Avaliação de parâmetros neuroquímicos em fatias de hipocampo de rato submetidas à privação de oxigênio e glicose

Hansel, Gisele

January 2009

Mesmo a isquemia sendo a terceira causa de morte em países industrializados, os mecanismos relacionados a esta doença ainda continuam polêmicos e obscuros. Utilizou-se a técnica de privação de oxigênio e glicose (OGD) em fatias do hipocampo de rato para investigar parâmetros mitocondriais, neurais, astrogliais e metabólicos no período de isquemia e durante o período de reoxigenação. Os resultados mostraram uma diminuição na atividade mitocondrial durante o período isquêmico que foi mantido durante todo o período de reoxigenação. Analisando o sobrenadante destas fatias submetidas à OGD, foi observado que os níveis de LDH, NSE e GFAP se elevaram. Com relação aos níveis de lactato, verificou-se sua diminuição durante todos os períodos. Os níveis de S100B estavam elevados somente durante o período de reoxigenação. Este aumento pode ser tanto um mecanismo de neuroproteção desta proteína frente ao insulto ou ainda uma liberação por dano celular astrocitário. Além disso, foi observado um grande aumento nos níveis de glutamato durante a isquemia e este aumento retornou no período de reoxigenação. Por fim, houve uma diminuição na captação de glutamato somente no período de reoxigenação. Todos estes resultados podem ser conseqüência de uma hiper-estimulação dos receptores glutamatérgicos devido ao insulto isquêmico. Em resumo, nosso estudo mostrou alterações em diversos parâmetros neuroquímicos específicos tanto no período isquêmico quanto na reoxigenação, mostrando que cada tipo celular, reage diferentemente frente ao insulto isquêmico na técnica de OGD in vitro. / Stroke is the third cause of mortality in industrialized countries, and the mechanisms related to this disease are polemic and unclear. Oxygen and glucose deprivation (OGD) in acute rat hippocampal slices was performed to investigate mitochondrial, neural, astroglial and metabolic neurochemical parameters at different ischemic and reoxygenation periods. Results showed the mitochondrial activity decrease due energy failure during ischemic insult and reoxygenation time. In the supernatant medium, LDH, NSE and glutamate levels were increased and the lactate decrease by the lack of energy observed in the ischemic period. Parameters such as GFAP, S100B and glutamate uptake suffered alterations only at the reoxygenation period. These results have shown the vulnerability of neurons facing ischemic insult. Meanwhile, it was also observed a delayed injure of astrocytes only at reoxygenation time, which demonstrate the difference between cell types at OGD. In summary, our finding has shown altered at specific neurochemical parameters in OGD in vitro which features the ischemic episodes and reoxygenation periods.

Glutamato

Fosfopiruvato hidratase

Isquemia

Proteína glial fibrilar ácida

Proteínas S100

Glutamate uptake

Glial fibrillary acid protein (GFAP)

Ischemia

Neuron-specific enolase (NSE)

Oxygen and glucose deprivation (OGD)

S100B

Avaliação de parâmetros neuroquímicos em fatias de hipocampo de rato submetidas à privação de oxigênio e glicose

Hansel, Gisele

January 2009

Mesmo a isquemia sendo a terceira causa de morte em países industrializados, os mecanismos relacionados a esta doença ainda continuam polêmicos e obscuros. Utilizou-se a técnica de privação de oxigênio e glicose (OGD) em fatias do hipocampo de rato para investigar parâmetros mitocondriais, neurais, astrogliais e metabólicos no período de isquemia e durante o período de reoxigenação. Os resultados mostraram uma diminuição na atividade mitocondrial durante o período isquêmico que foi mantido durante todo o período de reoxigenação. Analisando o sobrenadante destas fatias submetidas à OGD, foi observado que os níveis de LDH, NSE e GFAP se elevaram. Com relação aos níveis de lactato, verificou-se sua diminuição durante todos os períodos. Os níveis de S100B estavam elevados somente durante o período de reoxigenação. Este aumento pode ser tanto um mecanismo de neuroproteção desta proteína frente ao insulto ou ainda uma liberação por dano celular astrocitário. Além disso, foi observado um grande aumento nos níveis de glutamato durante a isquemia e este aumento retornou no período de reoxigenação. Por fim, houve uma diminuição na captação de glutamato somente no período de reoxigenação. Todos estes resultados podem ser conseqüência de uma hiper-estimulação dos receptores glutamatérgicos devido ao insulto isquêmico. Em resumo, nosso estudo mostrou alterações em diversos parâmetros neuroquímicos específicos tanto no período isquêmico quanto na reoxigenação, mostrando que cada tipo celular, reage diferentemente frente ao insulto isquêmico na técnica de OGD in vitro. / Stroke is the third cause of mortality in industrialized countries, and the mechanisms related to this disease are polemic and unclear. Oxygen and glucose deprivation (OGD) in acute rat hippocampal slices was performed to investigate mitochondrial, neural, astroglial and metabolic neurochemical parameters at different ischemic and reoxygenation periods. Results showed the mitochondrial activity decrease due energy failure during ischemic insult and reoxygenation time. In the supernatant medium, LDH, NSE and glutamate levels were increased and the lactate decrease by the lack of energy observed in the ischemic period. Parameters such as GFAP, S100B and glutamate uptake suffered alterations only at the reoxygenation period. These results have shown the vulnerability of neurons facing ischemic insult. Meanwhile, it was also observed a delayed injure of astrocytes only at reoxygenation time, which demonstrate the difference between cell types at OGD. In summary, our finding has shown altered at specific neurochemical parameters in OGD in vitro which features the ischemic episodes and reoxygenation periods.

