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With the success of mRNA vaccines during the COVID-19 pandemic and CAR T-cell therapies in clinical trials, there is growing opportunity for immunotherapies in the treatment of many types of cancers. Lentiviral vectors have proven effective at delivery of genetic material or gene editing technology for ex vivo processing, but the benefits and promise of Adeno-associated virus (AAV) and mRNA tools for in vivo immunotherapy have garnered recent interest. Here we describe complete synthetic solutions for immuno-oncology research programs using either mRNA-vaccines or virus-mediated cell and gene engineering. These solutions optimize workflows to minimize screening time while maximizing successful research results through: (1) Efficiency in lentiviral packaging with versatility in titer options for high-quality particles. (2) A highthroughput viral packaging process to enable rapid downstream screening. (3) Proprietary plasmid synthesis and preparation techniques to maintain ITR integrity through AAV packaging and improve gene delivery. (4) Rapid synthesis, in vitro transcription, and novel sequencing of mRNA constructs for complete characterization of critical components such as the polyA tail. The reported research demonstrates a streamlined approach that improves data quality through innovative synthesis and sequencing methodologies as compared to current standard practices.
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Delivery of self-amplifying mRNA (SAM) has high potential for infectious disease vaccination due to its self-adjuvanting and dose-sparing properties. Yet a challenge is the susceptibility of SAM to degradation and the need for SAM to reach the cytosol fully intact to enable self-amplification. Lipid nanoparticles are successfully deployed at incredible speed for mRNA vaccination, but aspects such as cold storage, manufacturing, efficiency of delivery, and the therapeutic window can benefit from further improvement. To investigate alternatives to lipid nanoparticles, a class of >200 biodegradable end-capped lipophilic poly(beta-amino ester)s (PBAEs) that enable efficient delivery of SAM in vitro and in vivo as assessed by measuring expression of SAM encoding reporter proteins is developed. The ability of these polymers to deliver SAM intramuscularly in mice is evaluated, and a polymer-based formulation that yields up to 37-fold higher intramuscular (IM) expression of SAM compared to injected naked SAM is identified. Using the same nanoparticle formulation to deliver a SAM encoding rabies virus glycoprotein, the vaccine elicits superior immunogenicity compared to naked SAM delivery, leading to seroconversion in mice at low RNA injection doses. These biodegradable nanomaterials may be useful in the development of next-generation RNA vaccines for infectious diseases.Copyright © 2023 The Authors. Advanced Therapeutics published by Wiley-VCH GmbH.
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Messenger RNAmRNAmedicine was urgently approved in 2020 as a vaccine for COVID-19 . However, current mRNA therapeutics are not fully established, with challenges remaining in translation efficiency and drug delivery system. Therefore, further research is needed to adapt mRNA therapeutics to other diseases. Furthermore, the preparation of mRNA drugs is time-consuming and costly because of the biological methods used. Our laboratory has been working on chemical methods to solve these issues. In this paper, we introduce chemical modifications and novel capping reactions as a method to improve the translation efficiency of mRNA and the introduction of disulfide modification to oligonucleotide therapeutics as an effort on the drug delivery system.Copyright © 2023, Japan Society of Drug Delivery System. All rights reserved.
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CBD, an FDA approved drug for epilepsy, may have therapeutic potential for other diseases and is currently being tested for efficacy in cancer-related clinical trials. As the literature about CBD, especially in vitro reports, is often contradictory, increasing our understanding of its specific action on a molecular level will allow to determine whether CBD can become a useful therapy or exacerbates specific cancers in a context-dependent manner. Due to its relative lipophilicity, CBD is challenging to dispense at therapeutic concentrations;therefore, one goal is to identify cannabinoid congeners with greater efficacy and reduced drug delivery challenges. We recently showed that CBD activates interferons as a mechanism of inhibiting SARS-CoV-2 replication in lung carcinoma cells. As factors produced by the innate immune system, interferons have been implicated in both pro-survival and growth arrest and apoptosis signaling in cancer. Here we show that CBD induces interferon production and interferon stimulated genes (ISGs) through a mechanism involving NRF2 and MAVS in lung carcinoma cells. We also show that CBDV, which differs from CBD by 2 fewer aliphatic tail carbons, has limited potency, suggesting that CBD specifically interacts with one or more cellular proteins rather than having a non-specific effect. We also identified other CBD-related cannabinoids that are more effective at inducing ISGs. Taken together, these results characterize a novel mechanism by which CBD activates the innate immune system in lung cancer cells and identify related cannabinoids that have possible therapeutic potential in cancer treatment.
