Acute physical exercise prevents memory amnesia caused by protein synthesis inhibition in rats' hippocampus.

The benefits of physical exercise (PE) on memory consolidation have been well-documented in both healthy and memory-impaired animals. However, the underlying mechanisms through which PE exerts these effects are still unclear. In this study, we aimed to investigate the role of hippocampal protein synthesis in memory modulation by acute PE in rats. After novel object recognition (NOR) training, rats were subjected to a 30-min moderate-intensity acute PE on the treadmill, while control animals did not undergo any procedures. Using anisomycin (ANI) and rapamycin (RAPA), compounds that inhibit protein synthesis through different mechanisms, we manipulated protein synthesis in the CA1 region of the hippocampus to examine its contribution to memory consolidation. Memory was assessed on days 1, 7, and 14 post-training. Our results showed that inhibiting protein synthesis by ANI or RAPA impaired NOR memory consolidation in control animals. However, acute PE prevented this impairment without affecting memory persistence. We also evaluated brain-derived neurotrophic factor (BDNF) levels after acute PE at 0.5h, 2h, and 12h afterward and found no differences in levels compared to animals that did not engage in acute PE or were only habituated to the treadmill. Therefore, our findings suggest that acute PE could serve as a non-pharmacological intervention to enhance memory consolidation and prevent memory loss in conditions associated with hippocampal protein synthesis inhibition. This mechanism appears not to depend on BDNF synthesis in the early hours after exercise.

Egg White Hydrolysate Mitigates Cadmium-induced Neurological Disorders and Oxidative Damage.

We aimed to investigate whether the consumption of Egg White Hydrolysate (EWH) acts on nervous system disorders induced by exposure to Cadmium (Cd) in rats. Male Wistar rats were divided into (a) Control (Ct): H2O by gavage for 28 days + H2O (i.p. - 15th - 28th day); (b) Cadmium (Cd): H2O by gavage + CdCl2 - 1 mg/kg/day (i.p. - 15th - 28th day); (c) EWH 14d: EWH 1 g/kg/day by gavage for 14 days + H2O (i.p.- 15th - 28th day); (d) Cd + EWH cotreatment (Cd + EWHco): CdCl2 + EWH for 14 days; (e) EWH 28d: EWH for 28 days; (f) EWHpre + Cd: EWH (1st - 28th day) + CdCl2 (15th - 28th day). At the beginning and the end of treatment, neuromotor performance (Neurological Deficit Scale); motor function (Rota-Rod test); ability to move and explore (Open Field test); thermal sensitivity (Hot Plate test); and state of anxiety (Elevated Maze test) were tested. The antioxidant status in the cerebral cortex and the striatum were biochemically analyzed. Cd induces anxiety, and neuromotor, and thermal sensitivity deficits. EWH consumption prevented anxiety, neuromotor deficits, and alterations in thermal sensitivity, avoiding neuromotor deficits both when the administration was performed before or during Cd exposure. Both modes of administration reduced the levels of reactive species, and the lipid peroxidation increased by Cd and improved the striatum's antioxidant capacity. Pretreatment proved to be beneficial in preventing the reduction of SOD activity in the cortex. EWH could be used as a functional food with antioxidant properties capable of preventing neurological damage induced by Cd.

Acute physical exercise enhances memory persistence in female rats.

Memory is a complex cognitive process with distinct stages, such as acquisition, consolidation, and retrieval. The hippocampus plays a crucial role in memory consolidation and retrieval. Physical exercise (PE) has been shown to enhance memory and cognitive functions, but the available research is mainly developed with males. So, there is limited knowledge about acute PE's effects on females' memory. This study aimed to investigate the impact of acute PE on memory in female rats and explore potential sex differences in PE memory modulation. Forty-two female Wistar rats were subjected to a novel object recognition (NOR) task, with half of them undergoing a single session of 30 min of PE after the learning session (memory acquisition). Behavioral assessments showed that acute PE improved memory persistence in female rats, with increased discrimination of novel objects. Biochemical analysis revealed elevated noradrenaline levels in the hippocampus following acute PE and NOR training. Notably, the positive effects of acute PE on female rats' memory were similar to those previously observed in male rats. These findings suggest that acute PE can enhance memory in female rats and underscore the importance of considering sex differences in cognitive research. PE may offer a non-invasive strategy to promote cognitive health in both males and females.

