Lipid based nanocarriers: Production techniques, concepts, and commercialization aspect

Over the past decade, compared to all other macromolecules lipid-based nanocarriers have proven to be an excellent carrier and delivery system for various pharmaceutical drugs of poor bioavailability. In addition to that, they exhibit exceptional qualities such as minimal toxicity, economical scale-up production, great biocompatibility, and high drug loading efficiency. In this study, we have discussed the various types of lipid nanoparticles, such as liposomes, nanostructured lipid carriers, solid lipid nanoparticles, and lipid polymer hybrid nanoparticles. We have also conferred in detail, the composition, shape and size, methods of preparation, advantages, and certain limitations associated with these lipid-based nanocarriers. Additionally, we have exclusively accounted for several examples of lipid-based nanomedicines that have either been approved and commercialized or are under the different phases of clinical trials. The current review overall focuses on the up-to-date research that has recently been published in view of developing lipid-based nanocarriers for various biological applications, including gene therapy, breast cancer therapy, and vaccine development.Copyright © 2022

Viral vector vaccines: ef forts to develop vaccines against emerging infectious diseases.

Vaccines are one of the most effective means of preventing viral infections. Since Edward Jenner invented the world's first vaccine in 1796, against smallpox, various types of vaccine have been DDS developed, including inactivated vaccines, attenuated live vaccines, recombinant protein vaccines, viral vector vaccines and nucleic acid vaccines. Viral vector vaccines and nucleic acid vaccines mRNA vaccines and DNA vaccineshave been developed most recently. In these vaccines, genes encoding viral proteins that serve as antigens are introduced into the body. The viral vector is an excellent vaccine delivery system that efficiently delivers antigen genes to target cells, and has been utilized for vaccine development against a variety of emerging infectious diseases, including AIDS, malaria, Ebola hemorrhagic fever, dengue fever, and most recently COVID-19 . Here, we provide an overview of viral vector vaccines and discuss recent efforts to develop vaccines against emerging infectious diseases.Copyright © 2022, Japan Society of Drug Delivery System. All rights reserved.

SARS-CoV-2 Vaccines: Types, Working Principle, and Its Impact on Thrombosis and Gastrointestinal Disorders.

In the current scenario of the coronavirus pandemic caused by Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2), considerable efforts have been made to control the pandemic by the development of a strong immune system through massive vaccination. Just after the discovery of the genetic sequences of SARS-CoV-2, the development of vaccines became the prime focus of scientists around the globe. About 200 SARS-CoV-2 candidate vaccines have already been entered into preclinical and clinical trials. Various traditional and novel approaches are being utilized as a broad range of platforms. Viral vector (replicating and non-replicating), nucleic acid (DNA and RNA), recombinant protein, virus-like particle, peptide, live attenuated virus, an inactivated virus approaches are the prominent attributes of the vaccine development. This review article includes the current knowledge about the platforms used for the development of different vaccines, their working principles, their efficacy, and the impacts of COVID-19 vaccines on thrombosis. We provide a detailed description of the vaccines that are already approved by administrative authorities. Moreover, various strategies utilized in the development of emerging vaccines that are in the trial phases along with their mode of delivery have been discussed along with their effect on thrombosis and gastrointestinal disorders.

Attitude and knowledge towards the effectiveness of nucleic acid-based vaccines among healthcare workers and medical students in the Jordanian population