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Recent advancements in nanotechnology have resulted in improved medicine delivery to the target site. Nanosponges are three-dimensional drug delivery systems that are nanoscale in size and created by cross-linking polymers. The introduction of Nanosponges has been a significant step toward overcoming issues such as drug toxicity, low bioavailability, and predictable medication release. Using a new way of nanotechnology, nanosponges, which are porous with small sponges (below one microm) flowing throughout the body, have demonstrated excellent results in delivering drugs. As a result, they reach the target place, attach to the skin's surface, and slowly release the medicine. Nanosponges can be used to encapsulate a wide range of medicines, including both hydrophilic and lipophilic pharmaceuticals. The medication delivery method using nanosponges is one of the most promising fields in pharmacy. It can be used as a biocatalyst carrier for vaccines, antibodies, enzymes, and proteins to be released. The existing study enlightens on the preparation method, evaluation, and prospective application in a medication delivery system and also focuses on patents filed in the field of nanosponges.Copyright © 2023 The Authors.
ABSTRACT
Introduction: There is a distinct unmet need in structured, curriculum based, unbiased education in neuromodulation. Current teaching is through sporadic industry workshops, cadaver courses and peer proctorship. The COVID pandemic has created a unique opportunity where online platforms have enabled education to be delivered remotely in both synchronous and asynchronously. The William Harvey Research Institute, Queen Mary University, London, UK have initiated University based accreditation- Post Graduate Certificate in neuromodulation (PGCert) that provides candidate a qualification in one academic year through part-time study. Method(s): The program underwent rigorous staged university approval process (figure 1). To ensure market feasibility, two short proof of concept CPD programs "Executive Education in Neuromodulation (EEPIN)" were delivered in 2021. These courses attracted 87 candidates across Australia, Singapore, India, Germany, Poland, Czech Republic, Ireland, and UK. The faculty includes key opinion leaders that will deliver the program ensuring the candidates gain academic background and specialist skills to understand safe practice of neuromodulation. The PGCert advisory board has been established to ensure strict governance in terms of content and unbiased delivery confirming ACCME guidance. In order to obtain PGCert, candidates are required to complete 4 x 15 credit modules (60 credits). The four modules include Anatomy & Neurophysiology;Patient care and Procedurals skills;Devices and available technology;Intrathecal drug delivery for cancer and non-cancer pain. The modular nature of the program is designed to provide cumulative knowledge, from basic science to clinical application in line with the best available evidence. The modules comprise nine lectures, spreading over three consecutive days, followed by a written assignment with 40 direct contact hours in each module. The webpage can be accessed at Results: The anonymous data from EEPIN reported on Likert scale 1-5: Objectives defined 30.6% - 4 and 69.4% -5;Relevance of topics 10.2%- 4 and 89.8% -5;Content of presentations 22.4%- 4 and 77.6% -5;Organization 24.5% -4 and 69.4% -5;Candidate faculty interaction 14.3% -4 and 81.6% -5. 