NZ616550B2 - Treatment of microbial infections using reactive oxygen species - Google Patents
Treatment of microbial infections using reactive oxygen species Download PDFInfo
- Publication number
- NZ616550B2 NZ616550B2 NZ616550A NZ61655012A NZ616550B2 NZ 616550 B2 NZ616550 B2 NZ 616550B2 NZ 616550 A NZ616550 A NZ 616550A NZ 61655012 A NZ61655012 A NZ 61655012A NZ 616550 B2 NZ616550 B2 NZ 616550B2
- Authority
- NZ
- New Zealand
- Prior art keywords
- composition
- hydrogen peroxide
- reactive oxygen
- oxidase
- oxygen species
- Prior art date
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Abstract
Provided are microbiocidal compositions comprising reactive oxygen species (ROS) or comprising components that produce ROS. The components that produce ROS may be an enzyme such as lactoperoxidase, chloroperoxidase, bromoperoxidase or iodooxidase and its corresponding substrate. For example a composition may comprise potassium iodide, lactoperoxidase and glucose oxidase. The compositions may be used in in the treatment of microbial infections or in the control of microbial contamination. The compositions may be particularly useful in the treatment of mastitis. osition may comprise potassium iodide, lactoperoxidase and glucose oxidase. The compositions may be used in in the treatment of microbial infections or in the control of microbial contamination. The compositions may be particularly useful in the treatment of mastitis.
Description
Title
Treatment of microbial infections using reactive oxygen species
Field of the Invention
The present application relates generally to an anti-microbial composition for use in the
treatment of microbial infections. In particular, the composition may be used to treat
bacterial infections, or for control of bacterial contamination, which avoids the use of
antibiotics. Such infections include mastitis, tuberculosis, cystic fibrosis and other lung
infections, and the contamination that may result from biofilm formation on surfaces
such as on medical devices. However, the composition is also suitable for the treatment
of viral, yeast or fungal infections or for the control of contamination by such
organisms.
Background to the Invention
Mastitis is a persistent inflammatory condition of the udder of cows and other milk-
producing animals. It is one of the most common diseases in dairy cows in the United
States and is also the most costly to the dairy industry. Mastitis occurs when white
blood cells are released into the mammary gland, usually in response to invasion of
bacteria in the teat canal. Milk from cows with mastitis has a higher somatic cell count,
and the higher the somatic cell count, the lower the quality of the milk.
Normal treatment for mastitis is with antibiotics, but milk from antibiotic treated cows
is not marketable, until the drug has left the cows’ system. The antibiotics used may be
systemic and injected into the body, or they may be forced into the teat through the teat
canal by intra-mammary infusion. Mastitis can be clinical, whereby visible signs of
infection are noted or sub-clinical, where the presence of infection is noted only by an
increase in somatic count in the resulting milk. In some clinical situations, cows are
often left untreated, though revenue is lost to the dairy farmer through a reduction in the
amount of money paid for the milk, which occur where there is an elevated somatic cell
count in the milk.
There are a number of other uses of the anti-microbial composition of the present
invention. These include infections of the mammalian lung. Cystic fibrosis and
tuberculosis are two diseases that are, at present, extremely difficult to treat.
Tuberculosis symptoms are caused by infection in the lungs and require long-term
antibiotic treatment. Cystic fibrosis (CF) is a condition wherein the sufferer cannot
regulate the transfer of chloride ions across their membranes, particularly in the lungs.
The condition invariably results in numerous, chronic, lung infections. Antibiotic
treatment for either condition can lead to serious drug resistance, minimising their
effectivness. At present, antibiotics are delivered through the blood stream intra-
venously, or by oral suspension/tablets, or by inhalation. Drug delivery is a big problem
for CF sufferers as the antibiotic cannot efficiently transverse the lung membrane to
where it is required. This leads to problems wherein resistance to the drug, through the
introduction of sub-inhibitory concentrations, may become a serious issue. This makes
any further treatment with the drug obsolete.
Burns patients, or patients with open wounds, are extremely susceptible to bacterial
infections, notably those due to Staphlycoccal species or Pseudomonad species of
bacteria. Treatment of such infections will invariably be by a regimen of antibiotics,
either oral or intra-venously. These may be given prophalactically, or when infection is
apparent. Such use of antibiotics will often lead to resistance to the drug and an
ineffective treatment outcome. The researchers envision a new method of treating burns
patients with the present technology.
In addition, large numbers of antibiotic treatments each year are due to the result of
medical devices that have become infected whilst in use by a patient. A large number of
organisms are responsible for such infections, including both Gram-positive and Gram-
negative bacteria. Infections, on such items as urinary or intra-venous catheters, are
often the result of the non-sterile installation of such devices. Over the course of a
number of days, any bacterial cells present on the surface of the device will proliferate,
leading to the production of biofilms. Such biofilms are extemely difficult to treat with
anitbiotics, due to the poor transfer of the drug across to the inner cells of the biofilm
mass, leading often to even greater levels of tolerance of the biofilms to the antibiotic.
Infection of the medical device will often require its removal and replacement, to the
discomfort of the patient. Although the infection will often be noted a number of days
after installation of the medical device, it will be typically incurred as the result of
bacteria being present very early in the installation.
It is generally known that a bacteriostatic effect is caused by the reaction between
hydrogen peroxide and thiocyanate, catalysed by lactoperoxidase – a process referred to
as the Lactoperoxidase (LP) system. In certain instances, the source of peroxide is a
reaction between glucose and glucose oxidase, which results in the production of
gluconic acid and peroxide. This process is used during the transport of milk.
Antibacterial treatments for the control of infections have been proposed, based on the
LP system. For example, PCT Application WO2008/04128 discloses a preparation with
an antimicrobial and immuno-stimulatory effect, which comprises an oxidoreductase
enzyme, an appropriate substrate for that enzyme to produce hydrogen peroxide, and
endogenous hydrogen peroxide preparations. The preparation produces 2-stage
hydrogen peroxide release; the endogenous form of peroxide ensuring that there is
instantly available hydrogen peroxide and further hydrogen peroxide is produced by the
oxidoreductase enzyme.
US Patent No. 6312687 describes a stabilised aqueous enzyme concentration
comprising lactoperoxidase, glucose oxidase, an alkaline metal halide salt and a
buffering agent, for use as an antimicrobial composition. US Patent No. 5607681
describes antimicrobial compositions, which comprise iodide anions and thiocyanate
anions together with D-glucose and either glucose oxidase or glucose oxidase together
with and at least one antioxidant. The composition may additionally comprise
lactoperoxidase.
The proposed basis for the bacteriostatic effect of the LP system in milk is based on
thiocyanate and a source of hydrogen peroxide. The thiocyanate ion is oxidised in the
presence of hydrogen peroxide by lactoperoxidase, to produce hypothiocyanous acid. In
certain embodiments, the peroxide ion is produced from glucose by the action of
glucose oxidase rather than by using a solution of hydrogen peroxide or its release from
a suitable perhydrate (such as sodium percarbonate). The present application suggests
the use of further substrates to help bring about the reaction to produce hydrogen
peroxide by means of supplemented enzymatic catalysis. Hydrogen peroxide is toxic to
both bacterial and mammalian cells, while hypothiocyanous acid reacts with free
sulphydryl groups in bacterial proteins, inactivating several metabolic enzymes.
The consensus in the literature teaches that the LP system has mainly a bacteriostatic
effect on catalase positive gram positive bacteria and also that there is a pH dependent
bactericidal effect on some gram negative bacteria (Wofson and Sumner, 1993,
“Antibacterial activity of the lactoperoxidase system: a review” Journal of Food
Protection 1993, 56(10):887-892; Kussendrager and van Hooijdonk, 2000
“Lactoperoxidase: physico-chemical properties, occurrence, mechanism of action and
applications”, British Journal of Nutrition, 84, Suppl. 1, S19-S25; Seifu et al., 2005
“Significance of the lactoperoxidase system in the dairy industry and its potential
applications: a review”, Trends in Food Science & Technology 16, 137–154). The
precise mechanisms underpinning the antimicrobial properties of the LP system remain
unresolved. The experimental protocols reported in the literature vary widely and many
authors report bacterial inhibition, but regrowth after a particular period of time, and
thus a biostatic rather than a biocidal effect (e.g. Ishido et al. “Continuous supply of
OSCN- ions by lactoperoxidase system developed from lactose as the primary substrate
and its anti-bacterial activities”, Milchwissenschaft, 66 1, 2011) Documents have also
claimed bactericidal activity using the LP system, but have reported significant numbers
of culturable cells remaining after testing, even at elevated LP concentrations (e.g.
