_Brain group and RF_Serum group, and the DEMs were significantly enriched in glycerophospholipid metabolism. Moreover, 10 up-regulated and 51 down-regulated differentially expressed proteins (DEPs) were discovered in the RF group. Functional correlation analysis showed that most DEMs and DEPs showed a significant correlation. These results suggested that 4.9 GHz exposure induced disturbance of metabolism in the brain and serum, and caused deregulation of proteins in the brain. [ABSTRACT FROM AUTHOR]

Published

2024

20. Oxidative Stress Markers and Na,K-ATPase Enzyme Kinetics Are Altered in the Cerebellum of Zucker Diabetic Fatty fa/fa Rats: A Comparison with Lean fa/+ and Wistar Rats.

Author

Radosinska, Dominika, Gaal Kovalcikova, Alexandra, Gardlik, Roman, Chomova, Maria, Snurikova, Denisa, Radosinska, Jana, and Vrbjar, Norbert

Subjects

*TYPE 2 diabetes, *ACTIVE biological transport, *OXIDATIVE stress, *LABORATORY rats, BRAIN metabolism

Abstract

Simple Summary: Type 2 diabetes mellitus (T2DM) is a global health burden that adversely affects various organs, including the brain, leading to neurodegeneration. Recent research emphasizes the cerebellum's role in studying the interactions between T2DM, obesity, aging, and brain energy metabolism. This study focused on the cerebellum of Zucker diabetic fatty (ZDF) rats, a model that mirrors the diversity of T2DM in humans. The primary objective was to measure oxidative stress markers and kinetic properties of sodium–potassium ATPase (Na,K-ATPase) in relation to T2DM severity (not documented yet). Na,K-ATPase is an active transport mechanism crucial for maintaining unequal cation distributions across the plasma membrane, and its activity has been shown to be altered by diabetes in various organs. While oxidative stress is well established in the pathogenesis of diabetes, this study confirmed systemic oxidative and carbonyl damage in ZDF rats and provided new evidence of such damage in cerebellar tissue. However, no differences were found in cerebellar oxidative stress markers based on T2DM severity. Additionally, Na,K-ATPase activity was higher in the cerebellum of ZDF rats compared with controls, suggesting the presence of compensatory mechanisms in this brain region in aged ZDF animals. However, further research is needed to confirm and elucidate this phenomenon. Type 2 diabetes mellitus has been referred to as being closely related to oxidative stress, which may affect brain functions and brain glucose metabolism due to its high metabolic activity and lipid-rich content. Na,K-ATPase is an essential enzyme maintaining intracellular homeostasis, with properties that can sensitively mirror various pathophysiological conditions such as diabetes. The goal of this study was to determine oxidative stress markers as well as Na,K-ATPase activities in the cerebellum of Zucker diabetic fatty (ZDF) rats depending on diabetes severity. The following groups of male rats were used: Wistar, ZDF Lean (fa/+), and ZDF (fa/fa) rats, arbitrarily divided according to glycemia into ZDF obese (ZO, less severe diabetes) and ZDF diabetic (ZOD, advanced diabetes) groups. In addition to basic biometry and biochemistry, oxidative stress markers were assessed in plasma and cerebellar tissues. The Na, K-ATPase enzyme activity was measured at varying ATP substrate concentrations. The results indicate significant differences in basic biometric and biochemical parameters within all the studied groups. Furthermore, oxidative damage was greater in the cerebellum of both ZDF (fa/fa) groups compared with the controls. Interestingly, Na,K-ATPase enzyme activity was highest to lowest in the following order: ZOD > ZO > Wistar > ZDF lean rats. In conclusion, an increase in systemic oxidative stress resulting from diabetic conditions has a significant impact on the cerebellar tissue independently of diabetes severity. The increased cerebellar Na,K-ATPase activity may reflect compensatory mechanisms in aged ZDF (fa/fa) animals, rather than indicating cerebellar neurodegeneration: a phenomenon that warrants further investigation. [ABSTRACT FROM AUTHOR]

Published

2024

21. Effects of Tryptophan and Physical Exercise on the Modulation of Mechanical Hypersensitivity in a Fibromyalgia-like Model in Female Rats.

Author

Rezende, Rafael Marins, Coimbra, Roney Santos, Kohlhoff, Markus, Favarato, Lukiya Silva Campos, Martino, Hércia Stampini Duarte, Leite, Luciano Bernardes, Soares, Leoncio Lopes, Encarnação, Samuel, Forte, Pedro, de Barros Monteiro, António Miguel, Peluzio, Maria do Carmo Gouveia, and José Natali, Antônio

Subjects

*INDOLEAMINE 2,3-dioxygenase, *AEROBIC exercises, *LABORATORY rats, *REDUCING exercises, BRAIN metabolism

Abstract

Though the mechanisms are not fully understood, tryptophan (Trp) and physical exercise seem to regulate mechanical hypersensitivity in fibromyalgia. Here, we tested the impact of Trp supplementation and continuous low-intensity aerobic exercise on the modulation of mechanical hypersensitivity in a fibromyalgia-like model induced by acid saline in female rats. Twelve-month-old female Wistar rats were randomly divided into groups: [control (n = 6); acid saline (n = 6); acid saline + exercise (n = 6); acid saline + Trp (n = 6); and acid saline + exercise + Trp (n = 6)]. Hypersensitivity was caused using two intramuscular jabs of acid saline (20 μL; pH 4.0; right gastrocnemius), 3 days apart. The tryptophan-supplemented diet contained 7.6 g/hg of Trp. The three-week exercise consisted of progressive (30–45 min) treadmill running at 50 to 60% intensity, five times (Monday to Friday) per week. We found that acid saline induced contralateral mechanical hypersensitivity without changing the levels of Trp, serotonin (5-HT), and kynurenine (KYN) in the brain. Hypersensitivity was reduced by exercise (~150%), Trp (~67%), and its combination (~160%). The Trp supplementation increased the levels of Trp and KYN in the brain, and the activity of indoleamine 2,3-dioxygenase (IDO), and decreased the ratio 5-HT:KYN. Exercise did not impact the assessed metabolites. Combining the treatments reduced neither hypersensitivity nor the levels of serotonin and Trp in the brain. In conclusion, mechanical hypersensitivity induced by acid saline in a fibromyalgia-like model in female rats is modulated by Trp supplementation, which increases IDO activity and leads to improved Trp metabolism via the KYN pathway. In contrast, physical exercise does not affect mechanical hypersensitivity through brain Trp metabolism via either the KYN or serotonin pathways. Because this is a short study, generalizing its findings warrants caution. [ABSTRACT FROM AUTHOR]

Published

2024

22. Brain energetics and glucose transport in metabolic diseases: role in neurodegeneration.

Author

Méndez-Flores, Orquídea G., Hernández-Kelly, Luisa C., Olivares-Bañuelos, Tatiana N., López-Ramírez, Gabriel, and Ortega, Arturo

Subjects

*GLUCOSE transporters, *LITERATURE reviews, *NEURAL development, *NEURODEGENERATION, BRAIN metabolism

Abstract

Objectives: Neurons and glial cells are the main functional and structural elements of the brain, and the former depends on the latter for their nutritional, functional and structural organization, as well as for their energy maintenance. Methods: Glucose is the main metabolic source that fulfills energetic demands, either by direct anaplerosis or through its conversion to metabolic intermediates. Development of some neurodegenerative diseases have been related with modifications in the expression and/or function of glial glucose transporters, which might cause physiological and/or pathological disturbances of brain metabolism. In the present contribution, we summarized the experimental findings that describe the exquisite adjustment in expression and function of glial glucose transporters from physiologic to pathologic metabolism, and its relevance to neurodegenerative diseases. Results: A exhaustive literature review was done in order to gain insight into the role of brain energetics in neurodegenerative disease. This study made evident a critical involvement of glucose transporters and thus brain energetics in the development of neurodegenerative diseases. Discussion: An exquisite adjustment in the expression and function of glial glucose transporters from physiologic to pathologic metabolism is a biochemical signature of neurodegenerative diseases. [ABSTRACT FROM AUTHOR]

Published

2024

23. Disrupted mitochondrial response to nutrients is a presymptomatic event in the cortex of the APPSAA knock‐in mouse model of Alzheimer's disease.

Author

Norambuena, Andrés, Sagar, Vijay Kumar, Wang, Zhuoying, Raut, Prakash, Feng, Ziang, Wallrabe, Horst, Pardo, Evelyn, Kim, Taylor, Alam, Shagufta Rehman, Hu, Song, Periasamy, Ammasi, and Bloom, George S.