97% of the EEPIN candidates recommended the program to others whilst 81.8% expressed their strong interest to enroll for university-based post graduate qualification if offered. Conclusion(s): This PGcert Neuromodulation is a unique, university accredited program that provides qualification in neuromodulation with access to a flexible online e-learning platform to discuss and exchange ideas, share knowledge in candidate's own time. This will support the ongoing need for formal curriculum-based education in neuromodulation. Disclosure: Kavita Poply, PHD: None, Phillippe Rigoard: None, Jan Kallewaard, MD/PhD: None, FRANK J.P.M. HUYGEN, MD PhD: ABBOTT: Speakers Bureau:, Saluda: Consulting Fee:, Boston Scientific: Consulting Fee:, Grunenthal: Speakers Bureau:, Pfizer: Speakers Bureau:, Ashish Gulve, FRCA, FFPMRCA, FFPMCAI, DPMed, FCARCSI, MD, MBBS: None, Ganesan Baranidharan, FRCA: None, Sam ELDABE, MD, FRCA, FFPMRCA: Medtronic: Consulting Fee:, Medtronic: Contracted Research:, Mainstay Medical: Consulting Fee:, Saluda Medical: Consulting Fee:, Boston Scientific: Contracted Research:, Saluda Medical: Contracted Research:, James Fitzgerald, MA,PhD: St Jude Medical: Consultant: Self, Medtronic: Consulting Fee:, UCB: Contracted Research:, Merck: Contracted Research:, Serge Nikolic, MD: None, Stana Bojanic, BSc MBBS FRCS (SN): Abbott: Contracted Research:, Habib Ellamushi: None, Paresh Doshi, MS MCh: None, Preeti Doshi, MBBS, MD, FRCA: None, Babita Ghai, MBBS, MD, DNB: None, Marc Russo, MD: Presidio Medical: Ownership Interest:, Saluda Medical: Ownership Interest:, Boston Scientific: Contracted Research: Self, Mainstay Medical: Contracted Research: Self, Medtronic: Contracted Research: Self, Nevro: Contracted Research: Self, Saluda Medical: Contracted Research: Self, Presidio Medical: Contracted Research: Self, Freedom Ne ro: Ownership Interest - Own Stocks: Self, Lungpacer: Ownership Interest - Own Stocks: Self, SPR Therapeutics: Ownership Interest - Own Stocks: Self, Lawrence Poree, MD,MPH,PHD: Medtronic: Consulting Fee: Self, Saluda Medical: Contracted Research: Family, Nalu Medical: Contracted Research: Family, Gimer Medical: Consulting Fee: Self, Nalu Medical: Consulting Fee: Self, Saluda Medical: Consulting Fee: Self, Nalu: Ownership Interest:, Saluda Inc: Ownership Interest:, Alia Ahmad: None, Alaa Abd Sayed, MD: Medtronic, Abbott, SPR and StimWave: Consulting Fee:, Salim Hayek, MD,PhD: None, CHRISTOPHER GILLIGAN, MD MBA: Persica: Consulting Fee: Self, Saluda: Consulting Fee: Self, Mainstay Medical: Contracted Research: Self, Sollis Therapeutics: Contracted Research: Self, Iliad Lifesciences, LLC: Owner: individuals with legal ownership in a company:, Vivek Mehta: NoneCopyright © 2023
ABSTRACT
This chapter reviews the trends in social sector outcomes in Zimbabwe and assesses the financing challenges in the post-Mugabe era. While Zimbabwe made significant progress in developing its social sectors in the post-independence era, the economic crisis experienced from 1998 to 2008 reversed some of the gains that had been achieved. When the country adopted a multiple currency system in 2009, social sector outcomes improved, driven by a favourable macroeconomic environment. From 2016, however, the country's economic fortunes reversed as the economy began to experience renewed challenges, including falling revenues and declining fiscal space, and shortage of foreign currency to import critical drugs, among other factors. In addition, continued depreciation of the domestic currency since its introduction in 2019 presented additional challenges to the Second Republic, as people's incomes were eroded while fiscal space continued to be squeezed. The situation was further exacerbated by the advent of the Covid-19 pandemic which affected both the education and health sectors in negative ways. These developments underlined the need for additional financing requirements to close the widening financing gap in social sectors in Zimbabwe. As this chapter shows, some of the possible financing options include broadening the tax base to unlock additional resources particularly from the informal economy, exploring contributory schemes, tapping into international financial assistance, strengthening public–private partnerships and tapping into diaspora remittances. There is also a need for strengthening public institutions to ensure efficiency and effectiveness in utilisation of public funds earmarked for social sectors. © 2023, The Author(s), under exclusive license to Springer Nature Switzerland AG.
