Experimental Disease Models Research Articles

Effect of bioactive extracts from Eucalyptus globulus leaves in experimental models of Alzheimer's disease.

Current therapies for Alzheimer's disease (AD) do not delay its progression, therefore, novel disease-modifying strategies are urgently needed. Recently, an increasing number of compounds from natural origin with protective properties against AD have been identified. Mixtures or extracts obtained from natural products containing several bioactive compounds have multifunctional properties and have drawn the attention because multiple AD pathways can be simultaneously modulated. This study evaluated the in vitro and in vivo effect of the essential oil (EO) obtained from the hydrodistillation of Eucalyptus globulus leaves, and an extract obtained from the hydrodistillation residual water (HRW). It was observed that EO and HRW have anti-inflammatory effect in brain immune cells modeling AD, namely lipopolysaccharide (LPS)- and amyloid-beta (Aβ)-stimulated microglia. In cell models that mimic AD-related neuronal dysfunction, HRW attenuated Aβ secretion and Aβ-induced mitochondrial dysfunction. Since the HRW's major components did not cross the blood-brain barrier, both EO and HRW were administered to the APP/PS1 transgenic AD mouse model by an intranasal route, which reduced cortical and hippocampal Aβ levels, and to rescue memory deficits and anxiety-like behaviors. Finally, HRW and EO were found to regulate cholesterol levels in aged mice after intranasal administration, suggesting that these extracts can reduce hypercholesterolemia and avoid risk for AD development. Overall, findings support a protective role of E. globulus extracts against AD‑like pathology and cognitive impairment highlighting the underlying mechanisms. These extracts obtained from underused forest biomass could be useful to develop nutraceutical supplements helpful to avoid AD risk and to prevent its progression.

Experimental models of antibiotic exposure and atopic disease

In addition to numerous clinical studies, research using experimental models have contributed extensive evidence to the link between antibiotic exposure and atopic disease. A number of mouse models of allergy have been developed and used to uncover the specific effects of various microbiota members and perturbations on allergy development. Studies in mice that lack microbes entirely have also demonstrated the various components of the immune system that require microbial exposure. The importance of the early-life period and the mechanisms by which atopy “protective” species identified in human cohorts promote immune development have been elucidated in mice. Finally, non-animal models involving human-derived cells shed light on specific effects of bacteria on human epithelial and immune responses. When considered alongside clinical cohort studies, experimental model systems have provided crucial evidence for the link between the neonatal gut microbiota and allergic disease, immensely supporting the stewardship of antibiotic administration in infants. The following review aims to describe the range of experimental models used for studying factors that affect the relationship between the gut microbiota and allergic disease and summarize key findings that have come from research in animal and in vitro models.

Response of lymphoid organs to immunization with Fc fragments of IgG carrying epitopes specific to regulatory rheumatoid factor