Long-term impact of neuroscience outreach interventions on elementary students' knowledge.

Neuroeducation is characterized as a subarea of neuroscience that involves comprehending the teaching and learning processes and relating them to neuroanatomy, neurophysiology, and neuropsychology. The inclusion of some aspects of the neuroscience of learning in teachers' and students' formation, applying them in teaching-learning environments, contributes to the quality of education and impacts students' quality of life and health. Thus, the POPNEURO outreach program performs interventions with students and teachers of low-income schools to disseminate neuroscience concepts, relating them to the students' daily lives. This study reports the impact of these actions, assessed 1 yr after their conclusion. The results showed that the long-term impact of the activities carried out is, in general, positive. Even 1 yr after the activities end, students demonstrate knowledge about the neuroscience themes and satisfaction with participating.NEW & NOTEWORTHY This article reports on neuroscience disclosure activities performed with school students and describes their short- and long-term positive impact. Even 1 yr after the activities, students demonstrate knowledge about the themes worked on and satisfaction with the activities.

Supplementation with Manihot esculenta Crantz (Cassava) leaves' extract prevents recognition memory deficits and hippocampal antioxidant dysfunction induced by Amyloid-ß.

OBJECTIVE: The Manihot esculenta Crantz (Cassava) is a typical South American plant rich in nutrients and energetic compounds. Lately, our group has shown that non-pharmacological interventions with natural antioxidants present different neuroprotective effects on oxidative balance and memory deficits in AD-like animal models. Here, our objective was to evaluate the neuroprotective effects of Cassava leaves' extract (CAS) in an AD-like model induced by amyloid-beta (Aß) 25-35 peptide. METHODS: Male Wistar rats (n = 40; 60 days old) were subjected to 10 days of CAS supplementation; then, we injected 2 µL Aß 25-35 in the hippocampus by stereotaxic surgery. Ten days later, we evaluated object recognition (OR) memory. Cassavas' total polyphenols, flavonoids, and condensed tannins content were measured, as well as hippocampal lipid peroxidation and total antioxidant capacity. RESULTS: CAS protected against Aß-induced OR memory deficits. In addition, Aß promoted antioxidant capacity decrease, while CAS was able to prevent it, in addition to diminishing lipoperoxidation compared to Aß. DISCUSSION: We show that treatment with Cassava leaves' extract before AD induction prevents recognition memory deficits related to Aß hippocampal injection. At least part of these effects can be related to the Cassava leaves' extract supplementation effects on diminishing lipid peroxidation and preventing a decrease in the hippocampal total antioxidant capacity in the hippocampus of AD-like animals without adverse effects. Once cassavais a plant of warm and dry ground that can adapt to growon various soil types and seems to resist several insects, our results enable Cassava to be considered asa potential preventive intervention to avoid or minimizeAD-induced memory deficits worldwide.

Acute physical exercise improves recognition memory via locus coeruleus activation but not via ventral tegmental area activation.

Both animals and humans have been studied to explore the impact of acute physical exercise (PE) on memory. In rats, a single session of PE enhances the persistence of novel object recognition (NOR) memory, which depends on dopamine and noradrenaline activity in the hippocampus. However, limited research has examined the involvement of other brain regions in this phenomenon. In this study, we investigated the role of the ventral tegmental area (VTA) and locus coeruleus (LC) in modulating the persistence of NOR memory induced by acute PE. After NOR training, some animals underwent a 30 min treadmill PE session, followed by infusion of either vehicle (VEH) or muscimol (MUS) in either the VTA or LC. Other animals did not undergo PE and only received VEH, MUS, or NMDA within the same time window. We evaluated memory recall 1, 7, and 14 days later. Acute PE promoted memory persistence for up to 14 days afterward, similar to NMDA glutamatergic stimulation of the VTA or LC. Moreover, only the LC region was required for the memory improvement induced by acute PE since blocking this region with MUS impaired NOR encoding. Our findings suggest that acute PE can improve learning within a closed time window, and this effect depends on LC, but not VTA, activity.

Novelty facilitates the persistence of aversive memory extinction by dopamine regulation in the hippocampus and ventral tegmental area.