Garcia-Garibay et al., 1995, Antimicrobial effect of the lactoperoxidase system in milk
activated by immobilised enzymes” Food Biotechnology, (3), 157-166). As discussed
elsewhere in this application, hydrogen peroxide, either provided in the medium or
produced during the LP reaction, is toxic to bacterial cells and, unless specific controls
are in place, it may contribute to reported antimicrobial activity. The prior art has also
disclosed a range of reportedly synergistic compounds, which are claimed to either
enhance, or indeed enable, the effectiveness of the LP system. In addition, US patent
application number 2011/0008361 A1 suggests that the antimicrobial effect of the
described extracted cationic fractions, including LP, are a combination of immune
stimulation, which helps to clear infection and direct antimicrobial activity.
The lack of systematic information on the precise factors influencing the antimicrobial
effects of the LP system is a barrier to commercial applications – as is the potential for
hydrogen peroxide toxicity in sensitive settings, such as the mammalian lung.
While the LP system has been widely described, it is thought by those skilled in the art
that this is an ineffective system to be utilised of the treatment of bacterial infection
(Rainard & Riollet 2006, “Innate immunity of the bovine mammary gland”, Veterinary
Research 37, 369-400; Sakai et al., 2008, “Generation of hydrogen peroxide by a low
molecular weight compound in whey of Holstein dairy cows”, Journal of dairy
Research, 75, 257-261; Sakai et al., 2008, “Production of hydrogen peroxide by a small
molecular mass compound in milk from Holstein cows with high and low milk somatic
cell count”, Journal of Dairy Research, 75, 335-339). A lack of robust and effective
bactericidal capacity of the LP and similar systems is a significant barrier to such
applications. Current commercial applications based on the LP system include
mouthwash, toothpaste, food preservation and disinfectants, which are mainly based on
inhibition of microbial growth, rather than the killing of cells and the total elimination
of bacterial populations from various settings. For example, the patents filed regarding
the lactoperoxidase system (Number US 4726945 and US 5607681) are used for topical
treatments and are designed mainly as a way to reduce the growth of bacteria present
(either in the solutions, for example as an ionic emulsion, or acne or athlete’s foot
treatments, or indeed as a prophylactic in feedstuffs for animals).
The broad spectrum and numerous potential targets of the antimicrobial species of the
invention are unlikely to induce the proliferation of resistance genes. Drug reactions
would not be a problem either, being that components of the therapeutic composition
may be produced naturally in the mammalian body (for example, via intermediates such
as thiocyanate, lactoperoxidase, glucose). Reaction to drugs is a current problem, with
% of patients reacting to B-lactam drugs (“Rapid de-sensitization for non-immediate
reactions in patients with cystic fibrosis”, Whitaker et al., 2011, Journal of Cystic
Fibrosis, 10(4):282-5).
Ishido et al. (Milchwissenschaft, Vol. 66, No. 1, 2011) describe a lactoperoxidase
system comprising lactoperoxidase, glucose oxidase and b-galactosidase, lactose and
potassium thiocyanate as an agent, which is said to be antibacterial. In all cases lactose
was present in the composition. The document, however, describes bacterial growth
suppression only and no analysis was conducted for more than 48 hours. The document
also states that there were no inhibitory effects against the gram-negative bacteria E.
coli and Klebsiella pneumoniae and the gram-positive species, S. xylosus, E. faecalis,
E. faecium and E. raffinosus. The results in the document are labelled as being ‘growth
suppression’ times, the time tested being no more than 12 hours. Overall this paper thus
describes a bacteriostatic effect and not a bactericidal effect.
Garcia – Garibay et al. (Food Biotechnology, 9 (3), 157-166 (1995) describes the use of
b-galactosidase and glucose oxidase to produce hydrogen peroxide in raw milk, to
reduce undesirable micro organisms in the milk. Again testing was conducted for 24
hours only, and thus the data presented showing a reduction in microorganism numbers
indicates only a bacteriostatic effect.
Sandholm et al. (J. Vet. Med. B 35, 346-352 (1988) describes glucose oxidase for use as
an antibacterial agent in teats or intramammary antiseptics.
US Patent No. 5607681 describes antimicrobial compositions comprising iodide and
thiocyanate ions, an oxidoreductase enzyme and its corresponding oxidisable substrate,
together with a lactoperoxidase. This document only describes activity against bacteria
for up to 72 hours and describes no therapeutic application of the system.
The present invention represents a paradigm shift from the prior art. It describes a
broad-spectrum, truly microbiocidal, therapy for treatment of infections and/or at least
provides the public with a useful choice.
The present inventors have shown that the reactive oxygen species (ROS)
produced by the LP system, or by other means are, in fact, bactericidal to a wide range
of pathogenic gram-positive and gram-negative bacteria, in a variety of media and
across a wide range of pH and temperature ranges, based on concentration dependent
dose response (see detailed description of the invention). We have also shown that the
ROS can completely kill bacteria and fungi growing in biofilms on various surfaces.
In a detailed series of controlled trials, it has been shown that this bactericidal
activity can be exclusively due to the action of the ROS and that the ROS are effective
in this regard with no residual hydrogen peroxide present and in the absence of any
other synergistic agents such as lactoferrin, quarternary ammonium compounds, fatty
acids, etc (see detailed description of the invention).
The concentrations of ROS required to completely kill particular populations of
bacteria in particular settings can be calculated and used to generate precise dose
response/minimum inhibitory concentration information, in a manner similar to that
used for antibiotics and other antimicrobial therapeutic agents (see detailed description
of the invention).
Administration of the ROS species at these dose levels can be used to
completely kill a wide variety of gram negative and gram positive bacterial pathogens -
including those isolated from the bovine udder and mammalian lung, those growing as
biofilms attached to various surfaces; those isolated from patients; and those that are
resistant to a wide range of antibiotics (see detailed description of the invention).
It has also been shown that the required bactericidal and therapeutic
concentrations of the ROS species can be generated at the site of treatment, for example
using the LP system in the bovine udder, or that the ROS species can be prepared
externally to the site of infection and delivered in the absence of any other active
ingredient to allow successful treatment and elimination of bacterial infections.
The present technology thus provides a unique way to limit microbial infection and
biofilm growth on the surface of, for example, medical devices and/or at least provides
the public with a useful choice.
Object of the Invention
An object of the invention is to provide an improved composition for the treatment of
microbial infections and/or to provide a composition which is capable of killing, as
opposed to slowing the growth of, bacteria, viruses, fungi and yeasts, and/or to provide
a composition that can kill antibiotic resistant organisms and/or to at least provide the
public with a useful choice.
Mastitis
A further objective is to provide a composition for the treatment of both clinical and
sub-clinical mastitis, without the use of antibiotics and/or to provide a treatment for
mastitis, which does not require that the milk be discarded during treatment, and/or to
provide a clinical solution to mastitis, which would be easy to administer and/or to at
least provide the public with a useful choice. Such is the reaction in the prior art
discussed above, that if all the components are mixed together, the reaction would occur
instantly, thus leaving a short shelf-life. In the prior art it is necessary to have two
aliquots that are mixed prior to administering the product, thus starting the reaction.
Another drawback is the fact that the glucose concentration is always a limiting factor.
To have enough glucose in a clinical situation, a concentrated source needed to be
added. This leads to solubility problems. The addition of extraneous glucose may also
lead to issues in the downstream processing of the milk and may also lead to consumer
problems regarding the taste and sweetness of the milk for consumption.
In an attempt to circumvent the need for glucose administration, the characteristics of
milk itself were examined by the present inventors. Milk is a source of lactose. Beta-
galactosidase is an enzyme that cleaves and converts the disaccharide sugar into its
constituents, glucose and galactose. The use of the enzyme would therefore rely on a
key constituent of milk itself to exploit the ability of the LP system to generate the
reactive oxygen species at the site of infection. Using this enzyme makes it easier to
administer the cocktail as the system will not react until glucose is present (and glucose
would not be produced until Beta-galactosidase was in contact with the milk). This is
much more useful than having to administer glucose or indeed a suitable
monosaccharide or disaccharide sugar prior to usage, negating the use of a concentrated
and problematic sugar solution.
