Archives Italiennes De Biologie最新文献

Purpose: Spinal cord injury (SCI) is a condition that causes disturbances in normal sensory, motor, and autonomic functions. During SCI, damages occur such as, contusion, compression, distraction. The aim of this study was to investigate effects of the antioxidative thymoquinone on neuron and glia cells in SCI biochemically, immunohistochemically and ultrastructurally.

Methods: Male Sprague-Dawley rats were divided into Control, SCI and SCI + Thymoquinone groups. After T10- T11 laminectomy was performed, a metal weight of 15 grams was left down the spinal tube for spinal damage. Immediately after the trauma, the muscles and skin incision were sutured. Thymoquinone was given to the rats by gavage as 30mg/kg/21days. Tissues fixed in 10% formaldehyde, embedded in paraffin wax and immunstained with Caspase-9 and phosphorylated signal transducer and activator of transcription 3 (pSTAT-3) antibodies. Remaining were stored at -80oC for biochemistry. Frozen spinal cord tissues were placed in a phosphate buffer solution and homogenized, centrifuged then used to measure malondialdehyde (MDA) levels, glutathione peroxidase (GSH) and Myeloperoxidase (MPO).

Results: In the SCI group, MDA, MPO, neuronal degeneration, vascular dilatation, inflammation, apoptotic appearance in the nucleus, loss of membrane and cristae in mitochondria, and dilatation in the endoplasmic reticulum were observed due to degeneration in the neuron structure. In the electron microscopic examination of the trauma + thymoquinone group, the membranes of the nuclei of the glial cells were thick and euchromatin, and mitochondria were shortened in length. In the SCI group, pyknosis and apoptotic changes were observed in neuronal structures and nuclei of glia cells in the substantia grisea and substantia alba region, along with positive Caspase-9 activity. An increase in Caspase-9 activity was observed in endothelial cells in blood vessels. In the SCI + thymoquinone group, Caspase-9 expression was positive in some of the cells in the ependymal canal while the cuboidal cells showed a negative Caspase-9 reaction in the majority. A few degenerated neurons in the substantia grisea region showed a positive reaction with Caspase-9. In SCI group, pSTAT-3 expression was positive in degenerated ependymal cells, neuronal structures, and glia cells. pSTAT-3 expression was positive in the endothelium and surrounding aggregated cells of the enlarged blood vessels. In the SCI+ thymoquinone group, pSTAT-3 expression was negative in most of the bipolar and multipolar neuron structures and glial cells in ependymal cells, enlarged blood vessel endothelial cells.

Conclusions: It has been thought that thymoquinone application in spinal cord injuries may be an antioxidant that can be recommended as an alternative treatment in suppressing the apoptosis of neural cells by significantly reducing the inflammation process.

Purpose: Spinal cord injury (SCI) causes various neurological consequences that disrupt the structure of axons. The C/EBP Homologous Protein (CHOP) acts in neuronal death by apoptosis has been demonstrated in experimental models. Rosmarinic acid (RA) is a phenolic compound used for therapeutic purposes in many diseases. In this study, we investigated the therapeutic effect of Rosmarinic acid application on inflammation and apoptotic development after spinal cord injury.

Methods: Male Wistar albino rats (n: 24) were assigned to three group: control, SCI and SCI+ RA. All rats were fixed on the operating table after anesthesia, the skin of the thoracic region was opened with a midline incision and the paravertebral muscles were dissected and T10-T11 laminas were exposed. A cylindrical tube of 10 cm length was fixed to the area to be laminectomy. A metal weight of 15 grams was left down the tube. Spinal damage was created, skin incisions were sutured. 50 mg/kg rosmarinic acid was given orally for 7 days after the spinal injury. Spinal tissues were fixed in formaldehyde solution and processed for paraffin wax tissue protocol and 4-5 μm sections were taken with microtome for further immunohistochemical examination. Caspase-12 and CHOP antibodies were applied to sections. Remaining tissues were carried out in glutaraldehyde for the first fixation then in osmium tetroxide for the second. Tissues were kept in pure araldite and thin sections were taken for transmission electron microscope.

Results: Values of malondialdehyde (MDA), myeloperoxidase (MPO), glutathione peroxidase (GSH), neuronal degeneration, vascular dilation, inflammation, CHOP and Caspase-12 expression were increased in SCI group compared to control group. Only glutathione peroxidase content was decreased in SCI group. In SCI group, disruption of basement membrane structure in canalis ependymalis, degeneration in structures of unipolar bipolar and multipolar neurons, and apoptotic changes were seen with increased inflammation in the piamater region and positive CHOP expression in vascular endothelial cells. In SCI+RA group, reorganization of basement membrane pill in canalis ependymalis were observed with mild Caspase-12 activity in some canalis ependymal and glial cells. Also, moderate CHOP expression in multipolar and bipolar neurons and glia cells were observed.