Previously, we identified a new factor of autoimmunity downregulation, called regulatory rheumatoid factor (regRF). The production of regRF was associated with the resistance of animals to the experimental autoimmune diseases or with the remission in animals that are sensitive to the autoimmune diseases. The action of regulatory rheumatoid factor is based on the killing of activated CD4 T lymphocytes expressing PD-1, which makes it possible to restrain the expansion of lymphocytes, including autoreactive ones. RegRF-specific epitopes (regRF epitopes) can be induced on IgG Fc fragments. Immunization of rats with homologous IgG Fc fragments bearing regRF epitopes suppresses symptoms, lymphocytic infiltration and target tissue damage in several experimental models of autoimmune diseases. An in vitro study of the mechanisms of regRF-producing lymphocytes activation by IgG Fc fragments carrying regRF epitopes showed that IgG Fc fragments carrying regRF epitopes are T cell-independent antigens type 2. The reactions of the immune system, in particular in lymphoid organs, to T cell-independent antigens type 2, especially having a protein nature, are poorly studied. The purpose of this work is to study the reactions of the spleen and lymph nodes of rats to immunization with IgG Fc fragments carrying regRF epitopes. Wistar rats were immunized subcutaneously with 500 μg of homologous IgG Fc fragments carrying regRF epitopes. Control animals received an injection of phosphate-buffered saline. Immunization with IgG Fc fragments carrying regRF epitopes caused a transient increase of regulatory rheumatoid factor blood level with a maximum on day 7 after immunization. It was found that immunization with IgG Fc fragments carrying regRF epitopes does not cause a reaction in the regional and distal lymph nodes of rats, but induces the development of secondary follicles in spleen that exist for at least 28 days. On day 49, the number of follicles with germinal centers in the spleen of rats immunized with IgG Fc fragments carrying regRF epitopes was lower than in control rats. Consequently, the reaction of splenic follicles in rats immunized with IgG Fc fragments carrying regRF epitopes is transient. No changes were detected in the periarteriolar lymphoid sheaths (splenic T cell zone) in rats immunized with IgG Fc fragments carrying regRF epitopes. Thus, IgG Fc fragments carrying regRF epitopes, being a T cell-independent antigens type 2, do not cause a reaction in the lymph nodes, but induce the development of germinal centers in the spleen that exist for several weeks.

Chronic stress-mediated dysregulations in inflammatory, immune and oxidative circuitry impairs the therapeutic response of methotrexate in experimental autoimmune disease models.

Chronic stress is significantly implicated in the worsening of autoimmune disorders, contributing to elevated inflammation and diminished therapeutic efficacy. Here, in this study, we investigated the detrimental impact of an 8-week chronic unpredictable stress (CUS) protocol on the progression of arthritis and psoriasis using collagen-induced arthritis (CIA) and imiquimod (IMQ)-induced psoriasis rat models, respectively. Our objective was to elucidate how prolonged stress exacerbates disease severity and impairs the effectiveness of treatment drug. Following the induction of CIA and IMQ, rats were subjected to an 8-week CUS paradigm designed to simulate chronic stress conditions. Moreover, after 5 weeks of CUS, methotrexate (MTX; 2 mg/kg, administered once weekly for 3 weeks, intraperitoneally) was introduced as a therapeutic intervention. The severity of CUS-induced effects and the therapeutic impairment of MTX in arthritis and psoriasis rats were assessed through pathological examination of joint and epidermal tissues, respectively. Additionally, we measured various pro-inflammatory cytokine levels, including NF-κB (nuclear factor kappa B), IFN-γ (interferon-gamma), TNF-α (tumour necrosis factor alpha), IL (interleukin)-1β, IL-6, IL-17 and IL-23 using enzyme-linked immunosorbent assay (ELISA), analysed immune cells through complete haematological profiling and evaluated oxidative stress markers. Our findings revealed that CUS significantly aggravated the pathological features of both arthritis and psoriasis. Prolonged stress exposure led to heightened inflammatory responses, increased oxidative stress and more severe tissue damage. Moreover, the therapeutic efficacy of MTX was notably reduced in stressed rats compared to non-stressed, underscoring the detrimental effects of chronic stress on treatment outcomes. Taken together, our results emphasize the importance of considering chronic stress as a critical factor in the management of autoimmune diseases.

Inflammation and resolution in obesity.

Inflammation is an essential physiological defence mechanism, but prolonged or excessive inflammation can cause disease. Indeed, unresolved systemic and adipose tissue inflammation drives obesity-related cardiovascular diseaseand type 2 diabetes mellitus. Drugs targeting pro-inflammatory cytokine pathways or inflammasome activation have been approved for clinical use for the past two decades. However, potentially serious adverse effects, such as drug-induced weight gain and increased susceptibility to infections, prevented their wider clinical implementation. Furthermore, these drugs do not modulate the resolution phase of inflammation. This phase is an active process orchestrated by specialized pro-resolving mediators, such as lipoxins, and other endogenous resolution mechanisms. Pro-resolving mediators mitigate inflammation and development of obesity-related disease, for instance, alleviating insulin resistance and atherosclerosis in experimental disease models, so mechanisms to modulate their activity are, therefore, of great therapeutic interest. Here, we review current clinical attempts to either target pro-inflammatory mediators (IL-1β,NOD-, LRR- and pyrin domain-containing protein 3 (NLRP3)inflammasome,tumour necrosis factor (TNF)and IL-6) or utilize endogenous resolution pathways to reduce obesity-related inflammation and improve cardiometabolic outcomes. A remaining challenge in the field is to establish more precise biomarkers that can differentiate between acute and chronic inflammation and to assess the functionality of individual leukocyte populations. Such advancements would improve the monitoring of drug effects and support personalized treatment strategies that battle obesity-related inflammation and cardiometabolic disease.