Abstract

INTRODUCTION: Reduced brain energy metabolism, mammalian target of rapamycin (mTOR) dysregulation, and extracellular amyloid beta (Aβ) oligomer (xcAβO) buildup are some well‐known Alzheimer's disease (AD) features; how they promote neurodegeneration is poorly understood. We previously reported that xcAβOs inhibit nutrient‐induced mitochondrial activity (NiMA) in cultured neurons. We now report NiMA disruption in vivo. METHODS: Brain energy metabolism and oxygen consumption were recorded in heterozygous amyloid precursor protein knock‐in (APPSAA) mice using two‐photon fluorescence lifetime imaging and multiparametric photoacoustic microscopy. RESULTS: NiMA is inhibited in APPSAA mice before other defects are detected in these Aβ‐producing animals that do not overexpress APP or contain foreign DNA inserts into genomic DNA. Glycogen synthase kinase 3 (GSK3β) signals through mTORC1 to regulate NiMA independently of mitochondrial biogenesis. Inhibition of GSK3β with TWS119 stimulates NiMA in cultured human neurons, and mitochondrial activity and oxygen consumption in APPSAA mice. DISCUSSION: NiMA disruption in vivo occurs before plaques, neuroinflammation, and cognitive decline in APPSAA mice, and may represent an early stage in human AD. Highlights: Amyloid beta blocks communication between lysosomes and mitochondria in vivo.Nutrient‐induced mitochondrial activity (NiMA) is disrupted long before the appearance of Alzheimer's disease (AD) histopathology in heterozygous amyloid precursor protein knock‐in (APPSAA/+) mice.NiMA is disrupted long before learning and memory deficits in APPSAA/+ mice.Pharmacological interventions can rescue AD‐related NiMA disruption in vivo. [ABSTRACT FROM AUTHOR]

Published

2024

24. Cerebral glucose metabolism in Alzheimer's disease.

Author

Salmon, Eric, Collette, Fabienne, and Bastin, Christine

Subjects

ALZHEIMER'S disease diagnosis, GLUCOSE metabolism, MILD cognitive impairment, POSITRON emission tomography, DIFFERENTIAL diagnosis

Published

2024

25. Brain metabolism after therapeutic hypothermia for murine hypoxia‐ischemia using hyperpolarized [1‐13C] pyruvate magnetic resonance spectroscopy.

Author

Liu, Xiaodan, Manninen, Tiina, Capper, Alkisti Mikrogeorgiou, Jiang, Xiangning, Ellison, Jacob, Kim, Yaewon, Gurler, Gokce, Xu, Duan, and Ferriero, Donna M.

Subjects

NUCLEAR magnetic resonance spectroscopy, ANAEROBIC metabolism, THERAPEUTIC hypothermia, BRAIN metabolism, NMR spectrometers, CEREBRAL anoxia-ischemia

Abstract

Hypoxic‐ischemic encephalopathy (HIE) is a common neurological syndrome in newborns with high mortality and morbidity. Therapeutic hypothermia (TH), which is standard of care for HIE, mitigates brain injury by suppressing anaerobic metabolism. However, more than 40% of HIE neonates have a poor outcome, even after TH. This study aims to provide metabolic biomarkers for predicting the outcomes of hypoxia‐ischemia (HI) after TH using hyperpolarized [1‐13C] pyruvate magnetic resonance spectroscopy. Postnatal day 10 (P10) mice with HI underwent TH at 1 h and were scanned at 6–8 h (P10), 24 h (P11), 7 days (P17), and 21 days (P31) post‐HI on a 14.1‐T NMR spectrometer. The metabolic images were collected, and the conversion rate from pyruvate to lactate and the ratio of lactate to pyruvate in the injured left hemisphere (kPL(L) and Lac/Pyr(L), respectively) were calculated at each timepoint. The outcomes of TH were determined by the assessments of brain injury on T2‐weighted images and behavioral tests at later timepoint. kPL(L) and Lac/Pyr(L) over time between the good‐outcome and poor‐outcome groups and across timepoints within groups were analyzed. We found significant differences in temporal trends of kPL(L) and Lac/Pyr(L) between groups. In the good‐outcome group, kPL(L) increased until P31 with a significantly higher value at P31 compared with that at P10, while the level of Lac/Pyr(L) at P31 was notably higher than those at all other timepoints. In the poor‐outcome group, kPL(L) and Lac/Pyr(L) increased within 24 h. The kPL(L) value at P11 was considerably higher compared with P10. Discrete temporal changes of kPL(L) and Lac/Pyr(L) after TH between the good‐outcome and poor‐outcome groups were seen as early as 24 h after HI, reflecting various TH effects on brain anaerobic metabolism, which may provide insights for early screening for response to TH. [ABSTRACT FROM AUTHOR]

Published

2024

26. A birdcage transmit, 24‐channel conformal receive array coil for sensitive 31P magnetic resonance spectroscopic imaging of the human brain at 7 T.

Author

Hovagimian, Johnny Der, Yazdanbakhsh, Pedram, Halilibrahimoglu, Hande, Couch, Marcus J., Hoge, Richard, and Rudko, David A.

Subjects

NUCLEAR magnetic resonance spectroscopy, MAGNETIC resonance imaging, BRAIN metabolism, TISSUES, PHASED array antennas

Abstract

Phosphorus (31P) magnetic resonance spectroscopic imaging (MRSI) can serve as a critical tool for more direct quantification of brain energy metabolism, tissue pH, and cell membrane turnover. However, the low concentration of 31P metabolites in biological tissue may result in low signal‐to‐noise ratio (SNR) in 31P MRS images. In this work, we present an innovative design and construction of a 31P radiofrequency coil for whole‐brain MRSI at 7 T. Our coil builds on current literature in ultra‐high field 31P coil design and offers complete coverage of the brain, including the cerebellum and brainstem. The coil consists of an actively detunable volume transmit (Tx) resonator and a custom 24‐channel receive (Rx) array. The volume Tx resonator is a 16‐rung high‐pass birdcage coil. The Rx coil consists of a 24‐element phased array composed of catered loop shapes and sizes built onto a custom, close‐fitting, head‐shaped housing. The Rx array was designed to provide complete coverage of the head, while minimizing mutual coupling. The Rx configuration had a mean S11 reflection coefficient better than −20 decibels (dB) when the coil was loaded with a human head. The mean mutual coupling (S21) among Rx elements, when loaded with a human head, was −16 dB. In phantom imaging, the phased array produced a central SNR that was 4.4‐fold higher than the corresponding central SNR when operating the 31P birdcage as a transceiver. The peripheral SNR was 12‐fold higher when applying the optimized phased array. In vivo 3D 31P MRSI experiments produced high‐quality spectra in the cerebrum gray and white matter, as well as in the cerebellum. Characteristic phosphorus metabolites related to adenosine triphosphate metabolism and cell membrane turnover were distinguishable across all brain regions. In summary, our results demonstrate the potential of our novel coil for accurate, whole‐brain 31P metabolite quantification. [ABSTRACT FROM AUTHOR]

Published

2024

27. Decreased Brain pH Correlated With Progression of Alzheimer Disease Neuropathology: A Systematic Review and Meta-Analyses of Postmortem Studies.

Author

Hagihara, Hideo and Miyakawa, Tsuyoshi

Subjects

BRAIN metabolism, ALZHEIMER'S disease, CEREBROSPINAL fluid, DISEASE progression, ENERGY metabolism

Abstract

Background Altered brain energy metabolism is implicated in Alzheimer disease (AD). Limited and conflicting studies on brain pH changes, indicative of metabolic alterations associated with neural activity, warrant a comprehensive investigation into their relevance in this neurodegenerative condition. Furthermore, the relationship between these pH changes and established AD neuropathological evaluations, such as Braak staging, remains unexplored. Methods We conducted quantitative meta-analyses on postmortem brain and cerebrospinal fluid pH in patients with AD and non-AD controls using publicly available demographic data. We collected raw pH data from studies in the NCBI GEO, PubMed, and Google Scholar databases. Results Our analysis of 20 datasets (723 patient samples and 524 control samples) using a random-effects model showed a significant decrease in brain and cerebrospinal fluid pH in patients compared with controls (Hedges' g  = −0.57, P  < .0001). This decrease remained significant after considering postmortem interval, age at death, and sex. Notably, pH levels were negatively correlated with Braak stage, indicated by the random-effects model of correlation coefficients from 15 datasets (292 patient samples and 159 control samples) (adjusted r  = −0.26, P  < .0001). Furthermore, brain pH enhanced the discriminative power of the APOE ε4 allele, the most prevalent risk gene for AD, in distinguishing patients from controls in a meta-analysis of 4 combined datasets (95 patient samples and 87 control samples). Conclusions The significant decrease in brain pH in AD underlines its potential role in disease progression and diagnosis. This decrease, potentially reflecting neural hyperexcitation, could enhance our understanding of neurodegenerative pathology and aid in developing diagnostic strategies. [ABSTRACT FROM AUTHOR]

Published

2024

28. Neurobehavioral dysfunction in a mouse model of Down syndrome: upregulation of cystathionine β-synthase, H2S overproduction, altered protein persulfidation, synaptic dysfunction, endoplasmic reticulum stress, and autophagy.