Aversive memory extinction comprises a novel learning that blocks retrieving a previously formed traumatic memory. In this sense, aversive memory extinction is an excellent tool for decreasing fear responses. However, this tool it's not effective in the long term because of original memory spontaneous recovery. Thus, searching for alternative strategies that strengthen extinction learning is essential. In the current study, we evaluated the effects of a novel context (i.e., novelty) exposure on aversive memory extinction enhancement over days and the dopaminergic system requirement. Given the purpose, experiments were conducted using 3-month-old male Wistar rats. Animals were trained in inhibitory avoidance (IA). Twenty-four hours later, rats were submitted to a weak extinction protocol. Still, 30 min before the first extinction session, animals were submitted to an exploration of a novel context for 5 min. After, memory retention and persistence were evaluated 24 h, 3, 7, 14, and 21 days later. The exposition of a novel context caused a decrease in aversive responses in all days analyzed and an increase in dopamine levels in the hippocampus. The intrahippocampal infusion of dopamine in the CA1 area or the stimulation of the ventral tegmental area (VTA) by a glutamatergic agonist (NMDA) showed similar effects of novelty. In contrast, VTA inhibition by a gabaergic agonist (muscimol) impaired the persistence of extinction learning induced by novelty exposition and caused a decrease in hippocampal dopamine levels. In summary, we show that novel context exposure promotes persistent aversive memory extinction, revealing the significant role of the dopaminergic system.

A 3-D-printed synaptic puzzle contributes to students' synaptic transmission comprehension.

We created the "3-dimensional synaptic puzzle" (3Dsp) as an educational resource for the physiology teaching of synaptic transmission (ST). In this study, we aimed to apply and evaluate the use of 3Dsp. For this, we divided 175 university students from public and private universities into two groups: 1) control (CT; students that were only exposed to traditional class or video lessons about ST), and; 2) test (3Dsp; students that were exposed to the 3Dsp practical class in addition to the traditional theoretical class). ST knowledge of students was evaluated before, immediately after, and 15 days after interventions. Additionally, students completed a questionnaire about their perception of teaching-learning methods used in physiology classes and their self-perception of engagement in the physiology content. The CT groups improved their ST knowledge score from pretest to immediate (P < 0.0001 for all groups) and late posttest (P < 0.0001 for all groups). 3Dsp groups also enhanced their score from pretest to immediate (P = 0.029 for public university students; P < 0.0001 for private university students) and late posttest (P < 0.0001 for all groups). We also observed improvement from the immediate to late posttest in the 3Dsp group from private universities (P < 0.001). Both private groups performed better in general ST and specific electrical synapse questions in the pretest and immediate posttest compared to the public CT group (P < 0.05 for all comparisons). More than 90% of the students from both universities affirmed that the 3Dsp contributed to their physiology comprehension and that they would recommend the use of the 3-D models to other teachers in their classes.NEW & NOTEWORTHY We included a 3-dimensional puzzle (3Dsp) of electrical and chemical synapses in the physiology of synaptic transmission (ST) teaching. After a traditional or video lesson class, students from private and public universities were oriented to use the educational resource. More than 90% of the students affirmed that the 3Dsp improved their comprehension of ST content.

Physiology faculty and student contributions to schoolteacher training in neuroscience: innovations during the COVID-19 pandemic.

Research investigating how the brain develops and learns profoundly impacts education. Understanding the brain mechanisms responsible for learning and memory and the factors that influence them, such as age, environment, emotions, and motivation, can transform educational strategies by contributing to the development of programs that optimize learning. Including neuroscience education in teachers' training requires teaching them a multidisciplinary approach to science, which presents a challenge. Furthermore, the potential educational advances from the incorporation of neuroscience into teachers' training are hindered by significant obstacles such as translating research into the classroom; this includes the spread of neuromyths and the products, practices, and programs based on them. Our group has 9 years of experience in developing courses for training teachers. However, in 2020 the world faced the COVID-19 pandemic, which imposed on society a new way of carrying out its daily activities, including teaching. This study reports the experiences of our group as we developed the ninth edition of the Neuroscience Applied to Education teachers' training in an online format that included synchronous and asynchronous activities. Sixty teachers participated in the course. The synchronous meetings lasted 1.5 h/wk and addressed different themes: neuroscience and education, neuroanatomy, neurophysiology, neurobiology of learning and memory, factors that interfere with learning, and pedagogical innovation. According to the teachers' perceptions, the course was fundamental for them in terms of acquiring new knowledge about neuroscience. Everyone agreed on the possible applicability of the concepts covered to improve their pedagogical practice and teaching environment.NEW & NOTEWORTHY This study reports the experience of developing the ninth edition of the Neuroscience Applied to Education course in an online format that included synchronous and asynchronous activities. Here we show that schoolteachers consider the course important for acquiring new knowledge about neuroscience and the applicability of the concepts covered to improve their pedagogical practice and teaching environment. The online format did not prejudice the experience, and the technologies used were well evaluated.