Testing Visual Function by Assessment of the Optomotor Reflex in Glaucoma.

Optomotor response/reflex (OMR) is a fast and efficient first-in-line visual screening method, especially for rodents. It has the potential to evaluate both the scotopic and photopic visions of nonrestrained animals through tracking head movement, providing a quantitative estimate of visual functions. In restrained animals, optokinetic response (OKR), compensatory eye movements for visual shifts in the surroundings, is utilized. Both OMR and OKR capitalize on an individual's innate reflex to stabilize images for the purpose of capturing clear vision. The two reflexes have similar reliability when evaluating stimulus luminance, contrast, spatial frequency, and velocity. They have emerged as powerful tools to evaluate the efficacy of pharmacological treatments and phenotypes of subjects undergoing study. With OMR and OKR accurately assessing visual acuity (VA) as well as contrast sensitivity (CS), the gold standards for measuring clinical vision, they provide reliable and easily accessible results that further eye and brain research. These methods of sight evaluation have been used in multiple animal models, particularly mice and zebrafish. Through OMR assays, these animal models have been utilized to investigate retinal degenerative diseases, helping researchers differentiate between worsening stages. Alongside tests such as optical coherence tomography (OCT), OMR provides confirmation of visual status, where increased OMR function often correlates with improved visual status. OMR has continued to be used outside of glaucoma in various retinal diseases, such as retinitis pigmentosa (RP), diabetic retinopathy, and age-related macular degeneration.In this chapter, we will introduce the concept and application of visual stimulus-induced head or eye reflex movement in different animal species and experimental models of eye diseases, such as glaucoma and other neurodegenerative disorders, and in patients with glaucoma.

Evaluating the effects of basil (Ocimum basilicum) in the experimental model of Alzheimer's disease in rats

Evaluating the effects of basil (Ocimum basilicum) in the experimental model of Alzheimer's disease in rats

Unveiling the fibrotic puzzle of endometriosis: An overlooked concern calling for prompt action

Endometriosis is a benign, estrogen-dependent, persistent chronic inflammatory heterogeneous condition that features adhesions caused by estrogen-dependent periodic bleeding. It is characterised by a widely spread fibrotic interstitium that comprising of fibroblasts, myofibroblasts, collagen fibres, extracellular proteins, inflammatory cells, and active angiogenesis found outside the uterus. Thus, fibrosis is recognized as a critical component because of which current treatments, such as hormonal therapy and surgical excision of lesions are largely ineffective with severe side effects, high recurrence rates, and significant morbidity. The symptoms include dysmenorrhea (cyclic or non-cyclic), dyspareunia, abdominal discomfort, and infertility. The significant lack of knowledge regarding the underlying root cause, etiology, and complex pathogenesis of this debilitating condition, makes it challenging to diagnose early and to implement therapeutic approaches with minimal side effects presenting substantial hurdles in endometriosis management. Research on understanding the pathogenesis of endometriosis is still ongoing to find biomarkers and develop non-hormonal therapeutic approaches. Current clinical research indicates a close relationship between endometriosis and fibrosis, which is thought to be tightly linked to pain, a major factor for the decline in the patient’s quality of life but little is known about the underlying pathophysiological cellular and molecular signaling pathways that lead to endometriosis-related fibrosis. The available experimental disease models have tremendous challenges in reproducing the human characteristics of the disease to assess treatment effectiveness. Future translational research on the topic has been hindered by the lack of an adequate fibrotic model of endometriosis emphasizing the necessity of etiological exploration. This review article’s goal is to examine recent developments in the field and pinpoint knowledge gaps that exist with a focus on the development of novel fibrotic mouse models for the early diagnosis and treatment of endometriosis and how this knowledge aids in the development of novel anti-fibrotic treatments which opens fresh avenues for a thorough investigation and extended research in the field of endometriosis.

