New respiratory viruses of humans

Natural Binary Herbal Small Molecules Self-Assembled Nanogel for Synergistic Inhibition of Respiratory Syncytial Virus

Respiratory syncytial virus (RSV) is one of the most significant pathogenic infections in childhood, associated with high morbidity and mortality rates. Currently, there is no effective and safe drug or vaccine available for RSV. Glycyrrhizic acid (GA), an active compound derived from the natural herb licorice, has been reported to provide protection against influenza and coronaviruses, exhibiting notable antiviral and anti-inflammatory properties. Ephedrine (EPH) is a commonly prescribed medication for the treatment of cough and asthma, and it also demonstrates certain antiviral effects. In this study, EPH and GA were combined to form an efficient nanomaterial (EPH-GA nanogel). The self-assembly of this nanogel is driven by hydrogen bonding and hydrophobic interactions, allowing it to serve as an antiviral nanomedicine without the need for a dual-component carrier, achieving a 100% drug loading efficiency. Oral administration of the EPH-GA nanogel significantly reduced viral load in the lungs of mice and improved lung lesions and tissue infiltration caused by RSV. Notably, we discovered that the assembled drug may create a "physical barrier" that prevents RSV from adsorbing to host cells, while free GA and EPH may compete with RSV for protein binding sites, thereby enhancing cellular uptake of EPH. Consequently, this prevents RSV infection and proliferation within host cells. Furthermore, the EC50 values changed from 310.83 μM for EPH and 262.88 μM for GA to 68.25 μM for the EPH-GA combination, with a combination index of 0.458. In addition, the in vivo biopharmaceutic process of GA and EPH was investigated, revealing that the oral administration of EPH-GA significantly increased the bioavailability of EPH while maintaining its plasma concentration at a relatively stable level. This enhancement may contribute to a synergistic antiviral effect when combined with GA. Furthermore, the in vivo process of EPH-GA demonstrates the advantage of delivering the drug to the lesion at elevated levels, thereby facilitating its antiviral mechanism at the cellular level. In this study, we identified an effective nanomedicine, EPH-GA nanogel, which can inhibit the proliferation of RSV and mitigate lung lesions resulting from viral infection by influencing the biopharmaceutical process in vivo. This research not only offers a novel strategy for the nanomedicine treatment of RSV but also elucidates, to some extent, the compatibility mechanisms of the multicomponents of traditional Chinese medicine.

Epidemiologic Analysis of Respiratory Viral Infections Mainly in Hospitalized Children and Adults in a Midwest University Medical Center After the Implementation of a 14-Virus Multiplex Nucleic Acid Amplification Test

OBJECTIVES

To investigate the etiology of viral respiratory tract infections mainly in hospitalized children and adults over a 12-month consecutive period after implementation of a 14-virus multiplex nucleic acid amplification test.

METHODS

From January 2014 to January 2015, a total of 2,237 respiratory samples were analyzed with the US Food and Drug Administration-cleared eSensor Respiratory Viral Panel (GenMark Diagnostics, Carlsbad, CA).

RESULTS

Of the 2,237 specimens tested, 788 specimens were positive for at least one virus, giving a positivity rate of 35.2%, and because of viral codetection, a total of 862 viral targets were identified. The age groups with the highest positivity rates were the 0- to 1-year (73.5%) and 2- to 6-year (78.4%) age groups. The overall viral codetection rate was 9.1%. Human rhinovirus (HRV) was the most prevalent respiratory virus found in children and adults. The peak of HRV seen in September 2014 represented a combination of HRV and enterovirus D68, 2014 epidemic respiratory infections.

CONCLUSION

The ability to detect a wider range of respiratory viruses gave us a better understanding of the etiology of respiratory infections in our population, particularly for HRV and enhanced our ability to detect viral coinfection.

Antivirals for Respiratory Viral Infections: Problems and Prospects

In the past two decades, several newly emerging and reemerging viral respiratory pathogens including several influenza viruses (avian influenza and pandemic influenza), severe acute respiratory syndrome coronavirus (SARS-CoV), and Middle East respiratory syndrome coronavirus (MERS-CoV), have continued to challenge medical and public health systems. Thereafter, the development of cost-effective, broad-spectrum antiviral agents is the urgent mission of both virologists and pharmacologists. Current antiviral developments have focused targets on viral entry, replication, release, and intercellular pathways essential for viral life cycle. Here, we review the current literature on challenges and prospects in the development of these antivirals.

Detection of respiratory viruses by real-time polymerase chain reaction in outpatients with acute respiratory infection

Viruses are the major contributors to the morbidity and mortality of upper and lower acute respiratory infections (ARIs) for all age groups. The aim of this study was to determine the frequencies for a large range of respiratory viruses using a sensitive molecular detection technique in specimens from outpatients of all ages with ARIs. Nasopharyngeal aspirates were obtained from 162 individuals between August 2007-August 2009. Twenty-three pathogenic respiratory agents, 18 respiratory viruses and five bacteria were investigated using multiplex real-time reverse transcriptase polymerase chain reaction (RT-PCR) and indirect immunofluorescence assay (IIF). Through IIF, 33 (20.4%) specimens with respiratory virus were recognised, with influenza virus representing over half of the positive samples. Through a multiplex real-time RT-PCR assay, 88 (54.3%) positive samples were detected; the most prevalent respiratory viral pathogens were influenza, human rhinovirus and respiratory syncytial virus (RSV). Six cases of viral co-detection were observed, mainly involving RSV. The use of multiplex real-time RT-PCR increased the viral detection by 33.9% and revealed a larger number of respiratory viruses implicated in ARI cases, including the most recently described respiratory viruses [human bocavirus, human metapneumovirus, influenza A (H1N1) pdm09 virus, human coronavirus (HCoV) NL63 and HCoV HKU1].