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Vaccination has been proved to be the most effective strategy to prevent the Corona Virus Disease 2019 (COVID-19). The mRNA vaccine based on nano drug delivery system (NDDS) - lipid nanoparticles (LNP) has been widely used because of its high effectiveness and safety. Although there have been reports of severe allergic reactions caused by mRNA-LNP vaccines, the mechanism and components of anaphylaxis have not been completely clarified yet. This review focuses on two mRNA-LNP vaccines, BNT162b2 and mRNA-1273. After summarizing the structural characteristics, potential allergens, possible allergic reaction mechanism, and pharmacokinetics of mRNA and LNP in vivo, this article then reviews the evaluation methods for patients with allergic history, as well as the regulations of different countries and regions on people who should not be vaccinated, in order to promote more safe injection of vaccines. LNP has become a recognized highly customizable nucleic acid delivery vector, which not only shows its value in mRNA vaccines, but also has great potential in treating rare diseases, cancers and other broad fields in the future. At the moment when mRNA-LNP vaccines open a new era of nano medicine, it is expected to provide some inspiration for safety research in the process of research, development and evaluation of more nano delivery drugs, and promote more nano drugs successfully to market.Copyright © 2023, Chinese Pharmaceutical Association. All rights reserved.
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The heart, liver, lungs, brain and kidney are the five most highly perfused organs. Incidentally, they are the ones prone to many diseases and disorders. There has been a phenomenal rise in lung diseases in the recent past which can be attributed to rising levels of environmental pollution, smoking and other lifestyle problems. The cytokine storm experienced in the COVID-19-affected population was a recent challenge faced by physicians around the globe. Scientists have tried different methods and delivery systems for effective delivery of drugs to the lungs. Pectin-based drug delivery systems have also been tried and tested suc- cessfully. This chapter will focus on the bumps and humps in the use of pectin as an effective polymer in delivering therapeutics to the lungs and management of various respiratory disorders. © The Author (s), under exclusive license to Springer Nature Singapore Pte Ltd. 2023.
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Coronavirus disease (COVID-19) is an infectious disease caused by coronavirus. Devel-oping specific drugs for inhibiting replication and viral entry is crucial. Several clinical trial studies are underway to evaluate the efficacy of anti-viral drugs for COVID-19 patients. Nanomedicine formulations can present a novel strategy for targeting the virus life cycle. Nano-drug delivery systems can modify the pharmacodynamics and pharmacokinetics properties of anti-viral drugs and reduce their adverse effects. Moreover, nanocarriers can directly exhibit anti-viral effects. A number of nanocarriers have been studied for this purpose, including liposomes, dendrimers, exosomes and decoy nanoparticles (NPs). Among them, decoy NPs have been considered more as nanodecoys can efficiently protect host cells from the infection of SARS-CoV-2. The aim of this review article is to highlight the probable nanomedicine therapeutic strategies to develop anti-viral drug delivery systems for the treatment of COVID-19.Copyright © 2023 Bentham Science Publishers.