Tibolone treatment after traumatic brain injury exerts a sex-specific and Y chromosome-dependent regulation of methylation and demethylation enzymes and estrogen receptors in the cerebral cortex

Tibolone, a synthetic steroid used for the treatment of climacteric symptoms, displays sex-specific protective actions in experimental models of brain diseases. Previous in vitro findings suggest that tibolone reduces oxidative stress and neuroinflammation through the regulation of DNA methylation and the activation of estrogen receptors (ERs) α and β. In this study, we assessed whether tibolone regulates the expression of genes coding for DNA methylation and demethylation enzymes and ERs in the injured cerebral cortex of animals suffering a traumatic brain injury. The four-core genotype mouse model was used to determine whether the effect of tibolone on gene regulation was influenced by gonads or by cell-autonomous actions of sex chromosomes. Tibolone treatment resulted in sex-specific modification in the expression of genes coding for DNA methyl transferases (Dnmt) 3a, and 3b, for growth arrest and DNA-damage-inducible proteins (Gadd) 45β and 45γ, and for ERα and ERβ. In contrast, tibolone did not affect the expression of genes coding for Dnmt1, Gadd45α, and ten-eleven translocation methylcytosine dioxygenases 1–3. The sex-specific effect of tibolone on Dnmt3a expression depended on gonadal sex. In contrast, the presence or absence of the Y chromosome determined the effect of tibolone on Dnmt3b, Gadd45β, Gadd45γ, ERα and ERβ expression. These findings suggest that tibolone exerts a sex-specific regulation of DNA methylation and ER expression in the injured cerebral cortex that is determined by a combination of gonadal effects and cell-autonomous actions of sex chromosome genes.

Alleviation of LPS-induced Endothelial Injury due to GHRH Antagonist Treatment.

GHRH is produced in the hypothalamus and affects various tissues beyond the pituitary, including the lungs. GHRH antagonists exert anti-inflammatory properties in several experimental models of disease, but their role inprotecting the endothelial barrier during inflammation is less understood. This study investigates the effects ofGHRHAnt on LPS-induced endothelial dysfunction. BPAEC and HMVEC-L cells were exposed to LPS to induce endothelial injury. GHRHAnt was administered eitherpre- or post-LPS treatment. Western blot analysis was used to evaluate protein expression levels. Paracellularpermeability was assessed utilizing FITC-dextran assay to evaluate endothelial barrier function. GHRHAnt post-treatment significantly reduced LPS-induced MLC2 phosphorylation and cofilin activation inBPAECs. Furthermore, pretreatment with GHRHAnt enhanced barrier function and ameliorated LPS-inducedhyperpermeability in both human and bovine endothelial cells. GHRHAnt treatment mitigates LPS-induced endothelial barrier dysfunction. These findings suggest that GHRHAntcould serve as potential therapeutic agents towards endothelial dysfunction-related illness (e.g. sepsis).

Behavioral Assays for Comprehensive Evaluation of Cognitive and Neuropsychiatric Comorbidities of Traumatic Brain Injury and Chronic Neurological Disorders.

