Longitudinal <sup>1</sup>H MRS of rat forebrain from infancy to adulthood reveals adolescence as a distinctive phase of neurometabolite development

Morgan, Jonathan J.; Kleven, Gale A.; Tulbert, Christina D.; Olson, John D.; Horita, David A.; Ronca, April E.

doi:10.1002/nbm.2913

Cited by 17 publications

(13 citation statements)

References 66 publications

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“…Although based on the work from Morgan and colleagues [69], the time frame in our study may be sufficient to reflect brain metabolite changes; however, others [70] have shown that in animals born with depletion in omega 3 fatty acids, the effects could possibly be reversed with supplemental diet when the supplementation was given from birth, but when the diet was given starting at weaning, recovery was only partial [70]. The onset of feeding (at weaning) and the duration of the diet (almost 6 weeks) may account for the lack of significant behavioral differences.…”

Section: Discussionmentioning

confidence: 99%

Effect of diet on brain metabolites and behavior in spontaneously hypertensive rats

Navarro¹,

Sikoglu²,

Heinze³

et al. 2014

Behavioural Brain Research

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Attention–deficit hyperactivity disorder (ADHD) is a heterogeneous psychiatric disorder affecting 5-10% of children. One of the suggested mechanisms underlying the pathophysiology of ADHD is insufficient energy supply to neurons. Here, we investigated the role of omega 3 fatty acids in altering neural energy metabolism and behavior of spontaneously hypertensive rats (SHR), which is an animal model of ADHD. To this end, we employed Proton Magnetic Resonance Spectroscopy (1H MRS) to evaluate changes in brain neurochemistry in the SHR following consumption of one of three experimental diets (starting PND 21): Fish Oil Enriched (FOE), Regular (RD) and Animal Fat Enriched (AFE) diet. Behavioral tests were performed to evaluate differences in locomotor activity and risk-taking behavior (starting PND 44). Comparison of frontal lobe metabolites showed that increased amounts of omega 3 fatty acids decreased total Creatine levels (tCr), but did not change glutamate (Glu), total N-acetylaspartate (tNAA), Lactate (Lac), Choline (Cho) or Inositol (Ino) levels. Although behavior was not significantly affected by different diets, significant correlations were observed between brain metabolites and behavior in the open field and elevated plus maze. SHR with higher levels of brain tCr and Glu exhibited greater hyperactivity in a familiar environment. On the other hand, risk-taking exploration of the elevated plus maze's open arms correlated negatively with forebrain tNAA and Lac levels. These findings support the possible alteration in energy metabolites in ADHD, correlating with hyperactivity in the animal model. The data also suggest that omega 3 fatty acids alter brain energy and phospholipid metabolism.

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Section: Discussionmentioning

confidence: 99%

Effect of diet on brain metabolites and behavior in spontaneously hypertensive rats

Navarro¹,

Sikoglu²,

Heinze³

et al. 2014

Behavioural Brain Research

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“…The imaging sequence employed a TE of 13 ms and a TR of 1250 ms. Fifteen transverse slices and seven coronal slices (thickness, 2 mm) were obtained of the rat brain. A 5 × 5 × 5-mm 3 voxel was approximately centered in the brain, with its center a distance of approximately 6 mm from the surface. Effort was made to ensure that the voxel was located in a similar location in each rat, but no segmentation procedures were carried out.…”

Section: Methodsmentioning

confidence: 99%

“…Proton magnetic resonance spectroscopy ( 1 H MRS) studies of mouse and rat brain at high magnetic field strengths, such as 9.4 T, have been demonstrated to be useful for the study of a variety of animal models of disease 1 and of brain developmental changes. 2,3 Taurine (Tau) is a relevant brain metabolite in the study of brain tumors, the brain and its development. [4][5][6][7][8] At 9.4 T, the Tau resonance at 3.42 ppm is sufficiently well resolved from other metabolite peaks to be utilized for quantification.…”

Section: Introductionmentioning

confidence: 99%

“…The levels of Cho have been shown to be altered in MRS examinations investigating brain tumors, 14 hypomyelination 15 and postnatal mouse brain development. 16 The Cho peak in rat and mouse brain has been shown to contain significant signal contamination from the Tau resonance at about 3.25 ppm, even at a high field strength of 9.4 T. 17,18 The quantification of Cho has been performed by either relying on spectral fitting software, such as LCModel, 2,3 or by subtracting the area of the other Tau resonance at approximately 3.42 ppm from the combined Cho and Tau peak. 16,19 The latter method may suffer from subtraction errors and uncertainties from making the assumption that the two Tau resonances are identical in the experimentally acquired spectrum.…”

Section: Introductionmentioning

confidence: 99%

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Characterization of the response of taurine protons to PRESS at 9.4 T for Resolving choline and Determining taurine T₂