Author

Panagaki, Theodora, Janickova, Lucia, Petrovic, Dunja, Zuhra, Karim, Ditrói, Tamás, Jurányi, Eszter P., Bremer, Olivier, Ascenção, Kelly, Philipp, Thilo M., Nagy, Péter, Filipovic, Milos R., and Szabo, Csaba

Subjects

RECOGNITION (Psychology), NEUROBEHAVIORAL disorders, ALZHEIMER'S disease, ENDOPLASMIC reticulum, BRAIN metabolism

Abstract

Down syndrome (DS) is a genetic condition where the person is born with an extra chromosome 21. DS is associated with accelerated aging; people with DS are prone to age-related neurological conditions including an early-onset Alzheimer's disease. Using the Dp(17)3Yey/ + mice, which overexpresses a portion of mouse chromosome 17, which encodes for the transsulfuration enzyme cystathionine β-synthase (CBS), we investigated the functional role of the CBS/hydrogen sulfide (H2S) pathway in the pathogenesis of neurobehavioral dysfunction in DS. The data demonstrate that CBS is higher in the brain of the DS mice than in the brain of wild-type mice, with primary localization in astrocytes. DS mice exhibited impaired recognition memory and spatial learning, loss of synaptosomal function, endoplasmic reticulum stress, and autophagy. Treatment of mice with aminooxyacetate, a prototypical CBS inhibitor, improved neurobehavioral function, reduced the degree of reactive gliosis in the DS brain, increased the ability of the synaptosomes to generate ATP, and reduced endoplasmic reticulum stress. H2S levels in the brain of DS mice were higher than in wild-type mice, but, unexpectedly, protein persulfidation was decreased. Many of the above alterations were more pronounced in the female DS mice. There was a significant dysregulation of metabolism in the brain of DS mice, which affected amino acid, carbohydrate, lipid, endocannabinoid, and nucleotide metabolites; some of these alterations were reversed by treatment of the mice with the CBS inhibitor. Thus, the CBS/H2S pathway contributes to the pathogenesis of neurological dysfunction in DS in the current animal model. [ABSTRACT FROM AUTHOR]

Published

2024

29. 1H-MRS reveals abnormal energy metabolism and excitatory-inhibitory imbalance in a chronic migraine-like state induced by nitroglycerin in mice.

Author

Gao, Jinggui, Wang, Da, Zhu, Chenlu, Wang, Jian, Wang, Tianxiao, Xu, Yunhao, Ren, Xiao, Zhang, Kaibo, Peng, Cheng, Guan, Jisong, and Wang, Yonggang

Subjects

*BIOLOGICAL models, *SOMATOSENSORY evoked potentials, *RESEARCH funding, *NEURAL pathways, *NITROGLYCERIN, *HYPOTHALAMUS, *TRIGEMINAL nerve, *CELLULAR signal transduction, *NOCICEPTIVE pain, *ENERGY metabolism, *MICE, *THALAMUS, *METABOLITES, *ANIMAL experimentation, *RESEARCH, *HIPPOCAMPUS (Brain), *MIGRAINE, *NEUROTRANSMITTERS, *PROTON magnetic resonance spectroscopy, *GABA, *CHEMICAL inhibitors, BRAIN metabolism

Abstract

Background: Chronic migraine is closely related to the dysregulation of neurochemical substances in the brain, with metabolic imbalance being one of the proposed causes of chronic migraine. This study aims to evaluate the metabolic changes between energy metabolism and excitatory and inhibitory neurotransmitters in key brain regions of mice with chronic migraine-like state and to uncover the dysfunctional pathways of migraine. Methods: A chronic migraine-like state mouse model was established by repeated administration of nitroglycerin (NTG). We used von Frey filaments to assess the mechanical thresholds of the hind paw and periorbital in wild-type and familial hemiplegic migraine type 2 mice. After the experiments, tissue was collected from five brain regions: the somatosensory cortex (SSP), hippocampus, thalamus (TH), hypothalamus, and the spinal trigeminal nucleus caudalis (TNC). Proton magnetic resonance spectroscopy (1H-MRS) was employed to study the changes in brain metabolites associated with migraine, aiming to explore the mechanisms underlying metabolic imbalance in chronic migraine-like state. Results: In NTG-induced chronic migraine-like state model, we observed a significant reduction in energy metabolism during central sensitization, an increase in excitatory neurotransmitters such as glutamate, and a tendency for inhibitory neurotransmitters like GABA to decrease. The TNC and thalamus were the most affected regions. Furthermore, the consistency of N-acetylaspartate levels highlighted the importance of the TNC-TH-SSP pathway in the ascending nociceptive transmission of migraine. Conclusion: Abnormal energy metabolism and neurotransmitter imbalance in the brain region of NTG-induced chronic migraine-like state model are crucial mechanisms contributing to the chronicity of migraine. [ABSTRACT FROM AUTHOR]

Published

2024

30. Accumulation of Cerebrospinal Fluid, Ventricular Enlargement, and Cerebral Folate Metabolic Errors Unify a Diverse Group of Neuropsychiatric Conditions Affecting Adult Neocortical Functions.

Author

Ikeda, Lena, Capel, Adrià Vilaseca, Doddaballapur, Dhruti, and Miyan, Jaleel

Subjects

*TETRAHYDROFOLATE dehydrogenase, *CEREBRAL ventricles, *ALDEHYDE dehydrogenase, *CHOROID plexus, *EXTRACELLULAR fluid, *FOLIC acid, BRAIN metabolism

Abstract

Cerebrospinal fluid (CSF) is a fluid critical to brain development, function, and health. It is actively secreted by the choroid plexus, and it emanates from brain tissue due to osmolar exchange and the constant contribution of brain metabolism and astroglial fluid output to interstitial fluid into the ventricles of the brain. CSF acts as a growth medium for the developing cerebral cortex and a source of nutrients and signalling throughout life. Together with perivascular glymphatic and interstitial fluid movement through the brain and into CSF, it also acts to remove toxins and maintain metabolic balance. In this study, we focused on cerebral folate status, measuring CSF concentrations of folate receptor alpha (FOLR1); aldehyde dehydrogenase 1L1, also known as 10-formyl tetrahydrofolate dehydrogenase (ALDH1L1 and FDH); and total folate. These demonstrate the transport of folate from blood across the blood–CSF barrier and into CSF (FOLR1 + folate), and the transport of folate through the primary FDH pathway from CSF into brain FDH + ve astrocytes. Based on our hypothesis that CSF flow, drainage issues, or osmotic forces, resulting in fluid accumulation, would have an associated cerebral folate imbalance, we investigated folate status in CSF from neurological conditions that have a severity association with enlarged ventricles. We found that all the conditions we examined had a folate imbalance, but these folate imbalances were not all the same. Given that folate is essential for key cellular processes, including DNA/RNA synthesis, methylation, nitric oxide, and neurotransmitter synthesis, we conclude that ageing or some form of trauma in life can lead to CSF accumulation and ventricular enlargement and result in a specific folate imbalance/deficiency associated with the specific neurological condition. We believe that addressing cerebral folate imbalance may therefore alleviate many of the underlying deficits and symptoms in these conditions. [ABSTRACT FROM AUTHOR]

Published

2024

31. Assessment of Mannitol-Induced Chronic Blood–Brain Barrier Dysfunction In Vivo Using Magnetic Resonance.

Author

Sampedro-Viana, Ana, Fernández-Rodicio, Sabela, Castillo, José, Hervella, Pablo, Alonso-Alonso, María Luz, and Iglesias-Rey, Ramón

Subjects

*SPRAGUE Dawley rats, *ALZHEIMER'S disease, *MAGNETIC resonance imaging, *MAGNETIC flux leakage, BRAIN metabolism

Abstract

The blood–brain barrier (BBB) is essential for protection and plays a crucial role in chronic neurological disorders like small-vessel disease and Alzheimer's disease. Its complexity poses significant challenges for effective diagnostics and treatments, highlighting the need for novel animal models and comprehensive BBB dysfunction studies. This study investigates chronic BBB dysfunction induction using osmotic disruption via mannitol in healthy adult male Sprague Dawley rats over 12 weeks. Group 1 received 1 bolus/week (2.0 g/kg), Group 2 received 3 boluses/week (1.5 g/kg), and Group 3 received 3 boluses/week (2.5 g/kg). BBB dysfunction was assessed using gadolinium (Gd) infusion and MRI to evaluate location, severity, evolution, and persistence. MR spectroscopy (MRS) examined the brain metabolism changes due to intravenous mannitol, with T2-weighted MRI assessing brain lesions. Biomarkers of neuroinflammation were analyzed in the highest mannitol dose group. Our data show chronic BBB dysfunction primarily in the cortex, hippocampus, and striatum, but not in the corpus callosum of rats under periodic mannitol dosing in groups 1 and 2. MRS identified a distinctive metabolite signature, including changes in alanine, choline, and N-acetyl aspartate in the striatum of Group 1. No significant differences were found in the serum levels of all pro- and anti-inflammatory cytokines analyzed in the high-dose Group 3. This study underscores the feasibility and implications of using osmotic disruption to model chronic BBB dysfunction, offering insights for future neuroprotection and therapeutic strategies research. [ABSTRACT FROM AUTHOR]

Published

2024

32. Limbic Network Derangement Mediates Unawareness of Apathy in Mild Cognitive Impairment due to Alzheimer's Disease: Clues from [18F]FDG PET Voxel-Wise Analysis.