Glutamato

Fosfopiruvato hidratase

Isquemia

Proteína glial fibrilar ácida

Proteínas S100

Glutamate uptake

Glial fibrillary acid protein (GFAP)

Ischemia

Neuron-specific enolase (NSE)

Oxygen and glucose deprivation (OGD)

S100B

Avaliação de parâmetros neuroquímicos em fatias de hipocampo de rato submetidas à privação de oxigênio e glicose

Hansel, Gisele

January 2009

Mesmo a isquemia sendo a terceira causa de morte em países industrializados, os mecanismos relacionados a esta doença ainda continuam polêmicos e obscuros. Utilizou-se a técnica de privação de oxigênio e glicose (OGD) em fatias do hipocampo de rato para investigar parâmetros mitocondriais, neurais, astrogliais e metabólicos no período de isquemia e durante o período de reoxigenação. Os resultados mostraram uma diminuição na atividade mitocondrial durante o período isquêmico que foi mantido durante todo o período de reoxigenação. Analisando o sobrenadante destas fatias submetidas à OGD, foi observado que os níveis de LDH, NSE e GFAP se elevaram. Com relação aos níveis de lactato, verificou-se sua diminuição durante todos os períodos. Os níveis de S100B estavam elevados somente durante o período de reoxigenação. Este aumento pode ser tanto um mecanismo de neuroproteção desta proteína frente ao insulto ou ainda uma liberação por dano celular astrocitário. Além disso, foi observado um grande aumento nos níveis de glutamato durante a isquemia e este aumento retornou no período de reoxigenação. Por fim, houve uma diminuição na captação de glutamato somente no período de reoxigenação. Todos estes resultados podem ser conseqüência de uma hiper-estimulação dos receptores glutamatérgicos devido ao insulto isquêmico. Em resumo, nosso estudo mostrou alterações em diversos parâmetros neuroquímicos específicos tanto no período isquêmico quanto na reoxigenação, mostrando que cada tipo celular, reage diferentemente frente ao insulto isquêmico na técnica de OGD in vitro. / Stroke is the third cause of mortality in industrialized countries, and the mechanisms related to this disease are polemic and unclear. Oxygen and glucose deprivation (OGD) in acute rat hippocampal slices was performed to investigate mitochondrial, neural, astroglial and metabolic neurochemical parameters at different ischemic and reoxygenation periods. Results showed the mitochondrial activity decrease due energy failure during ischemic insult and reoxygenation time. In the supernatant medium, LDH, NSE and glutamate levels were increased and the lactate decrease by the lack of energy observed in the ischemic period. Parameters such as GFAP, S100B and glutamate uptake suffered alterations only at the reoxygenation period. These results have shown the vulnerability of neurons facing ischemic insult. Meanwhile, it was also observed a delayed injure of astrocytes only at reoxygenation time, which demonstrate the difference between cell types at OGD. In summary, our finding has shown altered at specific neurochemical parameters in OGD in vitro which features the ischemic episodes and reoxygenation periods.

