Drug – bio-affecting and body treating compositions – Designated organic active ingredient containing – Nitrogen containing other than solely as a nitrogen in an...
Reexamination Certificate
2001-09-27
2003-10-21
Page, Thurman K. (Department: 1615)
Drug, bio-affecting and body treating compositions
Designated organic active ingredient containing
Nitrogen containing other than solely as a nitrogen in an...
C514S937000, C514S938000
Reexamination Certificate
active
06635676
ABSTRACT:
FIELD OF THE INVENTION
The present invention relates to compositions and methods for decreasing the infectivity, morbidity, and rate of mortality associated with a variety of pathogens. The present invention also relates to methods and compositions for decontaminating areas, samples, solutions, and foodstuffs colonized or otherwise infected by pathogens and microorganisms.
BACKGROUND OF THE INVENTION
Pathogens such as bacteria, fungi, viruses, and bacterial spores are responsible for a plethora of human and animal ills, as well as contamination of food and biological and environmental samples. The first step in microbial infections of animals is generally attachment or colonization of skin or mucus membranes, followed by subsequent invasion and dissemination of the infectious microbe. The portals of entry of pathogenic bacteria are predominantly the skin and mucus membranes.
In particular, bacteria of the Bacillus genus form stable spores that resist harsh conditions and extreme temperatures. Contamination of farmlands with
B. anthracis
leads to a fatal disease in domestic, agricultural, and wild animals (See e.g., Dragon and Rennie, Can. Vet. J. 36:295 [1995]). Human infection with this organism usually results from contact with infected animals or infected animal products (See e.g., Welkos et al., Infect. Immun. 51:795 [1986]). Human clinical syndromes include a pulmonary form that has a rapid onset and is frequently fatal. The gastrointestinal and cutaneous forms of anthrax, although less rapid, can result in fatalities unless treated aggressively (See e.g., Franz et al., JAMA 278:399 [1997]; and Pile et al., Arch. Intem. Med. 158:429 [1998]).
Bacillus anthracis
infection in humans is no longer common due to effective animal controls that include vaccines, antibiotics and appropriate disposal of infected livestock. However, animal anthrax infection still represents a significant problem due to the difficulty in decontamination of land and farms. In addition, there is concern about human infection brought about by warfare and/or terrorist activities.
While an anthrax vaccine is available (See e.g., Ivins et al., Vaccine 13:1779 [1995]) and can be used for the prevention of classic anthrax, genetic mixing of different strains of the organism can render the vaccine ineffective (See e.g., Mobley, Military Med. 160:547 [1995]). The potential consequences of the use of Anthrax spores as a biological weapon was demonstrated by the accidental release of
Bacillus anthracis
from a military microbiology laboratory in the former Soviet Union. Seventy-seven cases of human anthrax, including 66 deaths, were attributed to the accident. Some anthrax infections occurred as far as 4 kilometers from the laboratory (See e.g., Meselson et al., Science 266:1202 [1994]). Genetic analysis of infected victims revealed the presence of either multiple strains or a genetically altered
B. anthracis
(See e.g., Jackson et al., Proc. Nat. Acad. of Sci. U.S.A. 95:1224 [1998]).
Additionally, other members of the Bacillus genus are also reported to be etiological agents for many human diseases.
Bacillus cereus
is a common pathogen. It is involved in food borne diseases due to the ability of the spores to survive cooking procedures. It is also associated with local sepsis and wound and systemic infection (See e.g., Drobniewski, Clin. Micro. Rev. 6:324 [1993]). Many bacteria readily develop resistance to antibiotics. An organism infected with an antibiotic-resistant strain of bacteria faces serious and potentially life-threatening consequences.
Examples of bacteria that develop resistance include Staphylococcus that often cause fatal infections, Pneumococci that cause pneumonia and meningitis; Salmonella and
E. coli
that cause diarrhea; and Enterococci that cause blood-stream, surgical wound and urinary tract infections (See e.g., Berkelman et. al., J. Infcet. Dis. 170(2):272 [1994]).
