: Piperazine scaffolds are a group of heterocyclic atoms having pharmacological values and shows significant results in pharmaceutical chemistry. Piperazine has the flexible core structure for the design and synthesis of new bioactive compounds. These flexible heterogenous compounds exhibit various biological roles, primarily anticancer, antioxidant, cognition enhancers, antimicrobial, antibacterial, antiviral, antifungal, anti-inflammatory, anti-HIV-1 inhibitors, antidiabetic, antimalarial, antidepressant, antianxiety and anticonvulsant activities etc. In the past few years, researchers focused on the therapeutic profile of piperazine synthons for different biological targets. The present review highlights the development in designing and pharmacological activities of nitrogen-containing piperazine moiety as a therapeutic agent. The extensive popularity of piperazine as a drug of abuse and their vast heterogeneity research efforts over the last years motivated the new investigators to further explore this area.
Alzheimer’s disease (AD) is the most prevalent and severe neurodegenerative disease affecting more than 0.024 billion people globally, more common in women as compared to men. Senile plaques and amyloid deposition are among the main causes of AD. Amyloid deposition is considered as a central event which induces the link between the production of β amyloid and vascular changes. Presence of numerous biomarkers such as cerebral amyloid angiopathy, microvascular changes, senile plaques, changes in white matter, granulovascular degeneration specifies the manifestation of AD while an aggregation of tau protein is considered as a primary marker of AD. Likewise, microvascular changes, activation of microglia (immune defense system of CNS), amyloid-beta aggregation, senile plaque and many more biomarkers are nearly found in all Alzheimer’s patients. It was seen that 70% of Alzheimer’s cases occur due to genetic factors. It has been reported in various studies that apolipoprotein E(APOE) mainly APOE4 is one of the major risk factors for the later onset of AD. Several pathological changes also occur in the white matter which include dilation of the perivascular space, loss of axons, reactive astrocytosis, oligodendrocytes and failure to drain interstitial fluid. In this review, we aim to highlight the various biological signatures associated with the AD which may further help in discovering multitargeting drug therapy.
Globally, neurodegenerative diseases cause a significant degree of disability and distress. Brain-derived neurotrophic factor (BDNF), primarily found in the brain, has a substantial role in the development and maintenance of various nerve roles and is associated with the family of neurotrophins, including neuronal growth factor (NGF), neurotrophin-3 (NT-3) and neurotrophin-4/5 (NT-4/5). BDNF has affinity with tropomyosin receptor kinase B (TrKB), which is found in the brain in large amounts and is expressed in several cells. Several studies have shown that decrease in BDNF causes an imbalance in neuronal functioning and survival. Moreover, BDNF has several important roles, such as improving synaptic plasticity and contributing to long-lasting memory formation. BDNF has been linked to the pathology of the most common neurodegenerative disorders, such as Alzheimer’s and Parkinson’s disease. This review aims to describe recent efforts to understand the connection between the level of BDNF and neurodegenerative diseases. Several studies have shown that a high level of BDNF is associated with a lower risk for developing a neurodegenerative disease.
: Sleep is considered as one of the most important aspect for maintaining a healthy life. For a person to function normally at least 6-8 hours of sleep daily is necessary. Sleep not only affects our mood, but also regulates the efficiency of work done. Many complications arise due to inadequacy of sleep. The unhealthy food and lifestyle choices have made us more prone to sleep disorders. The medications which are used for the treatment of sleep disorders are mainly habit forming and have tendencies of withdrawal symptoms. This inadequacy in medication has lead to search for newer, better options. The field of nutraceuticals fits apt for treating such disorders. The quality of being non-toxic, non-habit forming, and being practically more efficient has had made it an excellent option. Nutraceuticals make use of food or part of food for the treatment or to prevent any disease. Remarkable positive effects of nutraceuticals like Caffeine, Chamomile, Kava kava, Cherries and Cherry juice, L tryptophan, Valerian, Vitamin D, Marijuana, melatonin, Lemon balmhad been mentioned in the treatment of sleep disorders. The present review gives a general overview of nutraceuticals and discusses their use in sleep disorders.
Background: Alzheimer’s disease is an irreversible, progressive brain disorder manifested with symptoms like loss of memory (known as dementia), personality changes, loss of cognition, impaired movement, confusion, deteriorated planning and thought process. Neurodegeneration in Alzheimer’s disease is the result of deposition of protein beta-amyloid that forms plaques and another protein called tau, forming tangles that prevent proper functioning of nerve cells in the brain. Methods: The goal of the review was to comprehensively study the utilization of nanotechnology and the role that carbon nanotubes can play as a drug delivery system for amelioration of Alzheimer’s disease. Results: Nanotechnology is one of the most researched domains of modern science. It contributes significantly to therapeutics by facilitating drug therapy to reach the target sites, which are otherwise difficult to reach with conventional drug delivery systems. Carbon nanotubes are the allotropes of carbon in which several carbon atoms bind with each other to form a cylindrical or a tube-like structure. The carbon nanotubes possess several unique qualities, which confers them with a high potential of being utilized as an efficient drug delivery system. They offer high drug loading, can readily cross the toughest biological barriers like BBB. Carbon nanotubes also facilitate the passage of drugs to the brain via the olfactory route, which further helps in restoring normal autophagy, thus preventing the elimination of autophagic chemicals. They can carry a vast range of cargos, including drugs, antigens, genetic materials, and biological macromolecules. Conclusion: Carbon nanotubes are highly promising drug delivery system for anti-Alzheimer’s drugs. They have potential of overcoming the various biological barriers like BBB. However, more extensive research is required so as to set up a firm base for development of advanced commercial products based on carbon nanotubes for treatment of Alzheimer’s disease.
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