Development of a nasal spray containing xylometazoline hydrochloride and iota-carrageenan for the symptomatic relief of nasal congestion caused by rhinitis and sinusitis

The increasingly large number of chemicals introduced onto the market and into the environment has necessitated the monitoring of environmental materials and specimen banking, as well as the development of rapid and reliable methods for the evaluation of toxicity. The Hen's Egg Test, or Hühner-Embryonen-Test (HET) is a rapid, sensitive and inexpensive toxicity test and can give information on embryotoxicity, teratogenicity, systemic and immunopathological effects, metabolic pathways and now, in developed form, on mucous-membrane irritation potencies of chemical substances. Testing with incubated hen's eggs is a borderline case between in vivo and in vitro systems and does not conflict with ethical and legal obligations especially animal protection laws. In the special field of mucous-membrane irritation testing, a specific score and classification scheme was developed for the HET, which allows risk assessments analogous to the Draize scheme. There is a good correlation between the results for HET tests on a variety of pyrithiones, phenols and isothiazolinones, and the corresponding data based on Draize tests. HET chorioallantoic membrane testing should and could not entirely replace current irritation tests in mammals, but it can diminish the number of investigations with mammals, as well as limit or eliminate pain and injury during animal experiments and allow regulators to set priority and toxicity categories.

Though several antivirals have been developed and marketed to treat influenza virus infections, the development of antiviral agents with clinical activity against other respiratory viruses has been more problematic. Here we review the epidemiology of respiratory viral infections in immunocompetent and immunocompromised hosts, examine the evidence surrounding the currently available antivirals for respiratory viral infections other than influenza, highlight those that are in the pipeline, and discuss the hurdles for development of such agents.

Agars and carrageenans are 1,3-alpha-1,4-beta-galactans from the cell walls of red algae, substituted by zero (agarose), one (kappa-), two (iota-), or three (lambda-carrageenan) sulfate groups per disaccharidic monomer. Agars, kappa-, and iota-carrageenans auto-associate into crystalline fibers and are well known for their gelling properties, used in a variety of laboratory and industrial applications. These sulfated galactans constitute a crucial carbon source for a number of marine bacteria. These microorganisms secrete glycoside hydrolases specific for these polyanionic, insoluble polysaccharides, agarases and carrageenases. This article reviews the microorganisms involved in the degradation of agars and carrageenans, in their environmental and taxonomic diversity. We also present an overview on the biochemistry of the different families of galactanases. The structure-function relationships of the family GH16 beta-agarases and kappa-caraggeenases and of the family GH82 iota-carrageenases are discussed in more details. In particular, we examine how the active site topologies of these glycoside hydrolases influence their mode of action in heterogeneous phase. Finally, we discuss the next challenges in the basic and applied field of the galactans of red algae and of their related degrading microorganisms.