Common colds incur significant costs in terms of sick leave and personal discomfort for affected individuals. This study investigated the performance of ColdZyme® Mouth Spray (ColdZyme), a protective barrier against common cold, in rhinovirus-inoculated healthy volunteers. This randomized, doubleblind, placebo-controlled pilot study was conducted on 46 healthy volunteers inoculated with rhinovirus 16 via the nose. Subjects self-administered ColdZyme or placebo 6 times daily for 11 days. Symptoms were recorded daily in a diary. Rhinovirus 16 in nasal and oropharyngeal samples at days 0, 3, 4, 6, 7 and 10 were quantified by RT-qPCR. The primary outcome measure was the reduction in viral load in oropharyngeal samples. Rhinovirus 16 was only detected in 35 out of 46 inoculated subjects. Exploratory analysis measuring the total viral load (i.e., area under the curve (AUC)) for days 3 -10 in successfully inoculated subjects found that ColdZyme treatment resulted in a lower total viral load in the oropharynx (p = 0.023). In subjects who experienced symptomatic common cold, irrespectively, if virus were detected, treatment with ColdZyme resulted in a reduction in the number of days with common cold symptoms from 6.5 to 3.0 days (p = 0.014) in comparison to placebo. ColdZyme reduced virus infection in the oropharynx and reduced the number of days with common cold symptoms and highlights the possible importance of the oropharynx in common cold infections. Suitable outcome measures for a feasible study on ColdZyme are total viral load in the oropharynx in subjects having detectable virus present in nasal or oropharyngeal samples.
Proteases have been used in medicine for several decades and are an established and well tolerated class of therapeutic agent. These proteases were sourced from mammals or bacteria that exist or have adapted to moderate temperatures (mesophilic organisms); however, proteases derived from organisms from cold environments—cold-adapted or psychrophilic proteases—generally have high specific activity, low substrate affinity, and high catalytic rates at low and moderate temperatures. Made possible by greater flexibility, psychrophilic enzymes interact with and transform the substrate at lower energy costs. Cold-adapted proteases have been used in a wide range of applications, including industrial functions, textiles, cleaning/hygiene products, molecular biology, environmental bioremediations, consumer food products, cosmetics, and pharmaceutical production. In addition to these applications, they have also shown promise as therapeutic modalities for cosmeceutical applications (by reducing glabellar [frown] lines) and a number of disease conditions, including bacterial infections (by disrupting biofilms to prevent bacterial infection), topical wound management (when used as a debridement agent to remove necrotic tissue and fibrin clots), oral/dental health management (by removing plaque and preventing periodontal disease), and in viral infections (by reducing the infectivity of viruses, such as human rhinovirus 16 and herpes simplex virus). Psychrophilic proteases with greater activity and stability (than the original organism-derived variant) have been developed; this coupled with available manufacturing recombinant production techniques suggests that cold-adapted proteases have a promising future as a distinct therapeutic class with diverse clinical applications.
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