Lung Infection
Another object of the invention is the treatment of a number of other bacterial infections
and/or to at least provide the public with a useful choice. Drug delivery and resistance to
antibiotics is a major problem in the treatment of both cystic fibrosis (CF) and
tuberculosis (TB). Antibiotic resistance often occurs as a result of only sub-inhibitory
concentrations of the drug reaching the target site, i.e. lungs. Chronic infections will
often result from this situation, seriously impairing the health of the patient. The ideal
delivery of the components of the lung would be as a nebulised spray, directly into the
lungs. This would have the advantage that the components would interact directly with
the organism at the correct site, and at the correct concentration. If it were administered
orally or through the blood stream, greater concentrations are required to give the same
effect. When using antibiotics, this will lead to large concentrations of the drug being
used, increasing the chances of resistance or a reaction to the drug. Because the
components of the present system are present naturally in the mammalian system (or
used in feedstuffs regularaly), reaction to them is highly unlikely, an advantage to
treatment with antibiotics where drug reactions are common. In patients with CF, the
natural level of thiocyanate is reduced in the lung due to the failure of regulation of
water in the membrane, reducing the effectiveness of the naturally found
lactoperoxidase system in the organ. Extraneous addition of the reactive oxygen species
that could act propylactically on people diagnosed with CF or be used to treat patients
that have already developed lung infections. Such a nebulised spray has the potential to
be used in hospitals in minimising infection during operations where body cavities are
open to the environment and at risk, especially those caused by antibiotic resistant
strains of bacteria.
Burns/Skin/Mouth
Other infections that are suitable targets for the technology are those incurred as a result
of burns or an open wound. The advantage of using the described system over present
antibiotic treatment regimens would be the similiar to those described above in treating
CF or TB as regards drug reaction, safety, efficacy, and resistance. The inventors have
shown that the reactive oxygen species are effective in the treatment of biofilm based
cells (those attached to a solid stratum). This would be the bacterial phenotype most
noted in the lungs of TB/CF patients, and in open wounds or burns. This phenotype
confers a generalised tolerance to the bacteria against a wide range of antibiotics
(“Antibiotic resistance of bacteria in biofilms”, Stewart & Costerton, 2001, The Lancet,
358, 135-138).
A form of the system could also serve as a general antibacterial solution, having
numerous purposes. For example, a mouthwash containing the antibacterial system
could help prevent the formation of biofilms within the mouth. Likewise, an
antibacterial nasal rinse could be used to help alleviate sinus problems, such as sinusitis
or allergic rhinitis. Currently, steroids and saline nasal washes are used. An antibacterial
saline wash would, however, also help to combat bacterial colonisation within the nasal
cavity.
Medical Devices
The use of reactive oxygen species, such as those generated by a haloperoxidase based
system, would also hold a number of advantages in the treatment and prevention of
bacterial infections on an implanted medical device. Infections (in the form of a
recalcitrant biofilm) are extremely common in various devices such as catheters. A
device impregnated or coated with the various enzymes would be able to react with
substrates naturally present in the blood.
General antibacterial wash
Another object of the invention is to provide a composition for use as a generalised,
safe, antibacterial wash for a multi-purpose product and/or to at least provide the public
with a useful choice. The proposed system could be effective at washing/removal of
bacteria from surfaces, pipes, beer lines, cooking equipment etc.
Antifungal agent
Infections can occur as a result of yeast or fungal growth as well as bacteria. As such, a
therapeutic regime capable of exerting antimicrobial activity (as opposed to antibacterial
activity, as is the case with antibiotics) would be of great benefit. To this end, the
antimicrobial activity of the reactive oxygen species (hypoiodate) was tested against two
fungal strains of note (Example 18 below). The Candida strains of fungus are typically
described as opportunistic pathogens. They can cause a variety of skin conditions, such
as vulvovaginitis and urinary tract infections. They are prevalent in HIV patients, and
other immunocompromised patients. Saccharomyces cerevesiae (commonly known as
yeast, or bakers’ yeast) is an important organism in food production. It also poses great
problems for the drinks industry, and is a typical organism found on beer lines, and is
the cause of beverage spoilage. As such, the antimicrobial reactive oxygen species
useful in the invention, would be a good therapeutic candidate to treat or control fungal
infections, or to clear surfaces, eradicating fungal contamination.
The invention also finds use as an anti-viral agent.
Summary of the Invention
In one aspect, the present invention relates to a microbiocidal composition comprising a
reactive oxygen species selected from the group consisting of hypothiocyanate
- - -
(hypothiocyanite, SCNO ), hypoiodate (IO ) and hypochlorite (CLO ), the composition
being capable of delivering the reactive oxygen species to a level of at least 0.4
millimoles per litre, over a 24 hour period.
In another aspect the present invention relates to the use of a reactive oxygen species
selected from the group consisting of hypothiocyanate (hypothiocyanite, SCNO ),
hypoiodate (IO ) and hypochlorite (CLO ), in the manufacture of a medicament for the
treatment of microbial infections, wherein the medicament is capable of delivering the
reactive oxygen species to a level of at least 0.4 millimoles per litre, over a 24 hour
period.
Certain statements that appear below are broader than what appears in the statements of
the invention above. These statements are provided in the interests of providing the
reader with a better understanding of the invention and its practice. The reader is
directed to the accompanying claim set which defines the scope of the invention.
Also described herein is a microbiocidal composition comprising a reactive oxygen
species or components capable of producing a reactive species, the composition being
capable of delivering the reactive oxygen species to a level of at least 0.4 millimoles per
litre over a 24 hour period. The composition may be capable of delivering the reactive
oxygen species to a level of at least 0.5 millimoles per litre, or at least 0.6 millimoles
per litre or at least 0.7 millimoles per litre or at least 0.8 millimoles per litre or at least
0.9 millimoles per litre or at least 1.0 millimoles per litre or at least 2.0 millimoles per
litre over a 24 hour period.
The reactive oxygen species may be produced by the reaction of a peroxidase, a
substrate for the peroxidase and hydrogen peroxide.
By microbicidal we mean a composition which is capable of killing microbes such as
bacteria, viruses, fungi and yeasts, as opposed to simply retarding their growth. The
microbicidal composition is capable of killing at least 90%, preferably at least 95%,
more preferably at least 99%, more preferably at least 99.99%, of the microbes present
in an environment to which it is applied.
The compostion is also capable of killing antiobiotic resistant organisms.
The reactive oxygen species of the composition may comprise hypothiocyanate (also
known as hypothiocyanite, SCNO ).
The reactive oxygen species of the composition may also comprise hypoiodate (IO also
known as hypoiodite) .
The reactive oxygen species of the composition may also comprise hypochlorite (ClO ).
In a further aspect the invention provides a microbicidal composition additionally
comprising a peroxidase enzyme and an oxidoreductase. This composition is
particularly suitable for the treatment of infections in cystic fibrosis or tuberculosis
patients, burns victims or patients with inserted medical devices.
In a further aspect the invention provides a microbicidal composition additionally
comprising a peroxidase enzyme, an oxidoreductase, and a glycoside hydrolase. This
composition is particularly suitable for the treatment of mastitis infections.
The composition may also comprise a substrate for the peroxidase.
The peroxidase may be a haloperoxidase. The haloperoxidase enzyme may be a
lactoperoxidase, a chloroperoxidase, a bromoperoxidase or an iodoperoxidase. Suitable
chloroperoxidases include myeloperoxidase and eosinophil peroxidase. Suitable
bromoperoxidases include ovoperoxidase, vanadium bromoperoxidase and Murex snail
bromoperoxidase. Suitable iodoperoxidases include horseradish peroxidaseand thyroid
peroxidase.
If a lactoperoxidase enzyme is used, the composition may further comprise potassium or
sodium iodide or potassium or sodium thiocyanate as the substrate. Chloroperoxidase
reacts with chloride ions, readily available in milk, blood or the like, so the addition of
chloride ions may not always be necessary. If bromooxidase or iodooxidase are used,
the substrate may be a source of bromide or iodide ions, respectively.
The haloperoxidase reacts with available hydrogen peroxide, and a suitable substrate
(iodide/bromide/chloride or thiocyanate) to produce an antibacterial reactive species.
The glycoside hydrolase may be Beta-galactosidase, which converts freely available
lactose in the milk into glucose and galactose.
The oxidoreductase may be glucose oxidase, which reacts with the resulting glucose to
produce hydrogen peroxide. Similarly, galactose oxidase could also be used, reacting
with galactose to produce hydrogen peroxide.
Preferably, the composition may further comprise a disaccharide sugar. The
disaccharide could be subsequently hydrolysed by its corresponding glycoside
hydrolase, for example sucrose and sucrase, allowing the release of monosaccharide
sugars, which in turn could act as a source of additional hydrogen peroxide by the use of
a corresponding oxireductase enzyme.