Since the beginning of the COVID-19 pandemic, catastrophic mortality and morbidity rates and unknown long-term ramifications were caused, leading to focused efforts on implementing effective vaccination. Nucleic acid-based vaccines (NBVs), an emergent advance in vaccine development, presented high efficacy rates but controversy regarding this approach soon spread. This study assesses healthcare workers (HCWs) knowledge and attitude towards NBVs' effectiveness. This cross-sectional study was conducted in Jordan from November 2020 to January 2021 through a web-based questionnaire. 320 participants were split into educated and uneducated groups, with the former being exposed to educational material on NBVs before survey completion. The educated group expressed increased concern towards NBVs' side effects. Specifically, the risk of developing cancer due to genetic modification(40.8%), fever(69.4%), skin rash(58.0%), and amyloid deposition(40.8%) showed a significant difference. The educated group preferred RNA-based NBVs over DNA-based ones(43.9%), had double the response rate, provided more scientifically accurate answers, and showed a more positive attitude towards the ability of NBVs to induce cellular immunity (57.3%) and prevent chronic forms of COVID-19(57.3%) (p < 0.05). Because HCWs are the most integral players in shaping public opinion about NBVs, thorough educational material on NBVs needs to be integrated within the curricula of health-related programs to bridge the gap present. This could prove vital in ensuring the success of the current and future vaccination campaigns. Copyright © 2022 The Author(s). This open access article is distributed under a Creative Commons Attribution (CC-BY) 4.0 license.

Advances in the polymeric delivery of nucleic acid vaccines.

Nucleic acid vaccines, especially messenger RNA (mRNA) vaccines, display unique benefits in the current COVID-19 pandemic. The application of polymeric materials as delivery carriers has greatly promoted nucleic acid vaccine as a promising prophylactic and therapeutic strategy. The inherent properties of polymeric materials render nucleic acid vaccines with excellent in vivo stability, enhanced biosafety, specific cellular uptake, endolysosomal escape, and promoted antigen expression. Although polymeric delivery of nucleic acid vaccines has progressed significantly in the past decades, clinical translation of polymer-gene vaccine systems still faces insurmountable challenges. This review summarizes the diverse polymers and their characterizations and representative formulations for nucleic acid vaccine delivery. We also discussed existing problems, coping strategies, and prospect relevant to applications of nucleic acid vaccines and polymeric carriers. This review highlights the rational design and development of polymeric vaccine delivery systems towards meeting the goals of defending serious or emerging diseases.

Essentials of COVID-19 and treatment approaches

The coronavirus family is as old as the 1930s when it first showed symptoms in chicken. The virus thereafter kept evolving and it has significantly taken over a large percentage of people worldwide in the form of this new pandemic. As of the present day, there is no treatment available for coronavirus disease 2019 (COVID-19) (caused by the severe acute respiratory syndrome coronavirus 2 [SARS-CoV-2]), although supportive therapy and preventive measures have shown a tremendous control rate among certain patients. Drugs like remdesivir, camostat, nafamostat, ritonavir/lopinavir, several monoclonal antibodies, and CPs are in their early phases of trials. There are approved by the WHO under an emergency use authorization program. Favipiravir has entered its phase 3 clinical trial and is supported by evidence to show no or less adverse effects in patients infected with SARS-CoV-2. Vaccine development is accelerating its pace, and vaccines will probably become available by the end of the year 2020. © 2022 Elsevier Inc.

Latest progress and prospect of development of COVID-19 vaccine

The emerging Corona virus Disease 2019 (COVID-19) pandemic poses a massive crisis to global public health. World Health Organization (WHO) declared the global pandemic of COVID-19 on March 11, 2020. The progress of 2019- nCoV vaccines cover nearly all forms of current vaccine research, including inactivated vaccine, recombinant protein vaccine, viral vector-based vaccine, nucleic-acid vaccine and live attenuated vaccine, as well as the vaccine design based on novel concepts such as reverse vaccinology and vaccinomics. This article reviews the COVID-19 vaccines in de¬velopment and clinical trials as well as the challenge in vaccine development.

SARS-CoV-2-Specific Vaccine Candidates; the Contribution of Structural Vaccinology.