Neurological deficits, psychiatric disorders, and cognitive impairments often accompany stroke, brain injury, epilepsy, and many neurological disorders, which present intricate comorbidities that challenge recognition and management. There are many tools and paradigms for evaluating learning, memory, anxiety, and depression-like behaviors in lab animal models of brain disorders. However, there is a significant gap between clinical observations and experimental models, which limit understanding of the complex interplay between chronic brain conditions and their impact on cognitive dysfunction and psychiatric impairments. This article describes an overview of experimental rationale, methods, protocols, and strategies for evaluating sensorimotor, affective and cognitive-associated comorbid behaviors in epilepsy, traumatic brain injury (TBI), stroke, spinal cord injury (SCI), and many other neurological disorders. First, we delve into clinical evidence elucidating the profound impact of comorbidities, e.g., psychiatric disorders and cognitive deficits, in individuals with epilepsy. Then, we discuss diverse approaches to assess these comorbidities in experimental models of brain diseases. Finally, we explore the methodologies for assessing motor function, sensorimotor, behavior, and psychiatric health. We cover strategies and protocols enabling these assays, including implementing behavioral paradigms to assess learning and memory, anxiety, and depression-like behaviors in rodents in health and disease conditions. It is essential to consider a comprehensive battery of tests to investigate various behavioral deficits, considering environment, age, and sex differences relevant to the disease, such as TBI, SCI, epilepsy, stroke, and other complex neurological conditions. © 2024 The Author(s). Current Protocols published by Wiley Periodicals LLC.

Exploring the Behavioral Traits of Male Mutant Crup Mice as an Experimental Neurodegenerative Disease Model

The congenic BALB/c-crup (‘crup’ meaning ‘cruza-pernas’ in Portuguese or cross legs in English), a homozygous recessive mutant mouse derived from N-ethyl-N-nitrosourea mutagenesis, exhibits a unique phenotype characterized by hindlimb crossing when the mouse is suspended by its tail, along with age-related neuromotor issues. The study aimed to identify the genetic mutation causing the BALB/c-crup phenotype and evaluate the behavioral responses of the mice. Open field test, elevated plus maze, and elevated beam experiments were conducted to evaluate general activity, motor function, as well as sensorimotor and autonomic nervous systems. Genetic mapping and exome analysis identified a nonsynonymous (missense mutation), a single nucleotide variant, in the Taf15 gene. This mutation results in the p.G55S substitution, where glycine is replaced by serine at position 55 in the gene product. Longitudinal assessment by the open field test revealed altered locomotion, decreased mobility, and reduced rearing and grooming frequency in mutant mice. Sensorimotor function declines were observed through reduced surface righting reflex scores, grip strength, and increased hindquarter angle. In the elevated beam test, mutants exhibited tail hypotonia and aversion to traversing the beam. The elevated plus maze revealed altered behavior in closed arms, suggesting increased anxiety-like behavior or sensorimotor impairment. Our findings provide insights into neurologic and behavioral anomalies associated with a Taf15 gene mutation. The altered locomotion, sensory impairments, and disorientation observed in the crup phenotype indicate a progressive neuromotor condition, potentially serving as a novel mouse model for neurodegenerative diseases.

A 6-Minute Limb Function Assessment for Therapeutic Testing in Experimental Peripheral Artery Disease Models

A 6-Minute Limb Function Assessment for Therapeutic Testing in Experimental Peripheral Artery Disease Models

Synthetic Human Embryos, Embryo Models and Embryo-like Structures in Islam

ABSTRACT A major breakthrough in developmental biology is the ex vivo generation of synthetic human embryos from stem cells. A comprehensive, in-depth bioethical analysis from a Sunni Islamic perspective reveals that the reproductive applications of synthetic human embryos contravene Islamic precepts of preserving lineage integrity (Hifz al-Nasl) due to disruption and confusion of kinship and familial relationships, similar to human cloning with somatic cell nuclear transfer. However, their non-reproductive applications in generating replacement tissues/organs, serving as in vitro experimental models of human development and disease, and testing platforms for evaluating pharmaceuticals and biomedical devices appear to align with Islamic principles.

Upregulation of Metrnl improves diabetic kidney disease by inhibiting the TGF-β1/Smads signaling pathway: A potential therapeutic target.