Additionally, oligosaccharides or polysaccharides containing more than two sugar
molecules, and that are cleaved to produce a source of hydrogen peroxide may be
added.
In some embodiments, the composition comprises two enzymes to derive a source of
hydrogen peroxide; a glycoside hydrolase to break down disaccharide sugars into
constituent monosaccharides, and a further oxireductase enzyme that reacts with the
monosaccharide sugars to release hydrogen peroxide.
The composition may comprise additional sources of hydrogen peroxide. One additional
source of hydrogen peroxide is the exogenous addition of a solution of hydrogen
peroxide or its release by a suitable perhydrate, such as sodium percarbonate.
Alternatively, or in addition, a number of enzymes can be used to produce hydrogen
peroxide. Xanthine oxidoreductase/oxidase reacts with either hypoxanthine or xanthine
(both present in milk) to produce hydrogen peroxide. Therefore, xanthine
oxidoreductase/oxidase and/or xanthine could be added to the composition producing
hydrogen peroxide. Similarly, sugar alcohols can be reacted with their appropriate
oxidase enzymes to produce a source of hydrogen peroxide. For example, glycerol
oxidase reacts with glycerol to produce a source of hydrogen peroxide and, therefore,
glycerol oxidase/glycerol could be added to the composition. Another example would
be mannitol reacting with mannitol oxidase. Further to this, citric acid is known to
release hydrogen peroxide, and therefore could also be added to the composition.
Similarly, L-amino acid oxidase is an enzyme that reacts with free amino acids (also
present in milk) to produce hydrogen peroxide. Likewise, its addition (with or without
L-amino acid supplementation) could provide a source of hydrogen peroxide.
The aspect of the invention, which provides a bactericidal composition additionally
comprising a peroxidase enzyme, an oxidoreductase, and a glycoside hydrolase
(specifcally Beta-galactosidase), has proven to have extremely effective antibacterial
qualities in milk. In particular, the system is effective at completely killing both Gram-
positive and Gram-negative organisms at high levels of bioburden (i.e. eliminating 10
cells/ml). Based on the prior art, this is a surprising finding as the WHO have stated
that the lactoperoxidase system ‘exerts primarily a bacteriostatic effect in raw milk’ and
was suitable only for limiting bacterial growth on a short term basis by such a means
during the transport of raw milk, in the absence of refrigeration (Report of an
FAO/WHO Technical Meeting FAO Headquarters, Rome, Italy, 28 November-2
December 2005). Other researchers concluded that any bacteriocidal activity in the
system was due to the hydrogen peroxide component and that the lactoperoxidase
system was bacteriostatic (Thomas et al., 1994, “Antibacterial activity of hydrogen
peroxide and the lactoperoxidase-hydrogen peroxide-thiocyanate system against oral
streptococci”, Infection and Immunity, Vol. 62, No.2, p 529-535).
The Beta-galactosidase reacts with lactose present in milk, to produce glucose and
galactose. The resulting glucose reacts with the glucose oxidase to produce hydrogen
peroxide. The hydrogen peroxide reacts with potassium iodide/thiocyanate to produce
an antibacterial effect. The antibacterial effect is aided by lactoperoxidase which
catalyses the peroxidation of iodides and other suitable substrates.
Relying on the inherent lactose in milk negates the use of a highly concentrated glucose
solution, which was a limiting factor in an in vitro situation, making it possible to use
the product in the field.
In another aspect of the invention, there is provided a composition for the treatment of
infections or contamination, comprising Xanthine oxidoreductase/oxidase. The
composition may further comprise either hypoxanthine or xanthine or both. The
composition may also comprise an oxidoreductase or a glycoside hydrolase or
disaccharides.
In yet another aspect of the invention there is provided a composition for the treatment
of infections or contamination comprising L-amino acid oxidase. The composition may
further comprise free amino acids. The composition may also comprise an
oxidoreductase or a glycoside hydrolase or disaccharides.
One potential of the composition of the invention lies in the treatment of bovine (or
other mammal) mastitis. It could be used to treat both clinical and sub-clinical mastitis
and would provide the advantage of not requiring the removal of resulting treated milk
from the bulk pool. The enzymes present in the proposed solutions are safe and the
potential substrates, including potassium iodide or thiocyanate are safe at the
concentrations used. The composition is unlikely to induce resistance to antibiotics,
which is an additional advantage. In addition, the report of an FAO/WHO technical
meeting in Rome, Italy on 22 November – 2 December 2005 indicated that a
lactoperoxidase system does not introduce substances into milk that are not normal
metabolites.
The use of enzymes to produce the biocidal reactive oxygen species useful in the
invention, provides the means to continuously produce the composition over periods of
time, which is advantageous when compared to antibiotic treatments, where new
molecules must be externally added to replenish the antimicrobial activity.
One product suitable for the treatment of mastitis is an intramammary infusion delivery
device (optionally presented as a dual barrelled syringe) loaded with 7-10 ml solution
(increasing its viscosity by gelatine supplementation) containing 2 mg glucose oxidase
(~200 units/mg), 0.5 ml Beta-galactosidase ( ≥2,600 units/ml), 4 mg lactoperoxidase
( ≥80 units/mg), and 100-150 mg potassium iodide, to be used to generate the
bactericidal reactive oxygen species to treat mastitis.
Other preparations could hold the enzymes as a lyophilized powder to be mixed with a
solution of substrates prior to use, thus aiding shelf-life of the reaction where
refrigeration is not a possibility. Other similar products may be produced based on the
weight of animal (sheep, etc.), milk production, and the bioburden level in the infected
udder. Further to this, various combinations of components could also be prepared,
notably using bromide/thiocyanate instead of iodide, using a different oxidoreductase
enzyme, or the supplementation of different possible sources of hydrogen peroxide, or
to use a xanthine oxidoreductase (a complex enzyme which comprises xanthine oxidase)
or an L-amino acid oxidase (a member of the oxidoreductase enzyme family) approach.
An alternative product involves substitution of lactoperoxidase with any other enzyme
that reacts with hydrogen peroxide and suitable substrate to produce the antimicrobial
species. Of these, chloroperoxidase is suitable with a loading of 7-10 ml solution
(increasing its viscosity by gelatine supplementation) containing 2 mg glucose oxidase
(~200 units/mg), 0.5 ml Beta-galactosidase ( ≥2,600 units/ml), and 50 μl
chloroperoxidase ( ≥11,100 units/ml).
A lactoperoxidase system has been described before (Number US 4726948 and US
5607681) in a number of formulations. The World Health Organisation (Report of an
FAO/WHO Technical Meeting FAO Headquarters, Rome, Italy, 28 November-2
December 2005) has recommended its use as a method of increasing the longevity of
milk in the absence of refrigeration in 3 world countries. The WHO recommended a
system using sodium percarbonate as the source of hydrogen peroxide. The aspect of the
invention presented here differs from the known LP system in that it uses an alternative
source of hydrogen peroxide, provided by the sequential cleavage of lactose present in
the milk. Further to this, an alternative is to use chloroperoxidase enzyme in place of
lactoperoxidase, wherein, it reacts with salt already present in milk, negating the need
for halide supplementation to the udder. Either form of this aspect of the invention
(lactoperoxidase/chloroperoxidase) offers the advantage over existing preparations in
that they would not start reacting until administered to the udder. Each would have a
lengthy shelf-life at 4ºC. The WHO discussed a number of problems in their described
incarnation of the LP system that would not occur in the aspect of the invention
described herein. The system proposed by the WHO delivered thiocyanate and
percarbonate powders in sachet form to milk. Powdered thiocyanate is hygroscopic and
may degrade overtime, and sodium percarbonate as a source of hydrogen peroxide may
lead to oxygen production, which could cause rupture and breakage of the sachet.
The invention described here improves on the lactoperoxidase system described by
Kussendrager and van Hooijdonk, 2000 (Lactoperoxisdase: physico-chemical
properties, occurrence, mechanism of action and applications. British Journal of
Nutrition, 81, 519-525). When treating mastitis, it uses a key ingredient of milk itself,
lactose, to drive the reaction to produce the specific required concentrations of the
bactericidal reactive oxygen species to eliminate the infection. The supplementation of
two enzymes (Beta-galactosidase and glucose oxidase) as opposed to sodium
percarbonate, allows a slow, prolonged, release of hydrogen peroxide necessary to allow
continuous production of the bactericidal agents at a controlled level. Because of the
availability of lactose in the proposed environment, hydrogen peroxide would not be a
limiting factor in the reaction. A relatively small amount of Beta-galactosidase has
proved just as effective as larger volumes of glucose supplementation.