Neuroprotective effects of strength training in a neuroinflammatory animal model.

BACKGROUND: The preventive role of muscular strength on diminishing neuroinflammation is yet unknown. In this study, the role of the prophylactic muscular strength exercise was investigated in order to verify whether it would diminish cognitive alterations and modify the antioxidant intracellular scenery in an animal neuroinflammatory model in of the CA1 region of the hippocampus. METHODS: The animals received muscular strength training (SE) three times a week for eight weeks. Subsequently, the stereotaxic surgery was performed with an intra-hippocampal infusion of either saline solution (SAL) or lipopolysaccharide (LPS). Next, we performed the behavioral tests: object recognition and social recognition. Then, the animals were euthanized, and their hippocampus and prefrontal cortex were collected. In another moment, we performed the dosage of the antioxidant activity and histological analysis. RESULTS: The results showed that the muscular strength exercises could show a beneficial prophylactic effect in the cognitive deficiencies caused by acute neuroinflammation. Regarding oxidative stress, there was an increase in catalase enzyme activity (CAT) in the group (SE + LPS) compared to the control groups (p < 0.05). As for the cognitive alterations, there were found in the (SE + LPS) group, diminishing the mnemonic hazard of the discriminative and social memories compared to the control groups (p < 0.05). CONCLUSION: We concluded, therefore, that the exercise performed prophylactically presents a protective effect capable of minimizing such mnemonic deficits and increasing catalase enzyme activity in rats that suffered a local neuroinflammatory process in the hippocampus.

Concurrent exercise does not prevent recognition memory deficits induced by beta-amyloid in rats.

Alzheimer's disease affects thousands of people worldwide. Alternatives aiming to prevent the disease or reduce its symptoms include different physical exercise configurations. Here we investigate the potential of concurrent exercise to prevent recognition memory deficits in an Alzheimer's disease-like model induced by the hippocampal beta-amyloid (Aß) injection in Wistar rats. We demonstrate that the concurrent exercise, which included running and strength exercises performed in the same exercise session, is ineffective in preventing recognition memory deficits in the Aß rats. Besides, higher levels of reactive oxygen species were found in the concurrent exercise group's hippocampus. The running exercise administrated alone prevented recognition memory impairments.

Novelty promotes recognition memory persistence by D1 dopamine receptor and protein kinase A signalling in rat hippocampus.

Strategies for improving memory are increasingly studied, and exposure to a novel experience can be an efficient neuromodulator. Novelty effects on memory depend on D1-family dopamine receptors (D1Rs) activation. Here, we evaluated the novelty effect on memory persistence of Wistar rats and investigated the contribution of D1Rs and their signalling pathways by protein kinase A (PKA) and C (PKC). Animals with infusion cannulae inserted into the CA1 hippocampus area were trained on the novel object recognition (NOR) task, which involved exploring two different objects. After training, some rats received intrahippocampal infusions of vehicle or D1Rs agonist; others explored a novel environment for 5 min and were infused with a variety of drugs targeting D1Rs and their signalling pathways. We demonstrated that pharmacological stimulation of D1Rs or novelty exposure promoted NOR memory persistence for 14 days and that the novelty effect depended on D1Rs activation. To determine if the D1 and D5 receptor subtypes were necessary for the impact of novelty exposure on memory, we blocked or stimulated PKA or PKC-protein kinases activated mainly by D1 and D5, respectively. Only PKA inhibition impaired the effect of novelty on memory persistence. After novelty and D1Rs blocking, PKA but not PKC stimulation maintained the memory persistence effect. Thus, we concluded that novelty promoted memory persistence by a mechanism-dependent on activating hippocampal D1Rs and PKA pathway.