et al. 2016

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Point-resolved spectroscopy (PRESS), characterized by two TEs (TE1 and TE2 ), can be employed to perform animal magnetic resonance spectroscopy (MRS) studies at 9.4 T. Taurine (Tau) and choline (Cho) are relevant metabolites that can be measured by MRS. In this work, the response of the J-coupled protons of Tau as a function of PRESS TE1 and TE2 was characterized at 9.4 T to achieve two objectives. The first was to determine two TE1 and TE2 combinations that could be used to obtain T2 -corrected measures of Tau (3.42 ppm) that were minimally influenced by J coupling. The second was to exploit the Tau J coupling to find a timing combination that minimized the 3.25-ppm Tau signal to enable the Cho (3.22 ppm) resonance to be resolved from the overlapping Tau signal. The response of Tau protons was investigated both numerically and experimentally. It was numerically determined that the timings {TE1 , TE2 } = {17 ms, 10 ms} and {TE1 , TE2 } = {80 ms, 70 ms} yielded similar 3.42-ppm Tau resonance areas (5% difference), rendering them suitable for Tau T2 determination. {TE1 , TE2 } = {25 ms, 50 ms} was found to yield minimal 3.25-ppm Tau signal, reducing its interference with Cho. The efficacy of the timings was demonstrated on phantom solutions and in vivo in four Sprague Dawley rats. LCModel was employed to analyse the in vivo spectra and Tau T2 values were estimated by fitting the Tau peak areas obtained with {TE1 , TE2 } = {17 ms, 10 ms} and {TE1 , TE2 } = {80 ms, 70 ms} to a monoexponentially decaying function. An average Tau T2 of 106 ms (standard deviation, 12 ms) was obtained. LCModel analysis of rat spectra obtained with {TE1 , TE2 } = {25 ms, 50 ms} demonstrated negligible levels of Tau signal, compared with that obtained with short TE.

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“…A recent longitudinal magnetic resonance imaging (MRI) study in rats has also identified a peak in cortical thickness during adolescence and a continued increase in volume of cerebral cortex and striatum and myelination from adolescence to adulthood (until PND60) (Mengler et al 2014). Levels of striatal metabolites such as N-acetylaspartate (NAA), glutamate and glutamine have also been observed to increase from neonatal period through adolescence to adulthood as examined in a longitudinal magnetic resonance spectroscopy (MRS) study in rats (Morgan et al 2013). Detailed reviews on maturation of adolescent neuronal systems can be found elsewhere (Brenhouse and Andersen 2011;Lewis 1997;McCutcheon and Marinelli 2009;Spear 2000;Sturman and Moghaddam 2011;Wahlstrom et al 2010).…”

Section: Figure 1-1 Adolescence In Rodents and Neural Maturation Chanmentioning

confidence: 99%

Evaluating long-term consequences of adolescent antipsychotic exposure

Moe¹

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Antipsychotic drugs (APDs) are being used increasingly to treat a variety of conditions in adolescence. Accordingly there has been a dramatic increase in the prescription of APDs to adolescents over the past twenty years. Adolescence is an important postnatal developmental period in which major maturation changes occur in both brain structures and multiple neurotransmitter systems. Therefore, adolescence may represent a period of sensitivity to environmental perturbations including exposure to such pharmacological agents. The specific neurobiological consequences of APDs on the adolescent brain are however still poorly understood. The aim of the work presented in this thesis is to investigate how APD administration in adolescence can affect the immature adolescent brain, using a rodent model of adolescence.In this thesis, I examined chronic risperidone treatment (1.3 mg/kg/day for 21-22 days) in adolescent rats (postnatal day (PND) 36-PND56/57) with respect to short-and long-term neurobiological changes. Short-term alterations were measured either during or proximal to chronic treatment. Long-term effects were measured after a lengthy drug-free interval of 36 -60 days.Risperidone-induced neurobiological effects in adolescents were compared with those in adult rats (PND80-PND100/101) treated with the same risperidone regimen. Risperidone was chosen for detailed examination given this is the atypical APD that is most commonly prescribed to adolescents in the clinic. Behavioural effects were assessed using two well-validated tests for APD action, namely suppression of the conditioned avoidance response (CAR) and the horizontal bar test for catalepsy. Risperidone-induced changes in brain structures and metabolism of the nucleus accumbens (NAc) were examined with clinical comparable methods namely magnetic resonance imaging (MRI) and proton magnetic resonance spectroscopy ( 1 H MRS), respectively.Neurochemical alterations and gene expression in the NAc and the striatum were assessed with high performance liquid chromatography (HPLC) and real-time polymerase chain reaction respectively.My data reveal that, during chronic risperidone treatment, adolescent rats were less sensitive to risperidone-induced increases in catalepsy (when tested in horizontal bar test) and escape failures (when tested in CAR paradigm), both of which are striatum-dependent behaviours. By contrast, adult rats were observed to develop a progressive increase in these behaviours during chronic risperidone treatment. Accompanying these behavioural findings, increased levels of dopamine metabolites were observed selectively in the striatum of rats treated with risperidone in adolescence.Increased dopamine metabolites represent increased turnover of dopamine and/or increased dopamine availability, which both suggest increased dopaminergic signalling. Increased dopamine neurotransmission in adolescent-treated rats may overcome the behavioural effects of dopaminergic blockade by risperidone. When assessed after an equivalent drug-free interval o...

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Longitudinal ¹H MRS of rat forebrain from infancy to adulthood reveals adolescence as a distinctive phase of neurometabolite development

Cited by 17 publications

References 66 publications

Effect of diet on brain metabolites and behavior in spontaneously hypertensive rats

Effect of diet on brain metabolites and behavior in spontaneously hypertensive rats

Characterization of the response of taurine protons to PRESS at 9.4 T for Resolving choline and Determining taurine T₂

Evaluating long-term consequences of adolescent antipsychotic exposure

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Longitudinal 1H MRS of rat forebrain from infancy to adulthood reveals adolescence as a distinctive phase of neurometabolite development

Cited by 17 publications

References 66 publications

Effect of diet on brain metabolites and behavior in spontaneously hypertensive rats

Effect of diet on brain metabolites and behavior in spontaneously hypertensive rats

Characterization of the response of taurine protons to PRESS at 9.4 T for Resolving choline and Determining taurine T2

Evaluating long-term consequences of adolescent antipsychotic exposure

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Longitudinal ¹H MRS of rat forebrain from infancy to adulthood reveals adolescence as a distinctive phase of neurometabolite development

Characterization of the response of taurine protons to PRESS at 9.4 T for Resolving choline and Determining taurine T₂