Conclusions: The application of RA has a significant effect on preventing damage in SCI. It was thought that CHOP and Caspase-12 mediated oxidative stress could be a guide in showing the potential and therapeutic target to stop the apoptotic course after SCI injury.

Laurus nobilis is known in the field of herbal medicine and in vitro studies for its antibacterial, antifungal, anti- diabetes, and anti-inflammatory beneficial effects. Laurus nobilis tea consumption was investigated with regard to its effects on anxiety and stress in healthy individuals, measured by subjective tools and by plasmatic cortisol levels. The study included thirty healthy Tunisian volunteers aged between 20 and 57 years consuming Laurus nobilis infusion, prepared from 5g of dried Laurus nobilis leaves in 100 ml boiled water, once a day during 10 days. Plasma concentrations of serum cortisol were measured before Laurus nobilis consumption and at the end of the experiment. Laurus nobilis tea consumption significantly decreased the concentration of plasmatic cortisol ([cortisol] D0= 93.5± 43.01ng/mL, D11=72.23± 25.37, p=0.001). A statistically significant decrease in PSS and STAI scores (p=0.006 and p=0.002 respectively) was also noted.These findings highlight the decrease in blood cortisol levels, which means a possible positive effect on reducing the risk of stress related-diseases in healthy volunteers consuming Laurus nobilis tea. However, more powerful studies with extended treatment periods are required.

Purpose: In this clinical study, it was aimed to prospectively evaluate the cochlear nerve with brainstem evoked response audiometry (BERA) in terms of audiological ailments in patients with COVID-19. Although the relationship of COVID-19 with tinnitus and hearing loss has been investigated since the day this infectious respiratory disease emerged, its relationship with BERA has not been fully demonstrated from a neurological perspective.

Methods: It was carried out on a group of patients who had COVID-19 in the last 6 months between February and August 2021 in Diyarbakır Gazi Yaşargil Training and Research Hospital. Patients between the ages of 18-50, who applied to the otorhinolaryngology and neurology clinic and had COVID-19 in the last 6 months, were selected. The COVID-19 group of our study consisted of 30 patients, 18 males and 12 females, who had had COVID-19 disease in the last 6 months, and 30 healthy individuals, 16 males and 14 females, as the control group.

Results: In patients with COVID-19, the evaluation of the destruction of the cochlear nerve with BERA showed that there was a statistically significant prolongation in I-III and I-V interpeaks at 70, 80 and 90 db nhl.

Conclusions: Statistically significant prolongation of especially I-III and I-V Interpeaks in BERA showed that COVID-19 has the potential to cause neuropathy. We believe that the BERA test should be considered in the neurological evaluation of cochlear nerve damage in patients with COVID-19 as a differential diagnosis.

Increasing findings indicate that a dysfunction in the autophagy machinery is common during retinal degeneration. The present article provides evidence showing that an autophagy defect in the outer retinal layers is commonly described at the onset of retinal degeneration. These findings involve a number of structures placed at the border between the inner choroid and the outer retina encompassing the choriocapillaris, the Bruch's membrane, photoreceptors and Mueller cells. At the center of these anatomical substrates are placed cells forming the retinal pigment epithelium (RPE), where autophagy seems to play most of its effects. In fact, a failure of the autophagy flux is mostly severe at the level of RPE. Among various retinal degenerative disorders, age-related macular degeneration (AMD) is mostly affected by a damage to RPE, which can be reproduced by inhibiting the autophagy machinery and it can be counteracted by the activation of the autophagy pathway. In the present manuscript evidence is provided that such a severe impairment of retinal autophagy may be counteracted by administration of a number of phytochemicals, which possess a strong stimulatory activity on autophagy. Likewise, natural light stimulation administered in the form of pulsatile specific wavelengths is capable of inducing autophagy within the retina. This dual approach to stimulate autophagy is further strengthened by the interaction of light with phytochemicals which is shown to activate the chemical properties of these natural molecules in sustaining retinal integrity. The beneficial effects of photo-biomodulation combined with phytochemicals is based on the removal of toxic lipid, sugar and protein species along with the stimulation of mitochondrial turn-over. Additional effects of autophagy stimulation under the combined effects of nutraceuticals and light pulses are discussed concerning stimulation of retinal stem cells which partly correspond to a subpopulation of RPE cells.

The aim of this study was to investigate how the application of vitamin E affected the levels of chemical elements in the brain tissues of epilepsy-induced rats. The sample of 40 adult male rats was separated into 4 equal groups: Group 1: control, Group 2: vitamin E; Group 3: penicillin to promote epileptic form activity and Group 4: penicillin + vitamin E. After three months of treatment, an Atomic Absorption Spectrophotometer was used to analyze the presence of the elements in brain tissue sections (brain, brainstem, cerebellum) of the decapitated animals. The levels of magnesium in the groups that received vitamin E (G2 and 4) were significantly higher than in the control group (G1) and the first epilepsy group (G3) (p.05).Chrome and zinc levels in brain, brainstem, and cerebellum tissue of the two epilepsy groups (G3-4) decreased significantly compared to the control group (G1) and the vitamin E group (G2) (p.05). The levels of copper in the brainstem and lead in the cerebellum of the first epilepsy group (G3) were higher than in all other groups (p.05). The findings showed that the application of vitamin E in experimental epilepsy may have a limited effect on element metabolism in brain tissue. A decline in zinc levels in the brain, brainstem and cerebellum tissues in epilepsy groups constitutes another result of our study. This should be examined further to determine whether decreased levels of zinc play a role in epilepsy pathogenesis.