The invention improves on the lactoperoxidase system found naturally in mammals as
it regulates the levels of hydrogen peroxide present (and indeed any other components).
During a typical infection, the level of hydrogen peroxide is quenched by bacterial
catalase activity, thus reducing the effectiveness of the system. The low availability of
hydrogen peroxide has lead a number of researchers to believe the antimicrobial nature
of the lactoperoxidase system was ‘questionable’ (Rainard & Riollet 2006, “Innate
immunity of the bovine mammary gland”, Veterinary Research 37, 369-400; Sakai et
al., 2008, “Generation of hydrogen peroxide by a low molecular weight compound in
whey of Holstein dairy cows”, Journal of dairy Research, Journal of Dairy Research, 75,
257-261; Sakai et al., 2008, “Production of hydrogen peroxide by a small molecular
mass compound in milk from Holstein cows with high and low milk somatic cell
count”, Journal of Dairy Research, 75, 335-339).
The embodiment of the invention which uses xanthine oxidoreductase/oxidase or L-
amino acid oxidase as sources of hydrogen peroxide would improve the technology as
neither require sugar supplementation, use constituents of the milk itself, and do not
alter the taste of the milk as regards its sweetness.
The patents filed regarding the lactoperoxidase system (US 4726945 and US 5607681)
are used for topical treatments and are designed mainly as a way to reduce the growth of
bacteria present (either in the solutions, for example as an ionic emulsion, or acne or
athlete’s foot treatments, or indeed as a prophylactic in feedstuffs for animals). The
present invention provides a novel means to treat “full-blown” bacterial infection as an
alternative to antibiotic regimens. High levels of bactericidal activity have been shown
using the invention, in its various aspects, both at an in vitro and in vivo level.
Variations on the technology, namely the type of enzymes and substrates utilised to
produce the bactericidal reactive oxygen species, would be used to treat other types of
bacterial infection.
An antimicrobial nasal rinse product as described herein contains the required
components of the system. These include a suitable peroxidase enzyme, such as
lactoperoxidase or chloroperoxidase, the appropriate substrate (such as iodide,
thiocyanate, or chloride ion). Similarly, a source of hydrogen peroxide would be
supplied, optionally by a mono-saccharide sugar and its cleaving enzyme, for example
glucose and glucose oxidase, or a hydrogen peroxide releasing molecule, such as
percarbonate or citric acid. These components and substrate(s) may be supplemented as
a dry salt powder/lyophilised enzyme in a sachet that would be re-hydrated before use.
The use of saline solution (or the addition of extra sodium chloride to the sachet) would
regulate the required salinity. Likewise, the use of sodium bicarbonate would regulate
the acidity. A dry-powdered form of the system would allow the product to maintain
shelf-life, reduce the volume of the product so that only water would be needed to
‘activate’ the system.
A composition for the treatment of CF/TB may be a solution delivered to the lung by
means of a nebulised spray, which would deliver the required components of the
invention (either lactoperoxidase or chloroperoxidase, required substrate
(thiocyanate/chloride), and a source of hydrogen peroxide (glucose and glucose oxidase,
or other possible enzymatic methods, such as xanthine oxidoreductase/oxidase and
hypoxanthine/xanthine or L-amino acid oxidase and L-amino acids, or by the addition
of a perhydrate such as sodium percarbonate, or even by the direct addition of a
hydrogen peroxide solution) to the lung. Storage of the solution may be achieved by
seperating certain components to ensure the reaction would only occur on delivery to
the lung. As such, one solution may contain the haloperoxidase enzyme and glucose and
would be mixed with another solution containing the substrate and glucose oxidase.
Mixing of these would start the reaction, producing the highly antibacterial reactive
species that could be delivered to the lung by nebuliser in a given volume.
Concentrations of each of the components may be tailored to the human lung, but would
be of the same possible order of magnitue as those described for the mastitis treatment
above. Likewise, the same overall delivery mechanism may be used for a general
antibacterial throat spray, which would not require the need for nebulisation.
The ability to efficiently eradicate biofilm cells by the present invention (see detailed
description of the invention Example 3) confers a significant improvement over
presently used antimicrobial treatments that are known to be inefficient in the treatment
of cystic fibrosis infection of the lung as Pseudomonad strains exhibit greater tolerance
to antibiotics (“Differences in biofilm formation and antimicrobial resistance of
Pseudomonas aeruginosa isolated from airways of mechanically ventilated patients and
cystic fibrosis patients”, Fricks-Lima et al., 2011, International Journal of Antimicrobial
Agents, 37(4), 309-315).
One embodiment described herein also provides a new method of treating burns
patients. A poultice impregnated with the enzymes capable of producing the
antimicrobial species (notably a haloperoxidase; such as
lactoperoxidase/chloroperoxidase; and an oxidoreductase, such as glucose oxidase) may
be dipped into a gel based solution containing ingredients necessary for the production
of antibacterial compounds; the potential substrate, notably iodide/thiocyanate/chloride;
and a monosaccharide sugar that will react with the oxidoreductase enzyme, notably
glucose. This poultice could be placed over the wound where required, allowing a safe
release of highly antibacterial compounds, maintaining a safe, aerobic environment
needed for tissue repair. Concentrations of the components would again be similar to
those described above for the treatment of mastitis. Alternative methods of producing
hydrogen peroxide could be used by the varying of the oxidoreductase and sugar, by
other enzymatic reactions (L-amino acid oxidase and L-amino acids, xanthine
oxidoreductase/oxidase and xanthine/hypoxanthine), by the addition of a perhydrate
such as sodium percarbonate, or the direct addition of a solution of hydrogen peroxide.
The embodiment described utilising the haloperoxidase based system may also be
employed to improve the physical properties of medical devices, to limit the chance of
causing infection during implantation into a patient. The method is safe, limiting drug
reaction or resistance, as is often the case in using antibiotics. The impregnation of
required enzymes, lactoerpoxidase or chloroperoxidase, and an oxidoreductase, glucose
oxidase and/or additional substrates, onto the surface of the device, is a viable method
of delivery. Typically, the substrates required to drive the reaction, notably glucose and
thiocyanate/chloride are present in blood, saliva, milk, and urine, thus a reaction would
occur on the slow release of the enzymes and/or additional substrates. The slow release
of the enzymes may be undertaken by their anchoring/coating on the surface by means
of electrical charge, in the form of an impregnated biodegradable polymer. As the
polymer degrades, fresh enzyme molecules are free to react with substrates passing over
the device. The steady release of these enzymes over the course of the initial number
days, post implantation, would maintain sterility of the device in the important window
of opportunity where infections/biofilms would normally take hold.
A generalised antibacterial solution may be produced by the mixing of two solutions (or
possibly their dried-powder forms in water). For example, an antibacterial solution may
be prepared by the mixing of crude sources of peroxidase enzyme (chloroperoxidase or
lactoperoxidase, for example), the appropriate substrate (optionally in the form of a salt
for example sodium iodide/thiocyanate /or chloride)and a source of hydrogen peroxide
(cheap sources would include citric acid, percarbonate, hydrogen peroxide itself, or
sugars with the appropriate enzyme to react with it – for example, glucose and glucose
oxidase). This antibacterial solution would be activated by the mixing of the
components in solution. The solution may be delivered to the surface needing to be
cleaned. Such examples would include beer lines, ceramic surfaces, metal surfaces, etc.
and could be used in hospitals, factories, kitchens and the like. The solution would be
relatively non-toxic, and would not produce the odour associated with many cleaning
products such as bleach. Further to this, a protein such as lactoferrin could be
supplemented to the system to increase potency. Lactoferrin is known to help break
down bacterial biofilm, and thus may serve to accentuate the antimicrobial nature of the
product.
Likewise, the proposed compositions could be pre-prepared or activated before
administration to an infection site.