Glutamato

Fosfopiruvato hidratase

Isquemia

Proteína glial fibrilar ácida

Proteínas S100

Glutamate uptake

Glial fibrillary acid protein (GFAP)

Ischemia

Neuron-specific enolase (NSE)

Oxygen and glucose deprivation (OGD)

S100B

The effect of weight loss on circulating biomarkers of brain health and executive function

Herra, Lindsay Marie

04 June 2020

Obesity is associated with deficits in cognitive function, particularly within the domain of executive function (EF). EF refers to higher order cognitive processes that regulate our ability to sustain attention, inhibit subconscious tendencies, remember and manipulate information for immediate use, and remain cognitively flexible. Deficits in EF in overweight and obese individuals may impact the success of weight loss and maintenance efforts. Therefore, understanding the biological links between obesity and EF, as well as the ability to reverse EF deficits with weight loss, is imperative. The first study aimed to determine the effect of weight loss in overweight and obese, middle-aged and older adults on serum brain-derived neurotrophic fact (BDNF), S100 calcium binding protein B (S100B), and glial fibrillary acidic protein (GFAP). Serum samples (n=21; 50-75 years, BMI 25-40 kg/m2) were pooled from two prior weight loss studies. Fasting blood measurements were taken before and after 8- or 12-weeks of hypocaloric diet-induced weight loss (1200 or 1500 kcal/d). Body Mass Index (BMI), body weight, waist circumference, and percent body fat (All p<0.001) decreased with weight loss. Serum BDNF (p=0.871), S100B (p=0.898), and GFAP (p=0.506) did not change following weight loss. The second study aimed to determine the correlation between the magnitude of change in serum BDNF, S100B, and GFAP and the magnitude of improvement in EF performance on three computer-based tests. Participants (n=8; 50-75 years, BMI 25-40 kg/m2) completed 4-weeks of hypocaloric diet-induced weight loss (1200 or 1500 kcal/d), followed by 4-weeks of weight maintenance (hypocaloric diet + steps/d goal). Fasting blood and EF measurements were completed at baseline, and weeks 4 and 8. BMI (p=0.001), body weight (p=0.001), waist circumference (p=0.002), and percent body fat (p=0.001) decreased from baseline to week 8. Serum BDNF (p=0.359), S100B (p=0.277), and GFAP (p=0.585) did not change following weight loss. Go/No-Go (GNG) errors of commission (p=0.009) and AX-Continuous Performance Test (AX-CPT) correct response time (p=0.041) decreased following the weight loss. The change in serum GFAP was inversely correlated with GNG errors of omission (r=-0.716, p=0.046) and AX-CPT correct hits (r=-0.737, p=0.037), and positively correlated with AX-CPT correct response time (r=0.859, p=0.006). In conclusion, although weight loss does not influence serum BDNF, S100B, or GFAP levels, it may have a positive effect on inhibitory control in overweight and obese, middle-aged and older adults. Further research is needed to understand the relationship between serum BDNF, S100B, and GFAP and executive function. / Master of Science / Obesity is associated with lower brain function, particularly in executive function (EF). EF refers to advanced thought processes that help to maintain focus, practice self-control, solve problems, and easily switch between tasks. Lower EF in individuals with overweight and obesity may impact the success of weight loss and maintenance efforts. Because of this, understanding body processes that may link obesity and lower EF, as well as the ability to improve EF with weight loss, is very important. The first study aimed to determine the effect of weight loss on blood proteins responsible for brain health: brain-derived neurotrophic fact (BDNF), S100 calcium binding protein B (S100B), and glial fibrillary acidic protein (GFAP). Twenty-one blood samples from overweight and obese, middle-aged and older adults were combined from two completed weight loss studies. In these studies, blood was measured before and after 8- or 12-weeks of a weight loss (low calorie diet;1200 or 1500 Calories per day). Body Mass Index (BMI), body weight, waist circumference, and percent body fat all decreased with weight loss; however, levels of BDNF, S100B, and GFAP in the blood did not change. The second study aimed to determine the relationship between blood BDNF, S100B, and GFAP and performance on three computer-based tests of EF before and after weight loss. Eight overweight and obese, middle-aged and older adults completed 4-weeks of weight loss (low-calorie diet; 1200 or 1500 Calories per day), followed by 4-weeks of weight maintenance. BMI, body weight, waist circumference, and percent body fat all decreased following the weight loss and maintenance intervention (week 8). Blood BDNF, S100B, and GFAP levels did not change, but performance on two EF measures improved: participants made less errors of commission (doing something when not supposed to) and had faster reaction time following the intervention, indicating better self-control. Additionally, greater increases in GFAP were associated with less errors of omission (not doing something when supposed to), fewer correct responses, and slower reaction time. In conclusion, although weight loss did not affect blood BDNF, S100B, or GFAP levels, it may improve self-control in overweight and obese, middle-aged and older adults. Further research is needed to understand the relationship between weight loss, blood proteins of brain health, and EF.

Obesity

older adults

cognitive function

executive function

brain-derived neurotrophic factor (BDNF)

calcium binding protein B (S100B)

glial-fibrillary acid protein (GFAP)