Author

Kreshpa, Wendy, Raffa, Stefano, Girtler, Nicola, Brugnolo, Andrea, Mattioli, Pietro, Orso, Beatrice, Calizzano, Francesco, Arnaldi, Dario, Peira, Enrico, Chincarini, Andrea, Tagliafico, Luca, Monacelli, Fiammetta, Calcagno, Pietro, Serafini, Gianluca, Gotta, Fabio, Mandich, Paola, Pretta, Stefano, Del Sette, Massimo, Sofia, Luca, and Sambuceti, Gianmario

Subjects

*MILD cognitive impairment, *ALZHEIMER'S disease, *CINGULATE cortex, *CAREGIVERS, BRAIN metabolism

Abstract

Background: Discrepancy between caregiver and patient assessments of apathy in mild cognitive impairment (MCI) is considered an index of apathy unawareness, independently predicting progression to AD dementia. However, its neural underpinning are uninvestigated. Objective: To explore the [18F]FDG PET-based metabolic correlates of apathy unawareness measured through the discrepancy between caregiver and patient self-report, in patients diagnosed with MCI. Methods: We retrospectively studied 28 patients with an intermediate or high likelihood of MCI-AD, progressed to dementia over an average of two years, whose degree of apathy was evaluated by means of the Apathy Evaluation Scale (AES) for both patients (PT-AES) and caregivers (CG-AES). Voxel-based analysis at baseline was used to obtain distinct volumes of interest (VOIs) correlated with PT-AES, CG-AES, or their absolute difference (DISCR-AES). The resulting DISCR-AES VOI count densities were used as covariates in an inter-regional correlation analysis (IRCA) in MCI-AD patients and a group of matched healthy controls (HC). Results: DISCR-AES negatively correlated with metabolism in bilateral parahippocampal gyrus, posterior cingulate cortex, and thalamus, PT-AES score with frontal and anterior cingulate areas, while there was no significant correlation between CG-AES and brain metabolism. IRCA revealed that MCI-AD patients exhibited reduced metabolic/functional correlations of the DISCR-AES VOI with the right cingulate gyrus and its anterior projections compared to HC. Conclusions: Apathy unawareness entails early disruption of the limbic circuitry rather than the classical frontal-subcortical pathways typically associated with apathy. This reaffirms apathy unawareness as an early and independent measure in MCI-AD, marked by distinct pathophysiological alterations. [ABSTRACT FROM AUTHOR]

Published

2024

33. Reference Ranges for Regional Cerebral Oxygen Saturation with Masimo O3 after Birth and Differences with Other Devices.

Author

Carnicero, Luis Bachiller and Carbonero, Sonia Caserío

Subjects

*OXYGEN metabolism, *OXYGEN saturation, *CESAREAN section, *REFERENCE values, *HEALTH literacy, *OXYGEN, *OXIMETRY, *SCIENTIFIC observation, *NEAR infrared spectroscopy, *RESUSCITATION, *DESCRIPTIVE statistics, *LONGITUDINAL method, *COMPARATIVE studies, *CHILDBIRTH, BRAIN metabolism

Abstract

Objective Cerebral oximetry using near-infrared spectroscopy (NIRS) is a noninvasive optical technology widely used in neonatology. The present study aimed to define reference ranges for cerebral tissue oxygen saturation (crSO 2) with a new four-wavelength NIRS device, Masimo O3 oximeter, during immediate transition after birth and compare values with those obtained previously with NIRO 200NX ®. Study Design This was a prospective observational study using Masimo O3 device to measure crSO 2 and regional cerebral fractional tissue oxygen extraction (cFTOE) in healthy term newborns delivered by primary cesarean section, during the 15 minutes after cord clamping. The neonates who required any medical support were excluded. The NIRS sensor was placed on the right forehead. Peripheral oxygen saturation and heart rate were continuously measured by pulse oximetry. Previous studies which established centiles for crSO 2 with NIRO 200NX were used for comparison. Results A total of 44 newborns were included. The median crSO 2 and cFTOE (interquartile range) at 2, 5, and 7 minutes was 54% (49–54), 71% (64–86), and 79% (73–84) and 0,25 (0,18–0,33), 0,19 (0,15–0,23), and 0,16 (0,12–0,21), respectively, with no further changes afterwards. The crSO 2 measurements were significantly higher with Masimo O3 compared with NIRO-200NX. Conclusion The present observational study presented reference ranges for crSO 2 and cFTOE measured with Masimo O3 oximeter during the immediate neonatal transition. Values obtained with O3 were higher than those obtained with other oximeters. For this reason, crSO 2 is device-specific so there must be known reference values for each oximeter to define therapeutic interventions based on crSO 2 and assess cerebral oxygenation in clinical studies. Key Points Masimo O3 uses four wavelengths to measure regional oxygen saturation value. O3 values of crSO 2 and cFTOE differ with other neonatal oximeters at birth. Knowledge of reference range of O3 at birth is essential to guide resuscitation. [ABSTRACT FROM AUTHOR]

Published

2024

34. Comparative study on structural and functional brain differences in mild cognitive impairment patients with tinnitus.

Author

Sang-Yoon Han, Heejung Kim, Yejin Yun, Min Jae Lee, Jun-Young Lee, Sun-Won Park, Yu Kyeong Kim, and Young Ho Kim

Subjects

BRAIN anatomy, MILD cognitive impairment, FUNCTIONAL connectivity, RESEARCH funding, RADIOPHARMACEUTICALS, CLUSTER analysis (Statistics), T-test (Statistics), BRAIN, DEOXY sugars, BODY surface mapping, QUESTIONNAIRES, MAGNETIC resonance imaging, DESCRIPTIVE statistics, TINNITUS, GRAY matter (Nerve tissue), RESEARCH, DATA analysis software, FACTOR analysis, COMPARATIVE studies, AMYLOID beta-protein precursor, DISEASE complications

Abstract

Objective: Tinnitus may be associated with various brain changes. However, the degenerative changes in patients with tinnitus have not been extensively investigated. We aimed to evaluate degenerative, structural, and functional brain changes in patients with mild cognitive impairment (MCI) who also suffer from tinnitus. Materials and methods: This study included participants aged 60 to 80 years with MCI and a hearing level better than 40 dB. The participants were classified into two groups: MCI with tinnitus (MCI-T) and MCI without tinnitus (MCI-NT). All patients underwent Tinnitus Handicap Inventory (THI), 3 T brain MRI, F18-florapronol PET, and F18-FDG PET. Results: The MCI-T group exhibited higher ß-amyloid deposition in the superior temporal gyrus, temporal pole, and middle temporal gyrus compared to the MCI-NT group (p < 0.05 for all). Additionally, the MCI-T group showed increased metabolism in the inferior frontal gyrus, insula, and anterior cingulate cortex (ACC) (p < 0.005 for all). The THI score was strongly correlated with increased volume in the insula, ACC, superior frontal gyrus, supplementary motor area, white matter near the hippocampus, and precentral gyrus (p < 0.05 for all). Moreover, the MCI-T group demonstrated higher metabolic activity in the default mode network (DMN) and lower activity in the executive control network (ECN) (p < 0.05 for all). In the MCI-T group, the posterior DMN was positively correlated with the visual network and negatively with the ECN, whereas in the MCI-NT group, it correlated positively with the ECN. Conclusion: The MCI-T group exhibited greater ß-amyloid accumulation in the auditory cortex and more extensive changes across various brain networks compared with the MCI-NT group, potentially leading to diverse clinical symptoms such as dementia with semantic deficits or depression. Tinnitus in MCI patients may serve as a biomarker for degenerative changes in the temporal lobe and alterations in brain network dynamics. [ABSTRACT FROM AUTHOR]

Published

2024

35. Acute exercise alters brain glucose metabolism in aging and Alzheimer's disease.

Author

Green, Zachary D., John, Casey S., Kueck, Paul J., Blankenship, Anneka E., Kemna, Riley E., Johnson, Chelsea N., Yoksh, Lauren E., Best, Shaun R., Donald, Joseph S., Mahnken, Jonathan D., Burns, Jeffrey M., Vidoni, Eric D., and Morris, Jill K.

Subjects

*BLOOD lactate, *ALZHEIMER'S disease, *POSITRON emission tomography, *GLUCOSE metabolism, BRAIN metabolism

Abstract

Key points There is evidence that aerobic exercise improves brain health. Benefits may be modulated by acute physiological responses to exercise, but this has not been well characterized in older or cognitively impaired adults. The randomized controlled trial ‘AEROBIC’ (NCT04299308) enrolled 60 older adults who were cognitively healthy (n = 30) or cognitively impaired (n = 30) to characterize the acute brain responses to moderate [45–55% heart rate reserve (HRR)] and higher (65–75% HRR) intensity acute exercise. Each participant received two fluorodeoxyglucose positron emission tomography (FDG‐PET) scans, one at rest and one following acute exercise. Change in cerebral glucose metabolism from rest to exercise was the primary outcome. Blood biomarker responses were also characterized as secondary outcomes. Whole grey matter FDG‐PET standardized uptake value ratio (SUVR) differed between exercise (1.045 ± 0.082) and rest (0.985 ± 0.077) across subjects [Diff = −0.060, t(58) = 13.8, P < 0.001] regardless of diagnosis. Exercise increased lactate area under the curve (AUC) [F(1,56) = 161.99, P < 0.001] more in the higher intensity group [mean difference (MD) = 97.0 ± 50.8] than the moderate intensity group (MD = 40.3 ± 27.5; t = −5.252, P < 0.001). Change in lactate AUC and FDG‐PET SUVR correlated significantly (R2 = 0.179, P < 0.001). Acute exercise decreased whole grey matter cerebral glucose metabolism. This effect tracked with the systemic lactate response, suggesting that lactate may serve as a key brain fuel during exercise. Direct measurements of brain lactate metabolism in response to exercise are warranted. Acute exercise is associated with a drop in global brain glucose metabolism in both cognitively healthy older adults and those with Alzheimer's disease. Blood lactate levels increase following acute exercise. Change in brain metabolism tracks with blood lactate, suggesting it may be an important brain fuel. Acute exercise stimulates changes in brain‐derived neurotrophic factor and other blood biomarkers. [ABSTRACT FROM AUTHOR]

Published

2024

36. Spatial regulation of NMN supplementation on brain lipid metabolism upon subacute and sub-chronic PM exposure in C57BL/6 mice.