Detailed Description of the Invention
Example 1
An antimicrobial composition was produced by the addition of 150 mg potassium
iodide, 4 mg lactoperoxidase ( ≥80 units/mg), and 2 mg glucose oxidase (~200 units/mg)
to 7 ml sterile water. This embodiment is referred to as ‘KI-Dose-150’. Similarly, a
composition was prepared using 150 mg potassium thiocyanate, and is referred to as
‘Thio-Dose-150’. The antimicrobial properties of these compositions were tested using
a doubling dilution 96-well plate growth assay-based method. An aliquot of the
composition was added to 150 µl growth medium (with 1-2% glucose present)
containing 10 bacterial cells, and brought to a final volume of 300 µl. The
composition concentration was doubly diluted by the removal of 150 µl of the mixture
and transfer to the next well containing 150 µl of identical growth medium, lacking the
ROS producing components. The optical density of the medium was measured for 24
hours at 595 nm. The concentration required to completely inhibit the bacteria was the
lowest concentration of the composition employed that resulted in no visible signs of
growth in the medium after the 24 hours. Controls included wells to which none of the
composition was supplemented, or wherein, one of the components was removed from
the composition. This method was used to determine the antimicrobial potency of the
compositions against a variety of micro-organisms, notably Escherichia coli,
Staphylococcus aureus, Psuedomonas aeruginosa, Burkholderia cepaciae,
Streptococcus dysglactiae, Streptococcus uberis, a non-haemolytic coliform. These
organisms are the often described as causative agents of numerous infections, notably
bovine mastitis, cystic fibrosis lung infections, skin infections, burns infections, etc and,
as such, represent the variety of organisms that the composition will be used to treat.
The relative susceptibility of the organisms to the compositions is described in Table 1
(Ratio indicates the lowest dilution of the composition at which no growth was still
recorded, for example, 1:800 had the composition diluted to the equivalent of 1 µl
composition for every 800 µl of growth medium) and are the lowest concentrations of
the composition that inhibited growth. The estimated level of the antimicrobial reactive
oxygen species (ROS) produced over the course of 24 hours is also provided (see also
Example 19 below).
Table 1 Susceptibility of bacterial strains to ‘Thio-Dose-150’ and ‘KI-Dose-150’.
The MIC indicates the level of reactive oxygen species below which bacteriocidal
effects were not noted (millimoles per litre produced over 24 hours).
Strain Thiocyanate Iodide
Dilution ROS MIC Dilution ROS MIC
E. coli ATCC 25922 1:400 0.4 – 0.8 1:800 0.25 – 0.5
Strep. dys 143 1:48,000 0.003 – 0.007 1:48,000 0.005 – 0.01
Strep. dys 160 1:48,000 0.007 – 0.01 1:48,000 0.005 – 0.01
Strep. uberis 1:24,000 0.007 – 0.01 1:24,000 0.005 – 0.01
Staph. aureus 15676 1:800 0.3 – 0.6 1:800 0.25 – 0.5
Burk. cepacia 1:800 0.3 – 0.6 1:1,600 0.075 – 0.15
P. aeruginosa PA01 1:800 0.3 – 0.6 1:1,600 0.075 – 0.15
Non-haemolytic coliform 1:400 0.4 – 0.8 1:800 0.25 – 0.5
Example 2
The lactoperoxidase system has been discussed in terms of its bacteriostatic or
inhibitory qualities. The protocol described in Example 1was performed in larger scale
volumes (an initial 500 µl aliquot of KI-Dose-150 or Thio-Dose-150 was added to 10 ml
growth medium containing the test organism and doubly diluted). After 48 hours of
incubation, the bacteriocidal qualities of the system were investigated by the sub-
culuture of the inoculated broths to agar plates. The composition was deemed to be
bacteriocidal for a bacterial strain at a particular concentration if no more than 0.0001%
of cells were recoverable after 24 hours following sub-culture to the fresh agar plate (ie
72 hours after exposure to the antimicrobial composition). The compositions were
bacteriocidal to each of the tested strains at concentrations that would be achievable for
an infection treatment (lowest dilutions at which inhibition was noted are presented in
Table 1 above.
Example 3
The choice of hydrogen peroxide source can be shown to affect the the LP system and
also the ability to produce an antimicrobial composition based on ROS at bactericidal
concentrations. Aliquots (20 ml) of nutrient broth were inoculated with 10 cells of E.
coli ATCC 25922, and 150 µl of the inoculated broth were added to wells in a 96 well
growth plate. This was repeated with the inoculated broth being further supplemented
with LP (37.5 µl of a 4 mg/ml solution) and KI (75 µl of a 40 mg/ml solution) to the
medium.
Sources of hydrogen peroxide were added (150 µl) to well 1 and doubly diluted to well
11, but not to well 12, which acted as a control. The sources of hydrogen peroxide were
as follows:
5 ml water containing 40 µl H2O2 (30% w/v)
5 ml water containing 50 mg sodium percarbonate
5 ml glucose (20%) + 47 µl glucose oxidase (2.5 mg/ml, 200 Units/mg)
Figure 1 illustrates that 1:8 and 1:16 dilutions of the H O solution were inhibitory to E.
coli, though the 1:32 dilution was not. Repetition of this assay in the presence of
supplemented KI and LP did not accentuate the effects observed using H O directly,
with a 1:32 dilution still not inhibitory to the bacteria (Fig. 2), although the levels of
H O would have been significantly reduced during the incubation, in this case. This is
because the supplemented LP would use available peroxide to catalyse the production of
reactive oxygen species using the supplemented KI as substrate.
The pattern of inhibition caused by the addition of the sodium percarbonate solution to
inoculated broths (Fig. 3) was identical to that observed following direct H O addition.
It is clear that there was no difference as regards inhibition, following supplementation
of KI and LP when using sodium percarbonate as the source of hydrogen peroxide
(Figs. 3 and 4) although the peroxide would have been used to produce the less toxic
reactive oxygen species, hypoiodate, during the incubation.
It was clear that only a 1:2 and 1:4 dilution of the glucose/glucose oxidase solution
added produced sufficient H O to be inhibitory (Fig. 5 ), but not at dilutions of 1:8
(partial), 1:16 or 1:32. It was clear, however, that on repetition of the glucose/glucose
oxidase assay in the presence of the KI and LP (Fig. 6), inhibition of E.coli occurred at a
much greater dilution (up to and including a 1:32 dilution) than achievable in the
absence of added KI and LP (Fig. 5).
This result clearly indicates that the enzymatic production of hydrogen peroxide at
levels greatly lower than those that are inhibitory to bacteria are sufficient to drive the
production of inhibitory concentrations of antimicrobial reactive oxygen species. This
offers a method to deliver a therapeutic dose of the antimicrobial reactive oxygen
species without accumulation of potentially toxic H O .
Example 4
Volumes of milk (10 ml) were inoculated with E. coli and supplemented with the
lactoperoxidase, glucose oxidase, potassium iodide and Beta-galactosidase as a
mechanism to generate the antimicrobial composition of the invention. Concentrations
of 3.75 mg/L glucose oxidase (~200 units/mg), 12 mg/L lactoperoxidase ( ≥80
units/mg), 120 mg/L potassium iodide/thiocyanate, and 400 ml/L Beta-galactosidase ( ≥
2,600 units/ml) or greater were sufficient to observe antibacterial activity. At the
optimised concentrations these mixtures proved lethal to up to 10 cells/ml of E. coli
(subculture of the solution to fresh agar plates resulted in no recoverable cells.).
Concurrent negative controls (excluding each of the components) resulted in an increase
of bacterial numbers over the proceeding 24 h in the milk. The composition, generated
in this manner, worked efficiently in the first 2 hours to eradicate bacteria.
A preparation was designed for use in the treatment of bovine mastitis by an
intramammary infusion method. A field trial (6 cows, 6 quarters) was conducted
wherein cows were treated on 4 occasions post milking with the proposed bactericidal
composition produced by an enzymatic system (in this case, using Beta-galactosidase
milk activation as an object of the present invention). The preparation contained
lactoperoxidase (4 mg ≥80 units/mg), glucose oxidase (2 mg, ~200 units/mg), Beta-
galactosidase (0.4 ml, ≥ 2,600 units/ml), and potassium iodide (150 mg) per dose.
Significant decreases were noted in somatic cell counts of the animals as a result of
treatment, recorded between 5 and 30 days after treatment. Results from the trial are
tabulated below (Table 2), farms C and D.
Table 2 Somatic Cell Counts of treated animals.
Cow # Initial SCC (in millions) After 5 days 30 days % Reduction
Farm C
1 8.9 1.46 84
2 11.58 0.36 97
3 2.32 0.647 72
Farm D
118 11.094 1.234 89
529 24.942 18.278 27
207 22.835 4.214 82
An attempt was made to determine the effects of the milk pasteurisation process on the
enzymatic components, which can be used to produce the reactive oxygen species of the
composition of the present invention. Working concentrations of the enzymes were
heated in 50 μl volumes to 72˚C and held for 15, 30, 60, 300 or 600 seconds.