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Background & Aim: Liposomes are spherical-shaped vesicles composed of one or more lipid bilayers. The ability of liposomes to encapsulate hydro- or lipophilic drugs allowed these vesicles to become a useful drug delivery system. Natural cell membranes, such as Bioxome, have newly emerged as new source of materials for molecular delivery systems. Bioxome are biocompatible and GMP-compliant liposome-like membrane that can be produced from more than 200 cell types. Bioxome self-assemble, with in-process self-loading capacity and can be loaded with a variety of therapeutic compounds. Once close to the target tissue, Bioxome naturally fuse with the cell membrane and release the inner compound. Orgenesis is interested in evaluating the potential of Bioxome as new drug delivery system for treatment of several diseases, including skin repair, local tumour or COVID19. Methods, Results & Conclusion(s): Bioxome were obtained from adipose- derived Mesenchymal Stem Cells, with a process of organic- solvent lipid extraction, followed by lyophilization and sonication assemblage. During the sonication process, Bioxome were charged or not with several cargos. Size distribution of empty Bioxome was detected by Particle Size Analyzer (NanoSight). Electron Microscopy (EM) was performed to assess Bioxome morphology. Lipid content was evaluated by electrospray ionization system. Dose response in vitro test on human lung fibroblasts treated or not with Bioxome encapsulating a specific cargo (API) against COVID19 were performed. NanoSight analysis showed that nanoparticle size in Bioxome samples ranged between 170+/-50 nm, with a concentration ranging between 109-1010+/-106 particles/mL. EM clearly showed the double phospholipid layers that composes the Bioxome. Stability study demonstrated that Bioxome are stable in size and concentration up to 90 days at +4Cdegree or even at RT. No change in size between encapsulated Bioxome with small size (~340 Da) cargo vs empty Bioxome was observed up to 30 days storage. Lipidomic analysis approach revealed that the yield of lipids and their composition are satisfactory for a therapeutic product using Bioxome. Lastly, in the in vitro model of COVID19, Bioxome encapsulating API effectively saved cells from death (20x vs untreated cells) and at lower doses of API than these of non-encapsulated cargo (0.005 microM vs 0.1 microM). Bioxome seems to be an excellent candidate for liposome mimetic tool as drug delivery system for targeting specific organs and diseases treatment.Copyright © 2023 International Society for Cell & Gene Therapy
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Nucleic acids, as a next generation of biotechnology drugs, not only can fundamentally treat diseases, but also own significant platform characteristics in view of technology and production. Therefore, nucleic acid-based drugs have broad clinical applications in biomedical fields. However, nucleic acids are degradable and unstable, and have very low intracellular delivery efficiency in vitro and in vivo, which greatly limits their applications. In recent years, ionizable lipid-based lipid nanoparticles have shown promising application potentials and have been successfully applied to COVID-19 (Coronavirus Disease 2019) vaccines in clinic. Lipid nanoparticles demonstrate high in vivo delivery efficiency and good safety profile due to their unique structural and physicochemical properties, which provides many possibilities for their clinical applications for nucleic acid delivery in the future. This review focused on the characteristics of nucleic acid drugs and their delivery barriers, and discussed the approved nucleic acid drugs to illustrate the key aspects of the success of their delivery carrier system. In addition, problems to be solved in the field were highlighted.Copyright © 2023, Chinese Pharmaceutical Association. All rights reserved.
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INTRODUCTION: COVID-19 pandemic is one of the most serious public health events of this century. There have been more than 670 million confirmed cases and more than 6 million deaths worldwide. From the emergence of the Alpha variant to the later rampant Omicron variant, the high transmissibility and pathogenicity of SARS-CoV-2 accelerate the research and development of effective vaccines. Against this background, mRNA vaccines stepped onto the historical stage and became an important tool for COVID-19 prevention. AREAS COVERED: This article introduces the characteristics of different mRNA vaccines in the prevention of COVID-19, including antigen selection, therapeutic mRNA design and modification, and different delivery systems of mRNA molecules. It also summarizes and discusses the mechanisms, safety, effectiveness, side effects, and limitations of current COVID-19 mRNA vaccines. EXPERT OPINION: Therapeutic mRNA molecules have plenty of advantages, including flexible design, rapid production, sufficient immune activation, safety without the risk of genome insertion in the host cells, and no viral vectors or particles involved, making them an important tool to fight diseases in the future. However, the application of COVID-19 mRNA vaccines also faces many challenges, such as storage and transportation, mass production, and nonspecific immunity.