SARS-CoV-2 vaccine production has taken us by storm. We aim to fill in the history of concepts and the work of pioneers and provide a framework of strategies employing structural vaccinology. Cryo-electron microscopy became crucial in providing three-dimensional (3D) structures and creating candidates eliciting T and B cell-mediated immunity. It also determined structural changes in the emerging mutants in order to design new constructs that can be easily, quickly and safely added to the vaccines. The full-length spike (S) protein, the S1 subunit and its receptor binding domain (RBD) of the virus are the best candidates. The vaccine development to cease this COVID-19 pandemic sets a milestone for the pan-coronavirus vaccine's designing and manufacturing. By employing structural vaccinology, we propose that the mRNA and the protein sequences of the currently approved vaccines should be modified rapidly to keep up with the more infectious new variants.

A pervasive review on new advancements of nano vaccines on covid-19 pandamic

The infection that causes COVID-19 may be a pathogen referred to as severe acute respiratory syndrome coronavirus-2 (SARS-CoV-2) and is believed to possess originated from China's Wuhan Province. The rapid spread of coronavirus disease 2019 (COVID-19) has become a worldwide concern, with the planet Health Organization (WHO) declaring it an epidemic on March, 2020. To enter the cells, SARS-CoV-2 S requires angiotensin-converting enzyme 2 (ACE2). Many existing vaccines have drawbacks like insufficient system stimulation, in vivo instability, high toxicity, the need for a chilly chain, and multiple administration. A nanotechnology is an efficient tool for addressing these issues. A successful vaccine against SARS-CoV-2 infection is predicted to stimulate innate and adaptive immune responses and protects against severe sorts of coronavirus disease 2019 (COVID-19). Different strategies are introduced because the go after an efficient and safe vaccination has begun. Currently, the foremost common vaccine types studied in clinical trials include viral vector-based vaccinations, genetic vaccines, attenuated vaccines, and protein-based vaccines. during this review, we cover the foremost promising anti-COVID-19 vaccine clinical trials also as various vaccination strategies to shed more light on the continued clinical trials. it's also discussed how nanotechnology is often wont to better understand the pathology of the present pandemic, also as how our understanding of SARS-CoV-2 cellular uptake and toxicity can influence future nanotoxicological considerations and nanomedicine design of safe yet effective nanomaterials.

Co-Delivery of mRNA and pDNA Using Thermally Stabilized Coacervate-Based Core-Shell Nanosystems.

Co-delivery of different species of protein-encoding polynucleotides, e.g., messenger RNA (mRNA) and plasmid DNA (pDNA), using the same nanocarrier is an interesting topic that remains scarcely researched in the field of nucleic acid delivery. The current study hence aims to explore the possibility of the simultaneous delivery of mRNA (mCherry) and pDNA (pAmCyan) using a single nanocarrier. The latter is based on gelatin type A, a biocompatible, and biodegradable biopolymer of broad pharmaceutical application. A core-shell nanostructure is designed with a thermally stabilized gelatin-pDNA coacervate in its center. Thermal stabilization enhances the core's colloidal stability and pDNA shielding effect against nucleases as confirmed by nanoparticle tracking analysis and gel electrophoresis, respectively. The stabilized, pDNA-loaded core is coated with the cationic peptide protamine sulfate to enable additional surface-loading with mRNA. The dual-loaded core-shell system transfects murine dendritic cell line DC2.4 with both fluorescent reporter mRNA and pDNA simultaneously, showing a transfection efficiency of 61.4 ± 21.6% for mRNA and 37.6 ± 19.45% for pDNA, 48 h post-treatment, whereas established commercial, experimental, and clinical transfection reagents fail. Hence, the unique co-transfectional capacity and the negligible cytotoxicity of the reported system may hold prospects for vaccination among other downstream applications.

[Progress and analysis on the development of 2019-nCoV vaccine].

As the COVID-19 pandemic is intensifying globally, more and more people are pinning their hopes on the development of vaccines. At present, there are many research teams who have adopted different vaccine technology routes to develop 2019-nCoV vaccines. This article reviews and analyzes the current development and research status of 2019-nCoV vaccines in different routes, and explores their possible development in the future.