This study comprises an investigation of the role of meteorin-like (Metrnl) in an experimental model of diabetic kidney disease (DKD). Twenty-four db/db mice were randomly assigned to one of the following groups: DKD, DKD + Metrnl-/-, and DKD + Metrnl+/+. Plasma Metrnl concentrations were measured using ELISA. Kidney tissues were examined via western blotting, qRT-PCR, and immunohistochemistry to determine the expression levels of inflammatory factors. Electron microscopy was employed to observe stained kidney sections. Compared with the NC group, FBG, BW, and UACR were elevated in the DKD and Metrnl-/- groups, with severe renal pathological injury, decreased serum Metrnl concentration, decreased renal Metrnl expression, and increased expression levels of TNF-α, TGF-β1, TGF-R1, pSmad2, pSmad3, and α-SMA. In contrast, the Metrnl+/+ group showed decreased FBG and UACR, BUN, TC and TG, increased HDL-C and serum Metrnl concentration, increased renal Metrnl expression, and decreased expression of TNF-α, TGF-β1, TGF-R1, pSmad2, pSmad3, and α-SMA, compared to the DKD and Metrnl-/- groups. A Pearson bivariate correlation analysis revealed a negative correlation between UACR and Metrnl, and a positive correlation between UACR and TGF-β1. Upregulation of renal Metrnl expression can improve renal injury by downregulating the expression of molecules in the TGF-β1/Smads signaling pathway in the renal tissues of type 2 diabetic mice; and by reducing the production of fibrotic molecules such as α-SMA.

Use of phytocanabinoids in animal models of Parkinson's disease: Systematic review

This systematic review was carried out with the aim of evaluating the use of medicinal Cannabis for the treatment of Parkinson's disease in experimental models. Furthermore, we sought to understand the main intracellular mechanisms capable of promoting the effects of phytocannabinoids on motor disorders, neurodegeneration, neuroinflammation and oxidative stress. The experimental models were developed in mice, rats and marmosets. There was a predominance of using only males in relation to females; in three studies, the authors evaluated treatments in males and females. Drugs were used as inducers of Parkinson's disease: 6-hydroxydopamine (6-OHDA), 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP), lipopolysaccharide (LPS), and rotenone. Substances capable of promoting catalepsy in animals were also used: haloperidol, L-nitro-N-arginine (L-NOARG), WIN55,212–2, and reserpine. The inducing agent was injected stereotaxically or intraperitoneally. The most commonly used treatments were cannabidiol (CBD), Delta-9-tetrahydrocannabinol (Δ-9 THC) and Delta-9-tetrahydrocannabivarin (Δ-9 THCV), administered intraperitoneally, orally, subcutaneously and intramuscularly. The use of phytocannabinoids improved locomotor activity and involuntary movement and reduced catalepsy. There was an improvement in the evaluation of dopaminergic neurons, while in relation to dopamine content, the treatment had no effect. Inflammation, microglial/astrocyte activation and oxidative stress were reduced after treatment with phytocannabinoids, the same was observed in the results of tests for allodynia and hyperalgesia.

High fat diet affects the hippocampal expression of miRNAs targeting brain plasticity-related genes

Metabolic disorders such as insulin resistance and type 2 diabetes are associated with brain dysfunction and cognitive deficits, although the underpinning molecular mechanisms remain elusive. Epigenetic factors, such as non-coding RNAs, have been reported to mediate the molecular effects of nutrient-related signals. Here, we investigated the changes of miRNA expression profile in the hippocampus of a well-established experimental model of metabolic disease induced by high fat diet (HFD). In comparison to the control group fed with standard diet, we observed 69 miRNAs exhibiting increased expression and 63 showing decreased expression in the HFD mice’s hippocampus. Through bioinformatics analysis, we identified numerous potential targets of the dysregulated miRNAs, pinpointing a subset of genes regulating neuroplasticity that were targeted by multiple differentially modulated miRNAs. We also validated the expression of these synaptic and non-synaptic proteins, confirming the downregulation of Synaptotagmin 1 (SYT1), calcium/calmodulin dependent protein kinase I delta (CaMK1D), 2B subunit of N-methyl-D-aspartate glutamate receptor (GRIN2B), the DNA-binding protein Special AT-Rich Sequence-Binding Protein 2 (SATB2), and RNA-binding proteins Cytoplasmic polyadenylation element-binding protein 1 (CPEB1) and Neuro-oncological ventral antigen 1 (NOVA1) in the hippocampus of HFD mice. In summary, our study offers a snapshot of the HFD-related miRNA landscape potentially involved in the alterations of brain functions associated with metabolic disorders. By shedding light on the specific miRNA-mRNA interactions, our research contributes to a deeper understanding of the molecular mechanisms underlying the effects of HFD on the synaptic function.