Author

Jiang, Yue, Li, Fang, Ye, Lizhu, Zhang, Rui, Chen, Shen, Peng, Hui, Zhang, Haiyan, Li, Daochuan, Chen, Liping, Zeng, Xiaowen, Dong, Guanghui, Xu, Wei, Liao, Chunyang, Zhang, Rong, Luo, Qian, and Chen, Wen

Subjects

BRAIN metabolism, LIPID metabolism, METABOLIC regulation, PARTICULATE matter, NERVOUS system

Abstract

Background: Atmospheric particulate matter (PM) exposure-induced neuroinflammation is critical in mediating nervous system impairment. However, effective intervention is yet to be developed. Results: In this study, we examine the effect of β-nicotinamide mononucleotide (NMN) supplementation on nervous system damage upon PM exposure and the mechanism of spatial regulation of lipid metabolism. 120 C57BL/6 male mice were exposed to real ambient PM for 11 days (subacute) or 16 weeks (sub-chronic). NMN supplementation boosted the level of nicotinamide adenine dinucleotide (NAD+) in the mouse brain by 2.04 times. This augmentation effectively reduced neuroinflammation, as evidenced by a marked decrease in activated microglia levels across various brain regions, ranging from 29.29 to 85.96%. Whole brain lipidomics analysis revealed that NMN intervention resulted in an less increased levels of ceramide (Cer) and lysophospholipid in the brain following subacute PM exposure, and reversed triglyceride (TG) and glycerophospholipids (GP) following sub-chronic PM exposure, which conferred mice with anti-neuroinflammation response, improved immune function, and enhanced membrane stability. In addition, we demonstrated that the hippocampus and hypothalamus might be the most sensitive brain regions in response to PM exposure and NMN supplementation. Particularly, the alteration of TG (60:10, 56:2, 60:7), diacylglycerol (DG, 42:6), and lysophosphatidylcholine (LPC, 18:3) are the most profound, which correlated with the changes in functional annotation and perturbation of pathways including oxidative stress, inflammation, and membrane instability unveiled by spatial transcriptomic analysis. Conclusions: This study demonstrates that NMN intervention effectively reduces neuroinflammation in the hippocampus and hypothalamus after PM exposure by modulating spatial lipid metabolism. Strategies targeting the improvement of lipid homeostasis may provide significant protection against brain injury associated with air pollutant exposure. [ABSTRACT FROM AUTHOR]

Published

2024

37. Calycosin-7-O-β-D-Glucoside Ameliorates Palmitate-Induced Lipid Accumulation in HT22 Cells.

Author

Yanming Xu, Dalong Li, Ao Xue, Jiaming Gu, Yifan Ren, Siyu Zhu, Xia Lei, Jianxin Liu, Jihui Zhao, Fang Geng, and Ning Zhang

Subjects

*CHOLESTEROL hydroxylase, *TIME-of-flight mass spectrometry, *CHOLESTEROL metabolism, *ALZHEIMER'S disease, BRAIN metabolism

Abstract

Background: The pathogenesis of Alzheimer's disease (AD) is complex. Recent research suggests that AD patients have early disorders in brain cholesterol metabolism. Cholesterol and its derivatives accumulate in neurons, leading to p-Tau overproduction and synaptic dysfunction, initiating AD progression. Calycosin-7-O-ß-D-glucoside (CG), a distinctive constituent of Astragali Radix, holds a representative position. Many clinical trials have demonstrated that CG can attenuate cerebral ischemia/reperfusion injury and preserve the structural integrity of the blood-brain barrier. However, whether CG alleviates tau-mediated neurodegeneration by increasing cholesterol efflux after lipid accumulation remains unexplored. Methods: Ultra-performance liquid chromatography/quadrupole time-of-flight mass spectrometry (UPLCQ-TOF-MS/MS) and multivariate data analysis were employed to investigate metabolic changes in HT22 cells induced by sodium palmitate following 24 hours of CG treatment. The potential therapeutic mechanisms of CG on AD were further examined through Kyoto Encyclopedia of Genes and Genomes (KEGG) pathway enrichment analysis. Results: Metabolomic analysis characterized 24 potential biomarkers, revealing that CG could ameliorate cholesterol metabolic pathways. The results of cell experiments revealed that CG can increase the expression of enzyme cholesterol 24-hydroxylase (CYP46A1) (p < 0.05) and the level of 24 hydroxycholesterol (24-OHC) (p < 0.05), reduce the expression of p-Tau (Thr231)/Tau (p < 0.01), inhibit the formation of lipid droplets. Conclusion: CG may inhibit the accumulation of cholesterol and its derivatives in neurons by affecting the CYP46A1-CE-Tau axis, offering a potential therapeutic strategy for AD. [ABSTRACT FROM AUTHOR]

Published

2024

38. Glyceraldehyde metabolism in mouse brain and the entry of blood‐borne glyceraldehyde into the brain.

Author

Hassel, Bjørnar, Sørnes, Kristian, Elsais, Ahmed, Cordero, Patricia Reyes, Frøland, Anne Sofie, and Rise, Frode

Subjects

*NUCLEAR magnetic resonance spectroscopy, *ADVANCED glycation end-products, *ALZHEIMER'S disease, *CELL metabolism, BRAIN metabolism

Abstract

D‐Glyceraldehyde, a reactive aldehyde metabolite of fructose and glucose, is neurotoxic in vitro by forming advanced glycation end products (AGEs) with neuronal proteins. In Alzheimer's disease brains, glyceraldehyde‐containing AGEs have been detected intracellularly and in extracellular plaques. However, little information exists on how the brain handles D‐glyceraldehyde metabolically or if glyceraldehyde crosses the blood–brain barrier from the circulation into the brain. We injected [U‐13C]‐D‐glyceraldehyde intravenously into awake mice and analyzed extracts of serum and brain by 13C nuclear magnetic resonance spectroscopy. 13C‐Labeling of brain lactate and glutamate indicated passage of D‐glyceraldehyde from blood to brain and glycolytic and oxidative D‐glyceraldehyde metabolism in brain cells. 13C‐Labeling of serum glucose and lactate through hepatic metabolism of [U‐13C]‐D‐glyceraldehyde could not explain the formation of 13C‐labeled lactate and glutamate in the brain. Cerebral glyceraldehyde dehydrogenase and reductase activities, leading to the formation of D‐glycerate and glycerol, respectively, were 0.27–0.28 nmol/mg/min; triokinase, which phosphorylates D‐glyceraldehyde to D‐glyceraldehyde‐3‐phosphate, has been demonstrated previously at low levels. Thus, D‐glyceraldehyde metabolism toward glycolysis could proceed both through D‐glycerate, glycerol, and D‐glyceraldehyde‐3‐phosphate. The aldehyde group of D‐glyceraldehyde was overwhelmingly hydrated into a diol in aqueous solution, but the diol dehydration rate greatly exceeded glyceraldehyde metabolism and did not restrict it. We conclude that (1) D‐glyceraldehyde crosses the blood–brain barrier, and so blood‐borne glyceraldehyde could contribute to AGE formation in the brain, (2) glyceraldehyde is taken up and metabolized by brain cells. Metabolism thus constitutes a detoxification mechanism for this reactive aldehyde, a mechanism that may be compromised in disease states. [ABSTRACT FROM AUTHOR]

Published

2024

39. Common anesthetic used in preclinical PET imaging inhibits metabolism of the PET tracer [18F]3F4AP.

Author

Ramos‐Torres, Karla, Sun, Yang, Takahashi, Kazue, Zhou, Yu‐Peng, and Brugarolas, Pedro

Subjects

*CYTOCHROME P-450 CYP2E1, *POSITRON emission tomography, *DISULFIRAM, *DIAGNOSTIC imaging, BRAIN metabolism

Abstract

Positron emission tomography (PET) imaging studies in laboratory animals are almost always performed under isoflurane anesthesia to ensure that the subject stays still during the image acquisition. Isoflurane is effective, safe, and easy to use, and it is generally assumed to not have an impact on the imaging results. Motivated by marked differences observed in the brain uptake and metabolism of the PET tracer 3‐[18F]fluoro‐4‐aminopyridine [(18F]3F4AP) between human and nonhuman primate studies, this study investigates the possible effect of isoflurane on this process. Mice received [18F]3F4AP injection while awake or under anesthesia and the tracer brain uptake and metabolism was compared between groups. A separate group of mice received the known cytochrome P450 2E1 inhibitor disulfiram prior to tracer administration. Isoflurane was found to largely abolish tracer metabolism in mice (74.8 ± 1.6 vs. 17.7 ± 1.7% plasma parent fraction, % PF) resulting in a 4.0‐fold higher brain uptake in anesthetized mice at 35 min post‐radiotracer administration. Similar to anesthetized mice, animals that received disulfiram showed reduced metabolism (50.0 ± 6.9% PF) and a 2.2‐fold higher brain signal than control mice. The higher brain uptake and lower metabolism of [18F]3F4AP observed in anesthetized mice compared to awake mice are attributed to isoflurane's interference in the CYP2E1‐mediated breakdown of the tracer, which was confirmed by reproducing the effect upon treatment with the known CYP2E1 inhibitor disulfiram. These findings underscore the critical need to examine the effect of isoflurane in PET imaging studies before translating tracers to humans that will be scanned without anesthesia. [ABSTRACT FROM AUTHOR]

Published

2024

40. Pro-atherogenic medical conditions are associated with widespread regional brain metabolite abnormalities in those with alcohol use disorder.