Subject(s)
COVID-19 , Viral Vaccines , Humans , COVID-19/prevention & control , SARS-CoV-2/genetics , Pandemics , RNA, Messenger/genetics , mRNA VaccinesABSTRACT
Given the potential respiratory health risks, the association of COVID infection and the use of combustible cigarettes, electronic nicotine delivery systems (ENDS), and concurrent dual use is a priority for public health. Many published reports have not accounted for known covarying factors. This study sought to calculate adjusted odds ratios for self-reported COVID infection and disease severity as a function of smoking and ENDS use, while accounting for factors known to influence COVID infection and disease severity (i.e., age, sex, race and ethnicity, socioeconomic status and educational attainment, rural or urban environment, self-reported diabetes, COPD, coronary heart disease, and obesity status). Data from the 2021 U.S. National Health Interview Survey, a cross-sectional questionnaire design, were used to calculate both unadjusted and adjusted odds ratios for self-reported COVID infection and severity of symptoms. Results indicate that combustible cigarette use is associated with a lower likelihood of self-reported COVID infection relative to non-use of tobacco products (AOR = .64; 95% CI [.55, .74]), whereas ENDS use is associated with a higher likelihood of self-reported COVID infection (AOR = 1.30; 95% CI [1.04, 1.63]). There was no significant difference in COVID infection among dual users (ENDS and combustible use) when compared with non-users. Adjusting for covarying factors did not substantially change the results. There were no significant differences in COVID disease severity between those of varying smoking status. Future research should examine the relationship between smoking status and COVID infection and disease severity utilizing longitudinal study designs and non-self-report measures of smoking status (e.g., the biomarker cotinine), COVID infection (e.g., positive tests), and disease severity (e.g., hospitalizations, ventilator assistance, mortality, and ongoing symptoms of long COVID).
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Vaccines that are delivered orally have several advantages over their counterparts that are administered via injection. Despite the advantages of oral delivery, however, approved oral vaccines are currently limited either to diseases that affect the gastrointestinal tract or to pathogens that have a crucial life cycle stage in the gut. Moreover, all of the approved oral vaccines for these diseases involve live-attenuated or inactivated pathogens. This mini-review summarizes the potential and challenges of yeast oral vaccine delivery systems for animal and human infectious diseases. These delivery systems utilize whole yeast recombinant cells that are consumed orally to transport candidate antigens to the immune system of the gut. This review begins with a discussion of the challenges associated with oral administration of vaccines and the distinct benefits offered by whole yeast delivery systems over other delivery systems. It then surveys the emerging yeast oral vaccines that have been developed over the past decade to combat animal and human diseases. In recent years, several candidate vaccines have emerged that can elicit the necessary immune response to provide significant protection against challenge by pathogen. They serve as proof of principle to show that yeast oral vaccines hold much promise.
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Erythrocytes are the most abundant type of cells in the blood and have a relatively simple structure when mature; they have a long life-span in the circulatory system. The primary function of erythrocytes is as oxygen carriers; however, they also play an important role in the immune system. Erythrocytes recognize and adhere to antigens and promote phagocytosis. The abnormal morphology and function of erythrocytes are also involved in the pathological processes of some diseases. Owing to the large number and immune properties of erythrocytes, their immune functions should not be ignored. Currently, research on immunity is focused on immune cells other than erythrocytes. However, research on the immune function of erythrocytes and the development of erythrocyte-mediated applications is of great significance. Therefore, we aimed to review the relevant literature and summarize the immune functions of erythrocytes.
