Tailoring epilepsy treatment: personalized micro-physiological systems illuminate individual drug responses.

Introduction: Approximately 50 million people worldwide have epilepsy, with many not achieving seizure freedom. Organ-on-chip technology, which mimics organ-level physiology, could revolutionize drug development for epilepsy by replacing animal models in preclinical studies. The authors' goal is to determine if customized micro-physiological systems can lead to tailored drug treatments for epileptic patients. Materials and methods: A comprehensive literature search was conducted utilizing various databases, including PubMed, Ebscohost, Medline, and the National Library of Medicine, using a predetermined search strategy. The authors focused on articles that addressed the role of personalized micro-physiological systems in individual drug responses and articles that discussed different types of epilepsy, diagnosis, and current treatment options. Additionally, articles that explored the components and design considerations of micro-physiological systems were reviewed to identify challenges and opportunities in drug development for challenging epilepsy cases. Results: The micro-physiological system offers a more accurate and cost-effective alternative to traditional models for assessing drug effects, toxicities, and disease mechanisms. Nevertheless, designing patient-specific models presents critical considerations, including the integration of analytical biosensors and patient-derived cells, while addressing regulatory, material, and biological complexities. Material selection, standardization, integration of vascular systems, cost efficiency, real-time monitoring, and ethical considerations are also crucial to the successful use of this technology in drug development. Conclusion: The future of organ-on-chip technology holds great promise, with the potential to integrate artificial intelligence and machine learning for personalized treatment of epileptic patients.

Microengineered neuronal networks: enhancing brain-machine interfaces.

The brain-machine interface (BMI), a crucial conduit between the human brain and computers, holds transformative potential for various applications in neuroscience. This manuscript explores the role of micro-engineered neuronal networks (MNNs) in advancing BMI technologies and their therapeutic applications. As the interdisciplinary collaboration intensifies, the need for innovative and user-friendly BMI technologies becomes paramount. A comprehensive literature review sourced from reputable databases (PubMed Central, Medline, EBSCOhost, and Google Scholar) aided in the foundation of the manuscript, emphasizing the pivotal role of MNNs. This study aims to synthesize and analyze the diverse facets of MNNs in the context of BMI technologies, contributing insights into neural processes, technological advancements, therapeutic potentials, and ethical considerations surrounding BMIs. MNNs, exemplified by dual-mode neural microelectrodes, offer a controlled platform for understanding complex neural processes. Through case studies, we showcase the pivotal role of MNNs in BMI innovation, addressing challenges, and paving the way for therapeutic applications. The integration of MNNs with BMI technologies marks a revolutionary stride in neuroscience, refining brain-computer interactions and offering therapeutic avenues for neurological disorders. Challenges, ethical considerations, and future trends in BMI research necessitate a balanced approach, leveraging interdisciplinary collaboration to ensure responsible and ethical advancements. Embracing the potential of MNNs is paramount for the betterment of individuals with neurological conditions and the broader community.

Revolutionizing neurotherapeutics: blood-brain barrier-on-a-chip technologies for precise drug delivery.

Introduction: The blood-brain barrier (BBB) is a critical neurovascular unit regulating substances' passage from the bloodstream to the brain. Its selective permeability poses significant challenges in drug delivery for neurological disorders. Conventional methods often fail due to the BBB's complex structure. Aim: The study aims to shed light on their pivotal role in revolutionizing neurotherapeutics and explores the transformative potential of BBB-on-a-Chip technologies in drug delivery research to comprehensively review BBB-on-a-chip technologies, focusing on their design, and substantiate advantages over traditional models. Methods: A detailed analysis of existing literature and experimental data pertaining to BBB-on-a-Chip technologies was conducted. Various models, their physiological relevance, and innovative design considerations were examined through databases like Scopus, EbscoHost, PubMed Central, and Medline. Case studies demonstrating enhanced drug transport through BBB-on-a-Chip models were also reviewed, highlighting their potential impact on neurological disorders. Results: BBB-on-a-Chip models offer a revolutionary approach, accurately replicating BBB properties. These microphysiological systems enable high-throughput screening, real-time monitoring of drug transport, and precise localization of drugs. Case studies demonstrate their efficacy in enhancing drug penetration, offering potential therapies for diseases like Parkinson's and Alzheimer's. Conclusion: BBB-on-a-Chip models represent a transformative milestone in drug delivery research. Their ability to replicate BBB complexities, offer real-time monitoring, and enhance drug transport holds immense promise for neurological disorders. Continuous research and development are imperative to unlock BBB-on-a-Chip models' full potential, ushering in a new era of targeted, efficient, and safer drug therapies for challenging neurological conditions.

Zika virus disease: an alarming situation resurfacing on the radar - a short communication.

Background/introduction: On the 13th of December 2022, a 5-year-old girl from Karnataka, India, tested positive for Zika virus. The first Zika virus was isolated from the serum of a rhesus monkey in the Zika Forest of Uganda in 1947. Zika virus was largely dormant for about 70 years before suddenly resurfacing across all of America, from Brazil to the Pacific Islands and is connected to a grouping of microcephaly phenotypes based on a complete virus genome analysis. All of the aforementioned research provides an overview of the migration of this virus from the Americas to continental Africa via mosquitoes. The current study, therefore, aims to evaluate the virologic characteristics, prophylaxis, transmitting mechanisms, diagnosis, clinical manifestations, and treatment of ZIKV infection in light of the virus's widespread dissemination and deadly nature. Aim: The investigation's findings aim to demonstrate that in order to prevent further outbreaks, there is a national requirement for active epidemiological and entomological observation of Zika. Materials and methods: Data were extracted from academic journals of medicine published in MEDLINE, PubMed, ScienceDirect, Ovid, and Embase inventory databases with a predetermined search strategy. Articles considering the Zika virus and its clinical manifestations, especially neurological, were included. Results: The Zika virus has been declared a public health emergency of global significance by the World Health Organization (WHO). It is of alarming concern that it is now one of the most prevalent infectious diseases associated with birth abnormalities discovered in the past five decades. The onset and accelerated spread of disease to other parts of the world is attributed to the migration of infected hosts and climate change. Rapid laboratory diagnosis, evaluation of serological techniques, and virus isolation are urgently needed, along with newer modalities such as mathematical modeling as prediction devices to curb this issue. Due to its grave neurological manifestations, it is mandated to engineer peptide therapies and a virus-specific vaccination to treat this neurotropic virus. Conclusion: There is currently no vaccination against Zika virus infection. If societies are not adequately prepared, the epidemiological wave will have an impact on the workforce and could pose a serious threat. To alleviate the significant cost on health systems and manage its promotion globally, improved investigation and response activities are needed.

Ebola Virus Disease in Uganda: A global emergency call.

The Ministry of Health of the Republic of Uganda declared the Ebola virus disease (EVD) outbreak on 20th September 2022 after a patient infected with the rare Sudan strain of Ebola virus (EBV) died in the Mubende district. Since the year 2000, several outbreaks of the EVD from the Sudan strain have been reported in Uganda and it has been more than a decade since the last case of EVD (Sudan strain) was reported in the country. EVD is a severe, often fatal illness that affects humans and other primates and presents with varied neurological and gastrointestinal symptoms. This article has explored various efforts by the World Health Organization and the Ministry of Health of the Republic of Uganda to coordinate outbreak preparedness and response. Certain recommendations have been made to individuals and the government for early management and prevention of the EVD. Further emphasis has been also laid on effective isolation, triage, and screening of symptomatic patients.