Appropriate concentrations of these aliquots were then transferred to milk containing
the necessary components of the system and ~10 cells/ml E. coli. Total viable counts
were performed after 24 hrs incubation at 37ºC. This allowed the determination of
whether the enzymes were still active after heating. Glucose oxidase demonstrated
activity after 300 seconds heating, as did lactoperoxidase. The activity of Beta-
galactosidase was, however, impaired by the heating process, with a typical
pasteurisation cycle (72ºC for 15 seconds) completely inactivating the enzyme. This
would suggest that bacterial starter cultures used in post-processing of milk (yogurt and
cheese) would not be inhibited by the use of the described preparations to generate the
reactive oxygen species useful in the present invention.
A 10 ml volume of milk was used a model to test the hypothesis that a chloroperoxidase
enzyme could be used instead of lactoperoxidase to generate antimicrobial reactive
oxygen species. Milk was again spiked with E. coli (~10 cells/ml). A suitable
concentration of both Beta-galactosidase (2-3 μl, ≥ 2,600 units/ml) and glucose oxidase
(15 μl of a 2.5 mg/ml solution, ~200 units/mg) was supplemented to the milk. A
preparation of chloroperoxidase (0.5 μl, ≥ 11,100 units/ml) was then added, and resulted
in a complete eradication of E. coli cells within 24 hours, at 37ºC. Control experiments,
without each, or two of the enzymes, resulted in the proliferation of a bacterial numbers
within the same incubation conditions (10 cells/ml).
Example 5
A field trial was conducted using a supplemented glucose based enzymatic system to
produce the reactive oxygen species and to assess the efficacy of such an approach to
producing the antimicrobial agents. A number of cows (8) were treated twice a day for
two days with the supplied system. These cows demonstrated a marked decrease in
their somatic cell counts (in the region of 50% after 5 days, see Table 3, Farms A and B,
followed by a similar decrease after a further 5 days for Farm B, where subsequent data
was available), a proxy method of measuring bacterial load. This demonstrated the
efficacy of the lactoperoxidase system in generating the antimicrobial species, without
use of Beta-galactosidase, to give assurance that it was a feasible source for generation
of the bactericidal species.
Table 3 Somatic Cell Counts of treated animals using a glucose supplementation
system to produce the antimicrobial reactive oxygen species.
Cow # Initial SCC (in millions) After 5 days 10 days % Reduction
Farm A
438 3.016 1.68 42.3
852 6.981 3.476 50.2
892 1.56 0.516 66.9
717 6.331 0.218 96.6
Farm B
794 3.4 0.926 0.59 82
501 0.71 0.47 0.394 44.5
831 3.5 3.3 0.995 71
823 0.812 0.554 0.186 77
Example 6
A trial was conducted to determine the ability of the proposed composition to eradicate
biofilm-based bacterial cells. This was performed using two culturing techniques. A
continuous culture of E. coli was established using a chemostat. This system is designed
to allow the operator the ability to control the growth rate of the organism. Most
infections will occur as a result of slow growing cells (due to limited nutrient
availability). This phenotype will have an effect on the tolerance of cells to
antimicrobials, and is more realistic of the host environment. Further to this, these
cultures were used to grow biofilms on a Modified Robbins Device, wherein, the cells
were allowed to attach and proliferate on the surface of a polyurethane coupon. These
cells share the phenotype of biofilm cells noted in a typical infection in mastitis, CF/TB
lungs, wounds, burns, and on medical devices and respond in a similar fashion and offer
a viable model for antimicrobial testing.
The antimicrobial species were produced on test coupons using the lactoperoxidase
based system, containing lactoperoxidase (2 mg/L, ≥80 Units/mg), potassium iodide,
(300 mg/L), glucose (12.5 g/L) and glucose oxidase (0.57 mg/L, ≥200 Units/mg), by
submerging the coupon in the solution at 37º C for 24-48 hours. Control coupons were
also treated with a saline solution or a mixture of the system lacking in one of the
components.
Cells were then recovered from the surface of the coupons by means of sonication, and
their viability determined. Cells treated with saline only were viable (10 cells/coupon),
as were those tested with the system lacking in one of the components required to
produce the antimicrobial species. No viable cells were recovered from the coupons
wherein cells were exposed to the antimicrobial species produced by a fully functioning
LP system. This result compares favourably with similar previously reported treatment
regimes using a variety of antibiotics (“Linezolid compared with eperezolid,
vanocmycin, and gentamicin in an in vitro model of antimicrobial lock therapy for
Staphycoccus epidermidis central venous catheter-related biofilm infections”, Curtin et
al., 2003, Antimicrobial Agents and Chemotherapy, Vol. 47, No.10, p 3145-3148),
wherein cells were still recoverable after 10 days with treatment of 10 g/L gentamycin
and 7 days with treatment of 10 g/L vancomycin, though better results were recorded for
linezolid and eperezolid. Such concentrations are far greater (up to 1,000 fold) than
those that would be lethal to the same strain grown planktonically. By contrast, the
concentrations of the antimicrobial species generated in the present experiment were of
the same order of magnitude as those used to kill planktonic cells.
Example 7
The susceptibility of a number of P. aeruginosa strains to the KI-Dose-150 composition
was tested using the method described in Example 1. These strains were of interest as
they demonstrated increased tolerance to a variety of key antibiotics typically used to
treat lung infections associated with cystic fibrosis, and were recovered from the sputum
of cystic fibrosis patients presenting with lung infection. The relative susceptibilities are
described in Table 4. As evident from Table 4, the antibiotic tolerant strains of P.
aeruginosa are no more tolerant to KI-Dose-150, indicating that the system would be
effective at treating such infections when delivered to the lung. ‘S’ denotes sensitive,
‘R’ denotes resistant or increased tolerance.
Table 4 Susceptibility of antibiotic tolerant P. aeruginosa strains to ‘KI-Dose-150’.
The MIC value represents the minimum level of reactive oxygen species
(hypoiodate) required to kill the strains (millimoles per litre produced over 24
hours).
Amikacin TobramycinCiprofloxacin Gentamicin MIC
PA01 (wild type) s s s s 0.25 mM
R550/2012 9026 R R R R 0.12 mM
R468/2012 9027 s s s 0.06 mM
R479/2012 9028 R R s R 0.12 mM
R480/2012 9029 R s R R 0.12 mM
P. aeruginosa s s s 0.25 mM
Example 8
The treatment of respiratory infections by antibiotics will typically be delivered using
oral or intra venous drugs. The aerosolised form of the antibiotics can also be used to
counteract the poor transfer of drug from blood across the alveoli of the lung to
infection sites. Various embodiments of the proposed antimicrobial composition were
aerosolised using an AeroNeb nebuliser (courtesy of Aerogen Ltd.). Solutions of
hydrogen peroxide/glucose/glucose oxidase/lactoerpoxidase/iodide/ or thiocyanate were
passed through the nebuliser one at a time, or mixed together and passed through the
nebuliser , and the aerosol collected in a sterile 25 ml container. The antimicrobial
potency of the aerosolised forms was compared to un-aerosolised forms (as described in
Example 1), using doubling dilutions on a multi-well plate based assay. The proposed
composition did not show any decreased activity when compared to the solutions that
were not aerosolised. In addition, it was demonstrated that the enzymatic system, which
can be used to produce the antimicrobial species was not affected by nebulisation.
Specifically, the solutions did not show any reduced enzyme activity, or decreased
levels of compound present when compared to stock solutions of the same components.
This model would suggest that the proposed antimicrobial system would be a good
target or candidate for successful aerosol delivery to the lung to treat respiratory
infections.
Example 9
Lactoferrin is a mammalian protein that has been characterised to exercise antimicrobial
properties, particularly on biofilm. As such, it is a good potential compound that could
target and disrupt biofilm production in an infection model, and one that could act
synergistically with a system such as the antimicrobial composition of the invention.
The relative antimicrobial potencies of KI-Dose-150 and Thio-Dose-150 were tested as
described in Example 1, both in the presence and absence of varying concentrations of
lactoferrin. The presence of supplemented lactoferrin to the thiocyante model did not
enhance the antimicrobial properties already present (ratios of lactoferrin to thiocyanate
were 1:1, 1:2, 1:4). This would suggest that the presence of lactoferrin at significant
concentrations does not inhibit the actions of a lactoperoxidase- thiocyanate model to
produce the antimicrobial species. Planktonic cells were used, allowing the possibility
that an accentuated antimicrobial effect would be noted for treatment of an actual
infection.
The same ratios for lactoferrin to iodide did, however, lead to a noted two-fold increase
in antimicrobial activity of the lactoperoxidase-iodide model for production of the
antimicrobial species, suggesting that it would be a suitable companion in a proposed
treatment regime. In the absence of lactoferrin, a 256-fold dilution of the system was
still inhibitory to E. coli. With the addition of lactoferrin (at the three described ratios), a
dilution factor of 512 was also inhibitory to the bacterial culture. Infection sites will
often be composed of biofilm, which would allow an increased activity of the lactoferrin
to be noted.