The present manuscript stems from evidence, which indicates that specific wavelength produce an activation of the autophagy pathway in the retina. These effects were recently reported to synergize with the autophagy-inducing properties of specific phytochemicals. The combined administration of photo-modulation and phytochemicals was recently shown to have a strong potential in eliciting the recovery in the course of retinal degeneration and it was suggested as a non-invasive approach named "Lugano protocol" to treat age-related macular degeneration (AMD). Recent translational findings indicate that the protective role of autophagy may extend also to acute neuronal injuries including traumatic neuronal damage. At the same time, very recent investigations indicate that autophagy activation and retinal anatomical recovery may benefit from sound exposure. Therefore, in the present study, the anatomical rescue of a traumatic neuronal loss at macular level was investigated in a patient with idiopathic macular hole by using a combined approach of physical and chemical non-invasive treatments. In detail, light exposure was administered in combination with sound pulses to the affected retina. This treatment was supplemented by phytochemicals known to act as autophagy inducers, which were administered orally for 6 months. This combined administration of light and sound with nutraceuticals reported here as Advanced Lugano's Protocol (ALP) produced a remarkable effect in the anatomical architecture of the retina affected by the macular hole. The anatomical recovery was almost complete at roughly one year after diagnosis and beginning of treatment. The structural healing of the macular hole was concomitant with a strong improvement of visual acuity and the disappearance of metamorphopsia. The present findings are discussed in the light of a synergism shown at neuronal level between light and sound in the presence of phytochemicals to stimulate autophagy and promote proliferation and neuronal differentiation of retinal stem cells.

In 1944, the physiologist Leão while studying epilepsy in the rabbit noticed a sudden temporary cessation of electrocorticographic (ECoG) activity accompanied with a large negative slow potential change recorded by extracellular electrodes, that is later known as spreading depolarizations (SDs). The depression of the brain electrical activity was slowly propagating through the cerebral cortex. The mechanism of propagation is still controversial. SDs and seizures are following each other interchangeably, yet the puzzle needs more investigation to be clarified. SDs have an obvious effect on blood-brain barrier integrity mainly through transcellular and paracellular routs, but not much known about that especially following traumatic brain injury (TBI). The cortical spreading depolarization (CSD) and the depression of brain activity have been recognized following a variety of neurological diseases and brain injuries. CSD has been studied in animal models and recently in humans, and it has been recognized and described as a massive neuronal depolarization accompanied with high level of disturbances in transmembrane ion gradients and significant changes in cerebral blood flow (1-3). Although there is a considerable amount of literatures on SD have been done since 1944, but the biophysical mechanism of SD, the long term effect on the brain structures and functions, and it is role in different disorders are still incompletely understood.Here, we summarize the history of spreading depolarization and the most accepted hypothesis for mechanism of initiation and propagation of that phenomenon. Most importantly, we present the most updated research on the relationship and interaction between spreading depolarization and traumatic brain injuries, seizure, blood-brain barrier, neurovascular coupling, and other neurological conditions. Learning more about the spreading depolarization will increase our understanding about that phenomenon and may explain its association with different clinical presentations.

Purpose: This study aims to evaluate the changes in brain tissue and blood-brain barrier due to oxidative stress during cadmium (Cd) poisoning by biochemical, histopathological, and immunohistochemical methods. Methods: 170-190 g weighing eight-week-old female Wistar albino rats were divided into two groups (control and experimental), with 7 animals in each group. Experimental group rats were given 2 mg/kg/day powdered cadmium chloride dissolved in water intraperitoneally every day for two weeks. Biochemical, histopathological and immunohistochemical examination was performed.Results: It was seen that brain malondialdehyde (MDA) levels increased significantly, and glutathione (GSH) and catalase (CAT) activity levels decreased. In addition to degeneration in some pyramidal cells and glial cells, deformity, and picnosis in the nucleus, dilation of the meninges and cortex vessels, and inflammation around the blood vessels were observed. An increase was found in ionized calcium binding adaptor molecule 1 (IBA-1) expression in microglia cells and degenerative endothelial cells, and increased glial fibrillary acidic protein (GFAP) expression was observed in astrocytes and degenerate neurons.Conclusions: It has been shown that cadmium toxicity may cause microgliosis and astrogliogenesis by inducing cytokine production due to cell degeneration, vascularity, and inflammation in the brain cortex and by affecting microglia, astrocytes cells.