Although an invaluable advance, antibiotic and antimicrobial therapy suffers from several problems, particularly when strains of various bacteria appear that are resistant to antibiotics. In addition, disinfectants/biocides (e.g., sodium hypochlorite, formaldehyde and phenols) that are highly effective against Bacillus spores, are not well suited for decontamination of the environment, equipment, or casualties. This is due to toxicity that leads to tissue necrosis and severe pulmonary injury following inhalation of volatile fumes. The corrosive nature of these compounds also renders them unsuitable for decontamination of sensitive equipment (See e.g., Alasri et al., Can. J. Micro. 39:52 [1993]; Beauchamp et al., Crit. Rev. Tox. 22:143 [1992]; Hess et al., Amer. J. dent. 4:51 [1991]; Lineaweaver et al., Arch. Surg. 120:267 [1985]; Morgan, Tox. Path. 25:291 [1997]; and Russell, Clin. Micro. 3;99 [1990]).
Influenza A virus is a common respirator pathogen that is widely used as a model system to test anti-viral agents in vitro (See e.g., Karaivanova and Spiro, Biochem. J. 329:511 [1998]; Mammen et al., J. Med. Chem. 38:4179 [1995]; and Huang et al., FEBS Letters 291:199 [1991]), and in vivo (See e.g., Waghorn and Goa, Drugs 55:721 [1998]; Mendel et al., Antimicrob. Agents Chemother. 42:640 [1998]; and Smith et al., J. med. Chem. 41:787 [1998]). The envelope glycoproteins, hemagglutinin (HA) and neuraminidase (NA), which determine the antigenic specificity of viral subtypes, are able to readily mutate, allowing the virus to evade neutralizing antibodies. Current anti-viral compounds and neuraminidase inhibitors are minimally effective and viral resistance is common.
Clearly, antipathogenic compositions and methods that decrease the infectivity, morbidity, and mortality associated with pathogenic exposure are needed. Such compositions and methods should preferably not have the undesirable properties of promoting microbial resistance, or of being toxic to the recipient.
SUMMARY OF THE INVENTION
The present invention relates to compositions and methods for decreasing the infectivity, morbidity, and rate of mortality associated with a variety of pathogens. The present invention also relates to methods and compositions for decontaminating areas, samples, solutions, and foodstuffs colonized or otherwise infected by pathogens and microorganisms. Certain embodiments of the present compositions are nontoxic and may be safely ingested by humans and other animals. Additionally, certain embodiments of the present invention are chemically stable and non-staining.
In some embodiments, the present invention provides compositions and methods suitable for treating animals, including humans, exposed to pathogens or the threat of pathogens. In some embodiments, the animal is contacted with effective amounts of the compositions prior to exposure to pathogenic organisms. In other embodiments, the animal is contacted with effective amounts of the compositions after exposure to pathogenic organisms. Thus, the present invention contemplates both the prevention and treatment of microbiological infections.
In other embodiments, the present invention provides compositions and methods suitable for decontaminating solutions and surfaces, including organic and inorganic samples that are exposed to pathogens or suspected of containing pathogens. In still other embodiments of the present invention, the compositions are used as additives to prevent the growth of harmful or undesired microorganisms in biological and environmental samples.
In preferred embodiments, decreased pathogenic organism infectivity, morbidity, and mortality is accomplished by contacting the pathogenic organism with an oil-in-water nanoemulsion comprising an oil phase, an aqueous phase, and at least one other component. In some preferred embodiments, the emulsion further comprises a solvent. In some preferred embodiments, the solvent comprises an organic phosphate so
Baker, Jr. James R.
Hamouda Tarek
Myc Andrzej
Shih Amy
Fubara Blessing
Medlen & Carroll, LLP.
Page Thurman K.
Regents of the University of Michigan
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