Author

Durazzo, Timothy C, Kraybill, Eric P, Stephens, Lauren H, May, April C, and Meyerhoff, Dieter J

Subjects

*RESEARCH funding, *CELL membranes, *BRAIN, *DESCRIPTIVE statistics, *METABOLITES, *GRAY matter (Nerve tissue), *CREATINE, *WHITE matter (Nerve tissue), *ALCOHOLISM, *COMPARATIVE studies, *COMORBIDITY, *PROTON magnetic resonance spectroscopy, BRAIN metabolism

Abstract

Aims Widespread brain metabolite abnormalities in those with alcohol use disorder (AUD) were reported in numerous studies, but the effects of the pro-atherogenic conditions of hypertension, type 2 diabetes mellitus, hepatitis C seropositivity, and hyperlipidemia on metabolite levels were not considered. These conditions were associated with brain metabolite abnormalities in those without AUD. We predicted treatment-seeking individuals with AUD and pro-atherogenic conditions (Atherogenic+) demonstrate lower regional metabolite markers of neuronal viability [N-acetylaspartate (NAA)] and cell membrane turnover/synthesis [choline-containing compounds (Cho)], compared with those with AUD without pro-atherogenic conditions (Atherogenic−) and healthy controls (CON). Methods Atherogenic+ (n = 59) and Atherogenic− (n = 51) and CON (n = 49) completed a 1.5 T proton magnetic resonance spectroscopic imaging study. Groups were compared on NAA, Cho, total creatine, and myoinositol in cortical gray matter (GM), white matter (WM), and select subcortical regions. Results Atherogenic+ had lower frontal GM and temporal WM NAA than CON. Atherogenic+ showed lower parietal GM, frontal, parietal and occipital WM and lenticular nuclei NAA level than Atherogenic− and CON. Atherogenic− showed lower frontal GM and WM NAA than CON. Atherogenic+ had lower Cho level than CON in the frontal GM, parietal WM, and thalamus. Atherogenic+ showed lower frontal WM and cerebellar vermis Cho than Atherogenic− and CON. Conclusions Findings suggest proatherogenic conditions in those with AUD were associated with increased compromise of neuronal integrity and cell membrane turnover/synthesis. The greater metabolite abnormalities observed in Atherogenic+ may relate to increased oxidative stress-related compromise of neuronal and glial cell structure and/or impaired arterial vasoreactivity/lumen viability. [ABSTRACT FROM AUTHOR]

Published

2024

41. CCNP Innovations in Neuropsychopharmacology Award: The psychopharmacology of psychedelics: where the brain meets spirituality.

Author

Gobbi, Gabriella

Subjects

*MENTAL illness drug therapy, *BRAIN, *SOCIAL cohesion, *NEUROPLASTICITY, *HALLUCINOGENIC drugs, *ANTIPSYCHOTIC agents, *DEFAULT mode network, *NEUROPSYCHOLOGY, *SPIRITUALITY, *AWARDS, *MOLECULAR structure, *PSYCHOPHARMACOLOGY, *CELL receptors, *COGNITION, *PHARMACODYNAMICS, BRAIN metabolism

Abstract

For 3000 years, psychedelics have been used in religious contexts to enhance spiritual thinking, well-being, and a sense of community. In the last few years, a renaissance in the use of psychedelic drugs for mental disorders has occurred in Western society; consequently, a pressing scientific need to elucidate the intricate mechanisms underlying their actions has arisen. Psychedelics mainly bind to serotonin (5-HT) receptors, particularly 5-HT2A receptors, but may also bind to other receptors. Unlike conventional psychotropic drugs used in psychiatry, psychedelics introduce a distinctive complexity. They not only engage in receptor activation, but also exert influence over specific neural circuits, thereby facilitating transformative cognitive experiences and fostering what many have identified as a spiritual contemplation or mystical experience. This comprehensive review describes clinical studies that have examined the propensity of psychedelics to enhance spiritual, mystical, and transcendent cognitive states. This multifaceted nature, encompassing diverse components and paradigms, necessitates careful consideration during the investigation of psychedelic mechanisms of action to avoid oversimplification. The present review endeavours to elucidate the mechanisms underlying the actions of 2 principal psychedelic substances, psilocybin and lysergic acid diethylamide (LSD), with a focus on monoamine and glutamate receptor mechanisms; molecular aspects, such as neuroplasticity and epigenetics; as well as the impact of psychedelics on brain circuits, including the default mode network and the cortico–striato–thalamo–cortical network. Given their distinctive and intricate mechanisms of action, psychedelics necessitate a novel conceptual framework in psychiatry, offering insight into the treatment of mental health disorders and facilitating the integration of the realms of brain, mind, and spirituality. [ABSTRACT FROM AUTHOR]

Published

2024

42. Persistent brain metabolic impairment in long COVID patients with persistent clinical symptoms: a nine-month follow-up [18F]FDG-PET study.

Author

Horowitz, Tatiana, Dudouet, Pierre, Campion, Jacques-Yves, Kaphan, Elsa, Radulesco, Thomas, Gonzalez, Sandra, Cammilleri, Serge, Ménard, Amélie, and Guedj, Eric

Subjects

*POST-acute COVID-19 syndrome, *COVID-19, *COVID-19 pandemic, *CEREBELLUM, BRAIN metabolism

Abstract

Purpose: A hypometabolic profile involving the limbic areas, brainstem and cerebellum has been identified in long COVID patients using [18F]fluorodeoxyglucose (FDG)-PET. This study was conducted to evaluate possible recovery of brain metabolism during the follow-up of patients with prolonged symptoms. Methods: Fifty-six adults with long COVID who underwent two brain [18F]FDG-PET scans in our department between May 2020 and October 2022 were retrospectively analysed, and compared to 51 healthy subjects. On average, PET1 was performed 7 months (range 3–17) after acute COVID-19 infection, and PET2 was performed 16 months (range 8–32) after acute infection, because of persistent severe or disabling symptoms, without significant clinical recovery. Whole-brain voxel-based analysis compared PET1 and PET2 from long COVID patients to scans from healthy subjects (p-voxel < 0.001 uncorrected, p-cluster < 0.05 FWE-corrected) and PET1 to PET2 (with the same threshold, and secondarily with a less constrained threshold of p-voxel < 0.005 uncorrected, p-cluster < 0.05 uncorrected). Additionally, a region-of-interest (ROI) semiquantitative anatomical approach was performed for the same comparisons (p < 0.05, corrected). Results: PET1 and PET2 revealed voxel-based hypometabolisms consistent with the previously reported profile in the literature. This between-group analysis comparing PET1 and PET2 showed minor improvements in the pons and cerebellum (8.4 and 5.2%, respectively, only significant under the less constrained uncorrected p-threshold); for the pons, this improvement was correlated with the PET1-PET2 interval (r = 0.21, p < 0.05). Of the 14,068 hypometabolic voxels identified on PET1, 6,503 were also hypometabolic on PET2 (46%). Of the 7,732 hypometabolic voxels identified on PET2, 6,094 were also hypometabolic on PET1 (78%). The anatomical ROI analysis confirmed the brain hypometabolism involving limbic region, the pons and cerebellum at PET1 and PET2, without significant changes between PET1 and PET2. Conclusion: Subjects with persistent symptoms of long COVID exhibit durable deficits in brain metabolism, without progressive worsening. [ABSTRACT FROM AUTHOR]

Published

2024

43. Frontal-striatal glucose metabolism and fatigue in patients with multiple sclerosis, long COVID, and COVID-19 recovered controls.

