The antipsychotic olanzapine reduces memory deficits and neuronal abnormalities in a male rat model of Autism.

The prevalence of autism spectrum disorder (ASD), a neurodevelopmental condition that impacts social interaction and sensory processing, is rising. Valproic acid (VPA) exposure during pregnancy causes autistic-like traits in offspring. Olanzapine (OLZ), an atypical antipsychotic, is used to treat ASD. We assessed the impact of OLZ on behavior, neuromorphology, and nitric oxide (NO) levels in the hippocampus using prenatal VPA treatment in rats. It is commonly known that ASD patients exhibit sensory abnormalities. As such, we utilized the tail flick test to validate the ASD model. In the novel object recognition test (NORT), VPA exposure reduces the discrimination index (DI) in the first introduction to the novel object. Moreover, OLZ and vehicle-treated rats perform differently in the second exposition to the DI of the novel object, suggesting that OLZ reverses VPA-induced deficits in recognition memory. The latency to find the hidden platform in the Morris water maze test of memory and learning improves in VPA-exposed rats after OLZ administration, indicating that OLZ improves spatial memory in these rats. Administration of prenatal VPA induces neuronal hypotrophy and reduces spine density in pyramidal neurons of the CA1 region of the hippocampus. Treatment with OLZ corrects the neuromorphological changes brought on by VPA. In the CA1 region of the hippocampus, VPA treatment increases the number of neurons, which normalizes with OLZ treatment. OLZ increases the NO levels in the dorsal hippocampus in control rats. In rats exposed to VPA, the second-generation antipsychotic OLZ reduces memory-related and neuroplastic alterations. The current findings support the use of OLZ in this illness and further validate the use of prenatal VPA as a model of ASD.

Cellular mechanisms in brain aging: Focus on physiological and pathological aging.

Aging is a natural phenomenon characterized by accumulation of cellular damage and debris. Oxidative stress, cellular senescence, sustained inflammation, and DNA damage are the main cellular processes characteristic of aging associated with morphological and functional decline. These effects tend to be more pronounced in tissues with high metabolic rates such as the brain, mainly in regions such as the prefrontal cortex, hippocampus, and amygdala. These regions are highly related to cognitive behavior, and therefore their atrophy usually leads to decline in processes such as memory and learning. These cognitive declines can occur in physiological aging and are exacerbated in pathological aging. In this article, we review the cellular processes that underlie the triggers of aging and how they relate to one another, causing the atrophy of nerve tissue that is typical of aging. The main topic of this review to determine the central factor that triggers all the cellular processes that lead to cellular aging and discriminate between normal and pathological aging. Finally, we review how the use of supplements with antioxidant and anti-inflammatory properties reduces the cognitive decline typical of aging, which reinforces the hypothesis of oxidative stress and cellular damage as contributors of physiological atrophy of aging. Moreover, cumulative evidence suggests their possible use as therapies, which improve the aging population's quality of life.

Memory and dendritic spines loss, and dynamic dendritic spines changes are age-dependent in the rat.

Brain aging is a widely studied process, but due to its complexity, much of its progress is unknown. There are many studies linking memory loss and reduced interneuronal communication with brain aging. However, only a few studies compare young and old animals. In the present study, in male rats aged 3, 6, and 18 months, we analyzed the locomotor activity and also short and long-term memory using the novel object recognition test (NORT), in addition to evaluating the dendritic length and the number of dendritic spines in the prefrontal cortex (PFC) and in the CA1, CA3 and DG regions of the dorsal hippocampus using Golgi-Cox staining. We also analyzed the types of dendritic spines in the aforementioned regions. 6- and 18-month old animals showed a reduction in locomotor activity, while long-term memory deficit was observed in 18-month old rats. At 18 months old, the dendritic length was reduced in all the studied regions. The dendritic spine number was also reduced in layer 5 of the PFC, and the CA1 and CA3 of the hippocampus. The dynamics of dendritic spines changed with age, with a reduction of the mushroom spines in all the studied regions, with an increase of the stubby spines in all the studied regions except from the CA3 region, that showed a reduction. Our data suggest that age causes changes in behavior, which may be the result of morphological changes at the dendrite level, both in their length and in the dynamics of their spines.

Cerebrolysin ameliorates prefrontal cortex and hippocampus neural atrophy of spontaneous hypertensive rats with hyperglycemia.

Hyperglycemia of diabetes mellitus causes damage at the vascular level, which at the renal level represents diabetic nephropathy. In this pathology, there is arterial hypertension. In addition, several reports suggest that hyperglycemia and arterial hypertension affect interneuronal communication at the level of dendritic morphology. We studied these changes in an animal model with streptozotocin-induced diabetes mellitus in the spontaneous hypertensive (SH) rat. Recent reports from our laboratory have demonstrated that cerebrolysin (CBL), a preparation of neuropeptides with protective and repairing properties, reduces dendritic deterioration in both pathologies, in separate studies. In the present study, we evaluated the effect of CBL using the animal model with hyperglycemia and arterial hypertension and assessed the dendritic morphology using a Golgi-Cox staining procedure. Our results suggest that CBL ameliorated the reduction in the number of dendritic spines in the PFC and hippocampus caused by hyperglycemia in the SH rat. In addition, CBL also increased distal dendritic length in the PFC and hippocampus in hyperglycemic SH rats. Consequently, the CBL could be a therapeutic tool used to reduce the damage at the level of dendritic communication present in both pathologies.