The type I interferon response during viral infections: a "SWOT" analysis

The type I interferon (IFN) response is a strong and crucial moderator for the control of viral infections. The strength of this system is illustrated by the fact that, despite some temporary discomfort like a common cold or diarrhea, most viral infections will not cause major harm to the healthy immunocompetent host. To achieve this, the immune system is equipped with a wide array of pattern recognition receptors and the subsequent coordinated type I IFN response orchestrated by plasmacytoid dendritic cells (pDCs) and conventional dendritic cells (cDCs). The production of type I IFN subtypes by dendritic cells (DCs), but also other cells is crucial for the execution of many antiviral processes. Despite this coordinated response, morbidity and mortality are still common in viral disease due to the ability of viruses to exploit the weaknesses of the immune system. Viruses successfully evade immunity and infection can result in aberrant immune responses. However, these weaknesses also open opportunities for improvement via clinical interventions as can be seen in current vaccination and antiviral treatment programs. The application of IFNs, Toll-like receptor ligands, DCs, and antiviral proteins is now being investigated to further limit viral infections. Unfortunately, a common threat during stimulation of immunity is the possible initiation or aggravation of autoimmunity. Also the translation from animal models to the human situation remains difficult. With a Strengths-Weaknesses-Opportunities-Threats ("SWOT") analysis, we discuss the interaction between host and virus as well as (future) therapeutic options, related to the type I IFN system.

Pulmonary pathology of pandemic influenza A/H1N1 virus (2009)-infected ferrets upon longitudinal evaluation by computed tomography

We investigated the development of pulmonary lesions in ferrets by means of computed tomography (CT) following infection with the 2009 pandemic A/H1N1 influenza virus and compared the scans with gross pathology, histopathology and immunohistochemistry. Ground-glass opacities observed by CT scanning in all infected lungs corresponded to areas of alveolar oedema at necropsy. These areas were most pronounced on day 3 and gradually decreased from days 4 to 7 post-infection. This pilot study shows that the non-invasive imaging procedure allows quantification and characterization of influenza-induced pulmonary lesions in living animals under biosafety level 3 conditions and can thus be used in pre-clinical pharmaceutical efficacy studies.

Association between respiratory and herpes viruses on pulmonary exacerbations in cystic fibrosis patients

Respiratory viruses discovered in the 21st century and human herpes viruses (N=13) were seldom (4/50) detected in our cystic fibrosis patients although exacerbation frequency (7.75+/-2.9/a versus 4.45+/-2.1/a; p=0.03) and colonization with Aspergillus fumigatus (RR: 2.6; CI95: 1.8-3.7), Pseudomonas aeruginosa (RR: 1.84; CI95: 1.4-2.4), and Staphylococcus aureus (RR: 1.5; CI95: 1.2-1.9) including MRSA (RR: 4.6; CI95: 1.3-16.6) were associated with virus positivity. Further studies should clarify whether this finding reflects non-specific colonization (human Bocavirus) or reactivation (Epstein-Barr virus) or rather an acceleration of lung tissue inflammation.

Vaccination for respiratory immunity: latest developments

Advances over the last 20 years in immunology and molecular biology have provided many new tools for identifying the important antigens and new ways to achieve the appropriate immune responses to these antigens. These provide many more options to achieve the best immune response from deletion mutations, subunit antigens, vectors or DNA immunization. These tools are being adopted to screen, discover and produce the appropriate antigens and to deliver them by the optimal method and with novel adjuvants to achieve the appropriate immune response. These developments will result in vaccines for respiratory disease that are safer and more efficacious, and provide greater flexibility for use and administration.

Human monoclonal antibodies to SARS-coronavirus inhibit infection by different mechanisms

SARS-CoV causes an acute infection making targeted passive immunotherapy an attractive treatment strategy. We previously generated human mAbs specific to the S1 region of SARS-CoV S protein. These mAbs bind epitopes within the receptor binding domain (RBD) or upstream of the RBD. We show that mAbs recognizing epitopes within the RBD inhibit infection by preventing viral attachment to the cellular receptor. One mAb binds upstream of the RBD and prevents viral entry by inhibiting a post-binding event. Evaluation of several mAbs demonstrated varying ability of the mAbs to select escape mutants when used individually. However, a mixture of antibodies could effectively neutralize a range of mutant viruses. These data strongly suggest that a mixture containing antibodies recognizing distinct regions and targeting more than one step in viral entry is likely to be more effective in neutralizing the virus and suppressing the generation of escape mutants, and thus potentially constitute a highly effective passive immunotherapy.