Author

Rudroff, Thorsten

Subjects

*POST-acute COVID-19 syndrome, *FATIGUE (Physiology), *GLOBUS pallidus, *CAUDATE nucleus, BRAIN metabolism

Abstract

This study compared brain glucose metabolism using FDG-PET in the caudate nucleus, putamen, globus pallidus, thalamus, and dorsolateral prefrontal cortex (DLPFC) among patients with Long COVID, patients with fatigue, people with multiple sclerosis (PwMS) patients with fatigue, and COVID recovered controls. PwMS exhibited greater hypometabolism compared to long COVID patients with fatigue and the COVID recovered control group in all studied brain areas except the globus pallidus (effect size range 0.7–1.5). The results showed no significant differences in glucose metabolism between patients with Long COVID and the COVID recovered control group in these regions. These findings suggest that long COVID fatigue may involve non-CNS systems, neurotransmitter imbalances, or psychological factors not captured by FDG-PET, while MS-related fatigue is associated with more severe frontal-striatal circuit dysfunction due to demyelination and neurodegeneration. Symmetrical standardized uptake values (SUVs) between hemispheres in all groups imply that fatigue in these conditions may be related to global or network-level alterations rather than hemisphere-specific changes. Future studies should employ fine-grained analysis methods, explore other brain regions, and control for confounding factors to better understand the pathophysiology of fatigue in MS and long COVID. Longitudinal studies tracking brain glucose metabolism in patients with Long COVID could provide insights into the evolution of metabolic patterns as the condition progresses. [ABSTRACT FROM AUTHOR]

Published

2024

44. Both Enantiomers of 2-Hydroxyglutarate Modulate the Metabolism of Cultured Human Neuroblastoma Cells.

Author

Gondáš, Eduard, Baranovičová, Eva, Bystrický, Peter, Šofranko, Jakub, Evinová, Andrea, Dohál, Matúš, Hatoková, Zuzana, and Murín, Radovan

Subjects

*PROTON magnetic resonance, *ANAEROBIC metabolism, *ESSENTIAL amino acids, *GENETIC regulation, BRAIN metabolism

Abstract

Elevated levels of D-2-hydroxyglutarate (D-2HG) and L-2-hydroxyglutarate (L-2HG) in the brain are associated with various pathological conditions, potentially contributing to neurological symptoms and neurodegeneration. Previous studies on animal models have revealed their capability to interfere with several cellular processes, including mitochondrial metabolism. Both enantiomers competitively inhibit the enzymatic activity of 2-oxoglutarate-dependent dioxygenases. These enzymes also execute several signaling cascades and regulate the level of covalent modifications on nucleic acids or proteins, e.g., methylation, hydroxylation, or ubiquitination, with an effect on epigenetic regulation of gene expression, protein stability, and intracellular signaling. To investigate the potential impact of 2HG enantiomers on human neuronal cells, we utilized the SH-SY5Y human neuroblastoma cell line as a model. We employed proton nuclear magnetic resonance (1H-NMR) spectroscopy of culture media that provided high-resolution insights into the changes in the content of metabolites. Concurrently, we performed biochemical assays to complement the 1H-NMR findings and to estimate the activities of lactate and 3-hydroxybutyrate dehydrogenases. Our results reveal that both 2HG enantiomers can influence the cellular metabolism of human neuroblastoma cells on multiple levels. Specifically, both enantiomers of 2HG comparably stimulate anaerobic metabolism of glucose and inhibit the uptake of several essential amino acids from the culture media. In this respect, both 2HG enantiomers decreased the catabolism capability of cells to incorporate the leucine-derived carbon atoms into their metabolism and to generate the ketone bodies. These results provide evidence that both enantiomers of 2HG have the potential to influence the metabolic and molecular aspects of human cells. Furthermore, we may propose that increased levels of 2HG enantiomers in the brain parenchyma may alter brain metabolism features, potentially contributing to the etiology of neurological symptoms in patients. [ABSTRACT FROM AUTHOR]

Published

2024

45. γ-Secretase activity, clinical features, and biomarkers of autosomal dominant Alzheimer's disease: cross-sectional and longitudinal analysis of the Dominantly Inherited Alzheimer Network observational study (DIAN-OBS).

Author

Schultz, Stephanie A, Liu, Lei, Schultz, Aaron P, Fitzpatrick, Colleen D, Levin, Raina, Bellier, Jean-Pierre, Shirzadi, Zahra, Joseph-Mathurin, Nelly, Chen, Charles D, Benzinger, Tammie L S, Day, Gregory S, Farlow, Martin R, Gordon, Brian A, Hassenstab, Jason J, Jack, Clifford R, Jucker, Mathias, Karch, Celeste M, Lee, Jae-Hong, Levin, Johannes, and Perrin, Richard J

Subjects

*ALZHEIMER'S disease, *MINI-Mental State Examination, *MEDICAL research, *NEURODEGENERATION, BRAIN metabolism

Abstract

Genetic variants that cause autosomal dominant Alzheimer's disease are highly penetrant but vary substantially regarding age at symptom onset (AAO), rates of cognitive decline, and biomarker changes. Most pathogenic variants that cause autosomal dominant Alzheimer's disease are in presenilin 1 (PSEN1), which encodes the catalytic core of γ-secretase, an enzyme complex that is crucial in production of amyloid β. We aimed to investigate whether the heterogeneity in AAO and biomarker trajectories in carriers of PSEN1 pathogenic variants could be predicted on the basis of the effects of individual PSEN1 variants on γ-secretase activity and amyloid β production. For this cross-sectional and longitudinal analysis, we used data from participants enrolled in the Dominantly Inherited Alzheimer Network observational study (DIAN-OBS) via the DIAN-OBS data freeze version 15 (data collected between Feb 29, 2008, and June 30, 2020). The data freeze included data from 20 study sites in research institutions, universities, hospitals, and clinics across Europe, North and South America, Asia, and Oceania. We included individuals with PSEN1 pathogenic variants for whom relevant genetic, clinical, imaging, and CSF data were available. PSEN1 pathogenic variants were characterised via genetically modified PSEN1 and PSEN2 double-knockout human embryonic kidney 293T cells and immunoassays for Aβ37, Aβ38, Aβ40, Aβ42, and Aβ43. A summary measure of γ-secretase activity (γ-secretase composite [GSC]) was calculated for each variant and compared with clinical history-derived AAO using correlation analyses. We used linear mixed-effect models to assess associations between GSC scores and multimodal-biomarker and clinical data from DIAN-OBS. We used separate models to assess associations with Clinical Dementia Rating Sum of Boxes (CDR-SB), Mini-Mental State Examination (MMSE), and Wechsler Memory Scale-Revised (WMS-R) Logical Memory Delayed Recall, [11C]Pittsburgh compound B (PiB)–PET and brain glucose metabolism using [18F] fluorodeoxyglucose (FDG)–PET, CSF Aβ42-to-Aβ40 ratio (Aβ42/40), CSF log 10 (phosphorylated tau 181), CSF log 10 (phosphorylated tau 217), and MRI-based hippocampal volume. Data were included from 190 people carrying PSEN1 pathogenic variants, among whom median age was 39·0 years (IQR 32·0 to 48·0) and AAO was 44·5 years (40·6 to 51·4). 109 (57%) of 190 carriers were female and 81 (43%) were male. Lower GSC values (ie, lower γ-secretase activity than wild-type PSEN1) were associated with earlier AAO (r =0·58; p<0·0001). GSC was associated with MMSE (β=0·08, SE 0·03; p=0·0043), CDR-SB (–0·05, 0·02; p=0·0027), and WMS-R Logical Memory Delayed Recall scores (0·09, 0·02; p=0·0006). Lower GSC values were associated with faster increase in PiB–PET signal (p=0·0054), more rapid decreases in hippocampal volume (4·19, 0·77; p<0·0001), MMSE (0·02, 0·01; p=0·0020), and WMS-R Logical Memory Delayed Recall (0·004, 0·001; p=0·0003). Our findings suggest that clinical heterogeneity in people with autosomal dominant Alzheimer's disease can be at least partly explained by different effects of PSEN1 variants on γ-secretase activity and amyloid β production. They support targeting γ-secretase as a therapeutic approach and suggest that cell-based models could be used to improve prediction of symptom onset. US National Institute on Aging, Alzheimer's Association, German Center for Neurodegenerative Diseases, Raul Carrea Institute for Neurological Research, Japan Agency for Medical Research and Development, Korea Health Industry Development Institute, South Korean Ministry of Health and Welfare, South Korean Ministry of Science and ICT, and Spanish Institute of Health Carlos III. [ABSTRACT FROM AUTHOR]

Published

2024

46. Molecular underpinnings underlying behaviors changes in the brain of juvenile common carp (Cyrinus carpio) in response to warming.

Author

Zhao, Yuanli, Duan, Ming, Lin, Xing, Li, Weiwei, Liu, Hairong, Meng, Kaifeng, Liu, Fei, Hu, Wei, and Luo, Daji

Subjects

*CENTRAL nervous system, *CARP, *NERVOUS system, *GLOBAL warming, BRAIN metabolism

Abstract

[Display omitted] • Warming impacted both individual and group behavior in juvenile C. carpio. • Long-term warming had a more pronounced impact on the decline of swimming activity. • Transcriptomics revealed that warming affected cytoskeletal organization, mitochondrial regulation, and energy metabolism in brain. • Synaptic transmission and signal transduction pathways were the key signature to explain behavior changes under warming. Global warming is increasing interest in how aquatic animals can adjust their physiological performance and cope with temperature changes. Therefore, understanding the behavioral changes and molecular underpinnings in fish under warming is crucial for both the individual and groups survival. This could provide experimental evidence and resource for evaluating the impact of global warming. Three genetic families of common carp (Cyprinus carpio) were generated. These juveniles were constructed short-term (4 days) and long-term (30 days) warming groups to investigate the effects of warming on behavioral responses and to elucidate the potential underlying mechanisms of warming-driven behavior. Behavioral tests were used to explore the effects of short- and long-term exposure to warming on the swimming behavior of C. carpio. Brain transcriptome combined with measurement of nervous system activity was used to further investigated the comprehensive neuromolecular mechanisms under warming. Long-term warming groups had a more significant impact on the decline of swimming behavior in juvenile C. carpio. Furthermore, brain comparative transcriptomic analysis combined with measurement of nervous system activity revealed that genes involved in cytoskeletal organization, mitochondrial regulation, and energy metabolism are major regulators of behavior in the juvenile under warming. Importantly, especially in the long-term warming groups, enrichment analysis of associated gene expression suggested functional alterations of synaptic transmission and signal transduction leading to swimming function impairment in the central nervous system, as revealed by behavioral tests. Our study provides evidence of the neurogenomic mechanism underlying the decreased swimming activity in juvenile C. carpio under warming. These findings have important implications for understanding the impacts of climate change on aquatic ecosystems and the organisms that inhabit them. [ABSTRACT FROM AUTHOR]

Published

2024

47. High‐field downfield MR spectroscopic imaging in the human brain.

Author

Özdemir, İpek, Etyemez, Semra, and Barker, Peter B.

