Collection and Testing of Respiratory Samples

NCT ID: NCT01302418

Last Updated: 2017-05-10

Basic Information

• Recruitment Status: COMPLETED
• Total Enrollment: 272 participants
• Study Classification: OBSERVATIONAL
• Study Start Date: 2011-02-28
• Study Completion Date: 2011-11-30

Brief Summary

The study will be conducted using nasopharyngeal swab specimens collected prospectively from individuals suspected of having the signs and symptoms of an acute respiratory tract infection caused by a respiratory virus. A series of standard viral culture tests validated for routine use in the clinical laboratory, and/or a series of PCR-based Laboratory Developed Tests (PCR-LDT) validated by a central reference laboratory will be used to verify the performance of the investigational artus Influenza A/B RT-PCR test and the QIAGEN ResPlex II Advanced Panel test. From each specimen five (5) aliquots will be prepared: (a) one aliquot will be tested in real-time using the assigned viral culture reference methods; (b) one aliquot will be used to extract nucleic acid in real-time for investigational testing; (c) one aliquot of the specimen will be stored at --70C for subsequent shipment to the reference laboratory for PCR-LDT testing, (d) one aliquot will be archived at -70C for subsequent follow-up by the reference laboratory (e.g., bi-directional sequencing of positive specimens), and (e) any remaining specimen will be stored for the Fresh vs. Frozen Study. The extracted nucleic acid generated from the second aliquot (i.e., "b" above) will be split and subjected to testing by both the artus Influenza A/B RT-PCR test and the ResPlex II Advanced Panel test.

Detailed Description

Each year the morbidity and mortality associated with acute respiratory tract infections fluctuates seasonally. This rise and fall is associated with the changing prevalence of respiratory viruses in the population. Myriad respiratory viruses are responsible for these infections. For example, Influenza Virus, Respiratory Syncytial Virus (RSV), Parainfluenza Virus, Human Metapneumovirus, Rhinovirus, and Adenovirus have all been identified as causing such acute infections. Numerous pathogenic subtypes have been identified within most of these viral groups. The outbreak of Severe Acute Respiratory Syndrome (SARS) in 2003 was eventually identified as a Coronavirus; the mortality of SARS among the elderly can be as high as 50%. More recently, Human Bocavirus (HBoV) has also been identified as causing acute respiratory tract infections. In 2005 the HBoV was identified by molecular testing and was found to be the only virus identified in a subpopulation of patients suffering from respiratory tract infections. Apart from supportive measure (e.g., bed rest, hydration, etc.), there are no effective treatments for many of these viral infections; however, antiviral agents (e.g., the neuraminidase inhibitors oseltamivir or zanamivir) can be used to alleviate the severity of flu-like symptoms. Identification of a respiratory virus as the causative agent is important because it eliminates the need for treatment with antibiotics; physicians typically wait 7-10 days for symptoms to alleviate before prescribing antibiotics due to risks associated with exacerbating bacterial antibiotic resistance.

Each year the virus population fluctuates, and with it the antigenic presentation of the dominant strains that circulate through the population. Epidemics arise when larger and larger portions of the population do not have innate or acquired immunological resistance to such strain(s) in a given season. The World Health Organization (WHO) maintains a separate website dedicated to tracking outbreaks of influenza, especially avian influenza (https://www.who.int/fluvirus_tracker). These zoonotic transmissions that further adapt to enable human-to-human transmission are of the greatest concern because it is predicted that virtually all humans will be immunologically naïve. Zoonotic transmissions in the human population are monitored in the hope that a pandemic similar to the Spanish Flu of 1918 can be avoided; it is estimated that well over 25 million people died from the Spanish Flu. The United States government also maintains a separate website with resources regarding the flu and pandemic related information (http://www.pandemicflu.gov/). On June 11, 2009 the WHO raised the pandemic threat level to 6 in response to the global appearance of a new strain of swine Influenza A (subtype H1N1). The rapidity with which the H1N1 virus has spread exemplifies the notion that quickly and accurately identifying a viral pathogen associated with an outbreak is critical to global public health.

In addition to the threat of an influenza outbreak, the expansion in the number of viruses that cause acute respiratory tract infections compounds the difficulty in correctly and rapidly identifying the primary pathogen; each new virus or subtype increases the complexity of testing. Molecular diagnostic assays are ideally suited to address this complexity. Assays based on the polymerase chain reaction (PCR) can incorporate multiple primers and probes (e.g., multiplexed) in a single reaction to deal with this complexity.4 Such assays are extremely sensitive, have a high degree of specificity, and can be performed very quickly. The artus Influenza A/B RT-PCR test is a real-time PCR assay for the detection and identification of Influenza A and B, while the QIAGEN ResPlex II Advanced Panel test is a nucleic acid amplification-based assay for the detection and identification of a broad range of some of the most common respiratory viruses associated with acute respiratory tract infections. In the present study respiratory specimens will be prospectively collected and tested using the artus Influenza A/B RT-PCR test and the QIAGEN ResPlex II Advanced Panel test.

Conditions

QIAGEN ResPlex II Advanced Panel; Influenza A; Respiratory Syncytial Virus Infections; Infection Due to Human Parainfluenza Virus 1; Parainfluenza Type 2; Parainfluenza Type 3; Parainfluenza Type 4; Human Metapneumovirus A/B; Rhinovirus; Coxsackie Virus/Echovirus; Adenovirus Types B/C/E; Coronavirus Subtypes 229E; Coronavirus Subtype NL63; Coronavirus Subtype OC43; Coronavirus Subtype HKU1; Human Bocavirus; Artus Influenza A/B RT-PCR Test; Influenza B

Study Design

• Observational Model Type: CASE_ONLY
• Study Time Perspective: PROSPECTIVE

Study Groups

Symptomatic

Individuals with signs and symptoms of an acute respiratory tract infection where it is suspected that such signs and symptoms are caused by a respiratory virus infection.

artus Influenza A/B RT-PCR Test

Intervention Type: DEVICE

The investigational assay, used for detecting the presence of Influenza A/B.

Interventions

artus Influenza A/B RT-PCR Test

The investigational assay, used for detecting the presence of Influenza A/B.

Intervention Type: DEVICE

Eligibility Criteria

Inclusion Criteria

• Subjects that sign the Informed Consent form required for prospectively enrolling patients into the study.
• Subjects that present at a hospital, clinic, or physician's office with the signs and symptoms of a respiratory tract infection.
• Subjects with an acute respiratory infection where said acute respiratory infection is suspected of being caused by an Influenza virus.

Exclusion Criteria

• Subjects where the duration of the symptoms of such an acute respiratory infection is greater than or equal to 5 days (i.e., ≥5).

• Eligible Sex: ALL
• Accepts Healthy Volunteers: No

Sponsors

QIAGEN Gaithersburg, Inc

INDUSTRY

Sponsor Role: lead

Responsible Party

Responsibility Role: SPONSOR

Locations

University of Arizona

Tuscon, Arizona, United States

Albany Medical College

Albany, New York, United States

Wadsworth Center, New York State Department of Health

Albany, New York, United States

The University of North Carolina

Chapel Hill, North Carolina, United States

Ohio State University

Columbus, Ohio, United States

Countries

United States

Other Identifiers

C10-INFLUENZA-001

Identifier Type: -

Identifier Source: org_study_id