Inhibition of glycolytic reprogramming suppresses innate immune-mediated inflammation in experimental amyotrophic lateral sclerosis.

Innate immune activation has been implicated in the pathogenesis of amyotrophic lateral sclerosis (ALS). However, metabolic pathways that govern this bioenergetically demanding process in ALS remains elusive. Here we investigated whether and how immunometabolic transformation of innate immune cells contributes to disease progression in an experimental model of this neurodegenerative disease. We utilized multidimensional flow cytometry and integrative metabolomics to characterize the immunometabolic phenotype of circulating and spinal cord innate immune cells in the B6SJL-Tg(SOD1*G93A)1Gur/J model of ALS (SOD1-G93A) at various disease stages (before vs. after the onset of motor dysfunction). Behavioral and survival analyses were also conducted to determine the impact of an energy-regulating compound on innate immune cell metabolism, inflammation, and disease development. Temporally coordinated accumulation of circulating inflammatory Ly6C + monocytes and spinal cord F4/80 + CD45hi infiltrates precedes the onset of motor dysfunction in SOD1-G93A mice. Subsequent metabolomic analysis reveals that this phenomenon is accompanied by glycolytic reprogramming of spinal cord inflammatory CD11b + cells, comprising both resident F4/80 + CD45low microglia and F4/80 + CD45hi infiltrates. Furthermore, pharmacologic inhibition of glycolysis by ZLN005, a small molecule activator of Ppargc1a, restrains inflammatory glycolytic activation of spinal cord CD11b + cells, enhances motor function, and prolongs survival in SOD1-G93A mice. These observations suggest that modulation of inflammatory glycolytic reprogramming of innate immune cells may represent a promising therapeutic approach in ALS.

Sex differences in an experimental long-term mouse model of chronic kidney disease

Sex differences in an experimental long-term mouse model of chronic kidney disease

The effect of growth hormone on motor findings and dendrite morphology in an experimental Parkinson's disease model.

Approaches for the induction of neurogenesis and neuronal recovery through several modalities are gaining popularity in Parkinson's disease (PD). Growth hormone (GH) seems to have a role in the reversal of neural function following brain injury as well as in normal brain development and function; therefore, the use of GH may represent a feasible strategy in the management of PD. This experimental study aimed to evaluate the effect of growth hormone on motor function and dendrite morphology in rats with 6-hydroxydopamine (6-OHDA)-induced PD model. Thirty-six Sprague Dawley rats were included and randomly allocated into one of the six study groups: two controls and four treatment groups that received daily subcutaneous growth hormone injections for 21days, 1, 2, and 3months. PD model was induced through unilateral 6-OHDA injection to the nigrostriatal pathway. The following assessments were made: apomorphine rotation test, stepping test, and tissue examinations for tyrosine hydroxylase and dendrite morphology. The apomorphine rotation test and the stepping test confirmed the presence of PD. These tests as well as dendritic spine density/number and length assessments showed improvement in PD findings over time with GH administration. Findings of this study suggest that GH administration may improve dendrite morphology and motor function in the PD model, which may translate into symptom relief and quality of life improvement in patients with PD. Such potential benefits should be tested in robust clinical studies.