Report on the online course "Basic Concepts in Neurophysiology": a course promoted during the COVID-19 pandemic quarantine.

"Basic Concepts in Neurophysiology" was a 3-wk online course developed during six synchronous meetings combined with asynchronous activities. We proposed an active learning course that used free online platforms to teach physiology during a period in which undergraduates were not in classrooms or taking online classes due to the COVID-19 pandemic. Herein, we report the course organization and the students' involvement in, acceptance of, and evaluation of the course. To address the students' perceptions about these points, we sent a questionnaire to 49 participants who finished the course. We found that although most students (52.5%) had never taken a course with similar methods before, almost all of them (95%) liked the flipped class model. Additionally, a majority of the students (92.5%) said that the method increased their study frequency during the social distancing period, which is an important aspect to consider during this challenging time for both students and professors.

Multicomponent Training Prevents Memory Deficit Related to Amyloid-ß Protein-Induced Neurotoxicity.

BACKGROUND: Alzheimer's disease (AD) is characterized by the accumulation of the amyloid-ß peptide in the brain, leading to early oxidative stress and neurotoxicity. It has been suggested that physical exercise could be beneficial in preventing AD, but studies with multicomponent training are scanty. OBJECTIVE: Verify the effects of multicomponent exercise training to prevent deficits in recognition memory related to Aß neurotoxicity. METHODS: We subjected Wistar rats to multicomponent training (including aerobic and anaerobic physical exercise and cognitive exercise) and then infused amyloid-ß peptide into their hippocampus. RESULTS: We show that long-term multicomponent training prevents the amyloid-ß-associated neurotoxicity in the hippocampus. It reduces hippocampal lipid peroxidation, restores antioxidant capacity, and increases glutathione levels, finally preventing recognition memory deficits. CONCLUSION: Multicomponent training avoids memory deficits related to amyloid-ß neurotoxicity on an animal model.

Relating human physiology content to COVID-19: a strategy to keep students in touch with physiology in times of social distance due to pandemic.

In 2020 universities had to quickly implement remote education alternatives as a result of the social distancing due to the COVID-19 pandemic. To keep students engaged with the university, we implemented a teaching-learning model that relates physiology contents to the COVID-19 pandemic using online educational platforms. A 1-mo web course was proposed for health sciences students from the Federal University of Pampa. It included synchronous meetings twice a week and asynchronous activities using scientific articles, case studies, and interactive online tools. The students approved the methodology developed, assessing it as dynamic and innovative. They reported that the activity helped to better understand the relations between COVID-19 and physiological systems. The web course also contributed to the identification of reliable sources of news and stimulated the sharing of scientific content with their families. We concluded that the use of online platforms contextualizing the physiology content considering current events helps students in learning human physiology and improves their abilities to apply this information to their daily life, in this specific case, regarding the COVID-19 pandemic.

Student assessment of online tools to foster engagement during the COVID-19 quarantine.

As a result of the installation of the COVID-19 (coronavirus disease 19) pandemic, online education has become an important teaching alternative, and new challenges about how to teach were found. Here we report our experience in offering an online course to review Human Physiology. We proposed synchronous and asynchronous activities using different online tools to address topics considered key to understanding the different systems of human physiology. The students considered important the use of this type of methodology, which uses different online tools to help understand the Human Physiology contents. The students highlighted the use of the Lt platform, Zoom, Mentimeter, and YouTube as the preferred online tools to use in physiology learning.

On the role of the dopaminergic system in the memory deficits induced by maternal deprivation.

Previous researches showed that maternal deprivation (MD) leads to memory deficits that persist until adulthood. The hippocampus, an important brain structure involved in memory processes, receives dopaminergic afferents from other brain areas that modulate memory. Here we demonstrated that MD results in object recognition memory deficits that are reverted by intra-hippocampal stimulation of D1-dopaminergic receptor and peripheral administration of a dopamine precursor. The D1-dopaminergic receptor and peripheral administration of a dopamine precursor also promoted memory persistence in control rats.