Subject(s)
Erythrocytes , Immune System , Humans , Phagocytosis , OxygenABSTRACT
Vaccination has been proved to be the most effective strategy to prevent the Corona Virus Disease 2019 (COVID-19). The mRNA vaccine based on nano drug delivery system (NDDS) - lipid nanoparticles (LNP) has been widely used because of its high effectiveness and safety. Although there have been reports of severe allergic reactions caused by mRNA-LNP vaccines, the mechanism and components of anaphylaxis have not been completely clarified yet. This review focuses on two mRNA-LNP vaccines, BNT162b2 and mRNA-1273. After summarizing the structural characteristics, potential allergens, possible allergic reaction mechanism, and pharmacokinetics of mRNA and LNP in vivo, this article then reviews the evaluation methods for patients with allergic history, as well as the regulations of different countries and regions on people who should not be vaccinated, in order to promote more safe injection of vaccines. LNP has become a recognized highly customizable nucleic acid delivery vector, which not only shows its value in mRNA vaccines, but also has great potential in treating rare diseases, cancers and other broad fields in the future. At the moment when mRNA-LNP vaccines open a new era of nano medicine, it is expected to provide some inspiration for safety research in the process of research, development and evaluation of more nano delivery drugs, and promote more nano drugs successfully to market.Copyright © 2023, Chinese Pharmaceutical Association. All rights reserved.
ABSTRACT
Vaccination is the most effective method to prevent dangerous infectious diseases and save lives. The expansion of human communication, the rapid spread of emerging infections worldwide, and the creation of dangerous pandemics like COVID-19 is worrying. On the other hand, with the emergence of new technologies such as genetic engineering of microorganisms, genome editing, and synthetic biology, the possibility of abusing these tools for illegal use is the next concern. In this situation, the need for rapid vaccination technologies and programs was given special importance. Recently, new vaccine platforms such as viral vector and mRNA vaccines have shown great promise that they can be used to prepare and protect human lives against dangerous infections. One of the most important factors for vaccination is the rapid development and approval of vaccines. In this review, we have given a perspective view of new vaccine technologies to rapidly develop vaccine s to combat emerging infections and the biodefence against biological criminals. © 2023 The Author(s).
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In December 2019, Wuhan, China, found SARS-CoV-2. It causes covid-19, a worldwide respiratory illness. Its global pandemic broke out unexpectedly, and the number of infections and deaths continued to rise dramatically, causing the collapse of medical systems and disease control organizations in many countries at the start of the outbreak. Vaccine research and development must be prioritized in order to control and reduce virus spread as soon as possible. The mRNA vaccine stands out among traditional vaccines due to its rapid research and development, ability to stimulate human dual immune responses and non-infectivity. Both humoral and cellular immunity can be stimulated by mRNA vaccines, which means that the produced T cells can help eliminate antigens in time, so their number does not increase in order to protect the original cells, and they can also create long-lived plasma cells and memory B cells to continue playing an immunological role for years. mRNA vaccines may not need repeated injections, unlike inactivated vaccinations, which may enhance efficiency. the first mRNA vaccinations that were made accessible to the general population when the US FDA approved its emergency use in December 2020. The generation of mRNA for the mRNA vaccination uses cell-free expression techniques and in vitro transcription-based systems. LNPs system, a nanoscale vesicle that can enclose mRNA in their cavity and imitates the lipid structure of the cell membrane, is the most often utilized delivery system in mRNA vaccines. The most common mRNA vaccine technique involves injecting a genetic component that tells the body to make a protein fragment of a specific pathogen, which the immune system recognizes and keeps mounting a robust response if it is subsequently exposed to that pathogen. © 2023 SPIE.
ABSTRACT
Messenger RNA(mRNA)medicine was urgently approved in 2020 as a vaccine for COVID-19 . However, current mRNA therapeutics are not fully established, with challenges remaining in translation efficiency and drug delivery system. Therefore, further research is needed to adapt mRNA therapeutics to other diseases. Furthermore, the preparation of mRNA drugs is time-consuming and costly because of the biological methods used. Our laboratory has been working on chemical methods to solve these issues. In this paper, we introduce chemical modifications and novel capping reactions as a method to improve the translation efficiency of mRNA and the introduction of disulfide modification to oligonucleotide therapeutics as an effort on the drug delivery system.Copyright © 2023, Japan Society of Drug Delivery System. All rights reserved.