Subjects

SPECTROSCOPIC imaging, MAGNETIC resonance imaging, CORPUS callosum, BRAIN metabolism, BRAIN tumors

Abstract

Purpose: To investigate the feasibility of downfield MR spectroscopic imaging (DF‐MRSI) in the human brain at 7T. Methods: A 7T DF‐MRSI pulse sequence was implemented based on the previously described methodology at 3T, with 3D phase‐encoding, 13‾31‾$$ 1\overline{3}3\overline{1} $$ spectral‐spatial excitation, and frequency selective refocusing. Data were pre‐processed followed by analysis using the "LCModel" software package, and metabolite maps created from the LCModel results. Total scan time, including brain MRI and a water‐reference MRSI, was 24 min. The sequence was tested in 10 normal volunteers. Estimated metabolite levels and uncertainty values (Cramer Rao lower bounds, CRLBs) for nine downfield peaks were compared between seven different brain regions, anterior cingulate cortex (ACC), centrum semiovale (CSO), corpus callosum (CC), cerebellar vermis (CV), dorsolateral prefrontal cortex (DLPFC), posterior cingulate cortex (PCC), and thalamus (Thal). Results: DF peaks were relatively uniformly distributed throughout the brain, with only a small number of peaks showing any significant regional variations. Most DF peaks had average CRLB<25% in most brain regions. Average SNR values were higher for the brain regions ACC and DLPFC (˜7 ± 0.95, mean ± SD) while in a range of 3.4–6.0 for other brain regions. Average linewidth (FWHM) values were greater than 35 Hz in the ACC, CV, and Thal, and 22 Hz in CC, CSO, DLPFC, and PCC. Conclusion: High‐field DF‐MRSI is able to spatially map exchangeable protons in the human brain at high resolution and with near whole‐brain coverage in acceptable scan times, and in the future may be used to study metabolism of brain tumors or other neuropathological disorders. [ABSTRACT FROM AUTHOR]

Published

2024

48. Exploring the translational impact of type 1 diabetes on cerebral neurovascular function through ECoG-LSCI.

Author

Yen, Shaoyu, Wang, Yuhling, and Liao, Lun-De

Subjects

TYPE 1 diabetes, SPREADING cortical depression, SPECKLE interference, CEREBRAL circulation, BRAIN metabolism, BRAIN physiology

Abstract

Type 1 diabetes mellitus (T1DM) can result in complications such as retinopathy, nephropathy, and peripheral neuropathy, which can lead to brain dysfunction. In this study, we investigated the effects of T1DM on cerebral neurovascular function in mice. Streptozotocin (STZ) is known to induce T1DM in animals; thus, we used an STZ-induced diabetes model to evaluate the effects of hyperglycemia on brain morphology and neurovascular tissue. Neurovascular coupling is the connection between neuronal activity and cerebral blood flow that maintains brain function. The ECoG-LSCI technique combines electrocorticography (ECoG) and laser speckle contrast imaging (LSCI) to detect cortical spreading depression (CSD) as a marker of neurovascular coupling and measure corresponding neurovascular function. Our results suggested that in the STZ group, hyperglycemia affected excitatory neurotransmission and metabolism, leading to reductions in intercellular signaling, somatosensory evoked potential (SSEP) amplitudes, and CSD transmission rates. Western blot data further revealed that brain-derived neurotrophic factor (BDNF) and neuronal nuclear antigen levels were reduced in the STZ group. Abnormalities in glucose metabolism in the brain and increased phosphorylation of AKT and GSK3 are hypothesized to be responsible for these decreases. Overall, this study highlights the importance of glucose metabolism in normal brain physiology and demonstrates that hyperglycemia disrupts neurovascular coupling and affects cerebral neurovascular function and that the degree of CSD is positively correlated with the extent of brain tissue damage. Further research is essential to gain a complete understanding of the related mechanisms and the implications of these findings. [ABSTRACT FROM AUTHOR]

Published

2024

49. Unraveling the Liver–Brain Axis: Resveratrol's Modulation of Key Enzymes in Stress-Related Anxiety.

Author

Tseilikman, Vadim E., Tseilikman, Olga B., Shevyrin, Vadim A., Yegorov, Oleg N., Epitashvili, Alexandr A., Aristov, Maxim R., Karpenko, Marina N., Lipatov, Ilya A., Pashkov, Anton A., Shamshurin, Maxim V., Buksha, Irina A., Shonina, Anna K., Kolesnikova, Alexandra, Shatilov, Vladislav A., Zhukov, Maxim S., and Novak, Jurica

Subjects

MONOAMINE oxidase, POST-traumatic stress disorder, LABORATORY rats, PSYCHOLOGICAL stress, BRAIN metabolism

Abstract

Stress-related anxiety disorders and anxiety-like behavior in post-traumatic stress disorder (PTSD) are associated with altered neurocircuitry pathways, neurotransmitter systems, and the activities of monoamine and glucocorticoid-metabolizing enzymes. Resveratrol, a natural polyphenol, is recognized for its antioxidant, anti-inflammatory, and antipsychiatric properties. Previous studies suggest that resveratrol reduces anxiety-like behavior in animal PTSD models by downregulating key enzymes such as 11 β -hydroxysteroid dehydrogenase type 1 (11 β -HSD-1) and monoamine oxidases (MAOs). However, the underlying mechanisms remain unclear. In this study, we explored the efficacy of resveratrol in treating stress-induced anxiety using a chronic predator stress model in rats. Resveratrol was administered intraperitoneally at 100 mg/kg following a 10-day stress exposure, and anxiety behavior was assessed with an elevated plus maze. Our results indicated that stress-related anxiety correlated with increased activities of brain MAO-A, MAO-B, and hepatic 11 β -HSD-1, alongside elevated oxidative stress markers in the brain and liver. Resveratrol treatment improved anxiety behavior and decreased enzyme activities, oxidative stress, and hepatic damage. We demonstrate that resveratrol exerts antianxiogenic effects by modulating glucocorticoid and monoamine metabolism in the brain and liver. These findings suggest resveratrol's potential as a therapeutic agent for anxiety disorders, warranting further clinical investigation. [ABSTRACT FROM AUTHOR]

Published

2024

50. Differences in subcortical functional connectivity in patients with epilepsy.

Author

Hryniewicz, Nikodem, Rola, Rafał, Ryglewicz, Danuta, Piątkowska-Janko, Ewa, Sawilska, Ada, and Bogorodzki, Piotr

Subjects

FUNCTIONAL magnetic resonance imaging, PARTIAL epilepsy, CENTRAL nervous system, FUNCTIONAL connectivity, BRAIN metabolism, EPILEPSY

Abstract

Introduction. Epilepsy is a disease characterized by abnormal paroxysmal bioelectrical activity in the brain cortex and subcortical structures. Seizures per se change brain metabolism in epileptic focus and in distal parts of the brain. However, interictal phenomena can also affect functional connectivity (FC) and brain metabolism in other parts of the brain. Aim of study. We hypothesised that epilepsy affects functional connectivity not only among cortical, but also between subcortical, structures of the brain in a resting state condition. Clinical rationale for study. Investigating functional connectivity in patients with epilepsy could provide insights into the underlying pathophysiological mechanisms. Better understanding may lead to more effective treatment strategies. Material and methods. Functional connectivity was analysed in 35 patients with epilepsy and in 28 healthy volunteers. The group of patients was divided into generalised and focal epilepsy (temporal and extratemporal subgroups). Each patient and healthy volunteer underwent an fMRI resting-state session. During the study, EEG signals were simultaneously recorded with fMRI to facilitate the subsequent detection of potential interictal epileptiform discharges (IEDs). Their potential impact on BOLD signals was mitigated through linear regression. The data was processed and correlation coefficients (FC values) between the BOLD signal from selected structures of the central nervous system were determined and compared between study groups. The results were presented as significant differences in correlation coefficients between brain/subcortical structures in the epilepsy and control groups. Results. Lower FC values for the epilepsy group compared to the control group were shown for connections related to the MPFC, hippocampus, thalamus, amygdala, and the parahippocampal gyrus. Conclusions. Epilepsy alters the functional connectivity of resting state subcortical networks. Patterns of pathological changes of FC differ between epilepsy subtypes, with predominant lower FC between the hippocampus, parahippocampal gyrus, amygdala and thalamus in patients with epilepsy. Clinical implications. This study suggests that epilepsy affects subcortical structures. Identifying distinct patterns of altered FC in epilepsy subtypes may help to tailor treatment strategies. Changes in FC detected by fMRI may precede clinical symptoms, aiding in the early diagnosis of cognitive and emotional disorders in focal epilepsy. [ABSTRACT FROM AUTHOR]

Published

2024