Example 10
Antibiotic therapies designed for the treatment of bovine mastitis will often induce an
inflammation of the udder, leading to an increase in the somatic cell count for the
animal. This is disadvantageous in that the price of the sold milk depends on a low
somatic cell count. A number of drugs can typically be added to counter the
inflammation arising due to the intramammary infusion of an antimicrobial therapy.
Prednisone (or its active form, prednisolone) is a glucocorticoid steroid used to
minimise an undesired immune response. A dosage of 10-20 mg is often administered in
conjunction with antibiotic based intramammary infusions to halt an increase in the
somatic cell count. An in vitro experiment using a dose of the proposed lactoperoxidase
system (KI-Dose-150) in the absence and presence of either predisone or prednisolone
did not result in any decrease in antimicrobial potency of the composition. This would
indicate that the use of a typical dose of either drug would not interfere with the ability
of the composition of the invention to eradicate bacteria in the udder (or other
environment), and would help minimise increase of the somatic cell count.
Example 11
The ability of an enzymatic system to produce the antimicrobial species on a continuous
basis was determined by repeat inoculations of bacterial culture to an antibacterial
component containing solution. A 10 ml volume of LB growth medium was
supplemented with glucose oxidase (15 µl of 2.5 mg/ml, 200 Units/mg), beta-
galactosidase (30 µl, 10 mg/ml, 48,000 Units/mg), lactoperoxidase (20 µl, 4 mg/ml, 80
Units/mg) potassium iodide (30 µl, 40 mg/ml), with a final concentration of 2% lactose.
Approximately 10 cfu of E. coli ATCC 25922 were added and the mixture was
incubated overnight, at 37 °C. After 24 hours, no cells were recoverable to a fresh
nutrient agar plate. A further inoculum of approximately10 cfu of E. coli ATCC 25922
cells was then added to the volume and the mixture was again allowed to incubate
overnight. Similar, subsequent inoculations (ten inoculations, at one day intervals) of
the broth with the bacterium did not result in growth or the recovery of bacterial cells.
This result demonstrates that the concentration of the antimicrobial reactive species was
held sufficiently above bactericidal levels over a significant time period.
Example 12
The effect of substrate choice on the potency of the composition produced by various
systems was determined using variations of an inhibition growth assay, firstly, where
the concentration of H O (produced by the enzymatic reaction of glucose and glucose
oxidase) was constant and the concentration of the chosen substrates was altered.
Secondly, an assay where the concentration of substrates was maintained constant, and
the H O levels were varied was employed.
(i) Constant H O
E. coli (50 µl of an overnight culture) was added to Mueller Hinton broth containing 5
µl glucose oxidase (2.5 mg/ml) and 10 µl LP (4 mg/ml). This was aliquoted (150 µl) to
rows of a 96-well plate. Equal volumes (150 µl) of either potassium iodide or potassium
thiocyanate (both 40 mg/ml) were added to the initial well. The samples were doubly
diluted as far as well 11, leaving well 12 as a control. The plate was incubated overnight
at 37 °C, and the optical density measured throughout.
Result: Thiocyanate concentrations in dilutions 1 to 9 were at a level sufficient for
complete inhibition of the bacteria. Iodide concentrations in dilutions 1 to 8 were at a
level sufficient for complete inhibition of the bacteria. This result would initially
indicate that there was no significant difference in the potency of the reactive species
produced by either substrate, and whatever differences were noted could have been as a
result of the difference in molarity of the concentrations.
(II) Constant Substrate
E. coli (200 µl of an overnight culture) was added to 20 ml Mueller Hinton broth
already containing 40 µl LP (4 mg/ml) and 60 µl of either potassium iodide or
potassium thiocyanate (40 mg/ml). This was aliquoted (150 µl) to a 96 well plate.
Samples of a H O producing system (2 ml 20% glucose containing 10 µl glucose
oxidase, 2.5 mg/ml) were added to the initial well, and doubly diluted, leaving well 12
as a control.
Result: Using a broth with a constant thiocyanate concentration, there was inhibition in
the two highest dilutions of sample (H O ). However, on using iodide, there was
inhibition of bacterial growth up to, and including, six dilutions of sample.
This results indicates that there is a significant difference in the potency of the
antimicrobial species produced using an enzymatic system, which releases lower levels
of hydrogen peroxide, when the substrate level is maintained at a constant level. This
would imply that there would be a distinct advantage in using iodide when lower levels
of H O production are typical. Differences in molarity cannot explain the apparent
difference in outcome when using iodide instead of thiocyanate.
Repetition of (i) and (ii) using milk as the growth medium showed very similar results
and patterns. Using an alternative source of H2O2 (direct addition in this case) did not
show up the peculiar outcome difference between iodide and thiocyanate.
Example 13
A protocol was drawn up that allows an operator to determine the appropriate
concentrations of the antimicrobial species useful in the invention for use in the
inhibition/killing of bacterial cells in broth. The protocol is based on doubling dilutions
of the components, similar to that used in 96-well plate described in Example 1. A
bacterial culture (10 cfu/ml) is established and aliquoted to tubes (5 ml volumes added
to 15 ml tubes would allow sufficient headspace for required oxygen, with the first tube
to contain double the volume, 10 mls. The broth should contain sufficient appropriate
sugar if using enzymes to produce H O , for example, glucose if using glucose oxidase,
with 1-2% being typically sufficient).
An aliquot (preferably no more than 5% of the total volume of the solution, 500 µl) of
the hydrogen peroxide producing components are added to the initial volume, and
doubly diluted. After 24 hours the level of innate tolerance for a bacterial strain to
hydrogen peroxide can be determined by the pattern of growth/no growth in the tubes.
The hydrogen peroxide producing components could consist of a monosaccharide or
disaccharide sugar and their appropriate cleaving enzymes (notably lactose and beta-
galactosidase and glucose oxidase, or glucose and glucose oxidase) or more simply
hydrogen peroxide can be added directly, or as hydrogen peroxide releasing
percarbonate or citric acid, etc.
In conjunction with the test to determine the innate hydrogen peroxide sensitivity of the
test strain, the same test would also be used using a reactive oxygen species producing
solution (such as Thio-Dose-150 or KI-Dose-150, as described in example 1), wherein
the hydrogen peroxide producing components are present, as well as the peroxidise
enzyme (chloroperoxidase or lactoperoxidase, and their appropriate substrates) are also
present.
Although various ratios and concentration variations of the LP system, for example, can
be employed to yield antimicrobial and bactericidal concentration of the reactive
species, the authors recommend a possible ratio of 75:2 of substrate to lactoperoxidase
(for example, 150 mg KI and 4 mg lactoerpoxidase (at least 80 Units/mg). Similarly, if
H O is to be produced by the enzymatic cleavage of glucose, for example, the authors
recommend a 75:2:1 of substrate, lactoperoxidase, and glucose oxidase (200 Units/mg
glucose oxidase). The samples should be incubated at the appropriate temperature, and
shaken overnight. Control cultures (without, for example, LP components or H O )
should yield bacterial growth. At sufficiently high concentrations of H O (initial few
tubes), growth should not be observed but as the H O level drops (more dilute
cultures), growth will be evident. This will allow the operator to determine the innate
tolerance of the strain to the actions of H O . Often, Streptococci strains are very
susceptible to the actions of H O , as they lack catalase required to cleave the H O
2 2 2 2
molecule, whilst other species will be tolerant of H O at levels of ~2mM (some yeasts,
for example). The addition of the substrate and lactoperoxidase to the initial tube should
result in no growth at levels of H2O2 that were not previously inhibitory as the more
potent reactive species are produced. Similarly, there will be a level at which the
dilution was such that growth occurred. The difference in outcome between ‘H O only’
and ‘H O and substrate and LP’ will inform the operator as to concentration of the LP-
system components necessary to kill the test strain, or to inhibit its growth over 24 or 48
hours, as required. The authors recommend choosing a concentration at which the H O
is not inhibitory in itself. Data described in Example 3 describes the use of an enzymatic
cleavage of sugar, which allows a ‘window’ where the H O levels produced in the
solution are insufficient to cause inhibition, though sufficient to drive the production of
the antimicrobial reactive oxygen species by the LP reaction (in instances where the
strain does not produce catalase, and is therefore extremely susceptible to the actions of
H O , the authors recommend using levels sufficient to kill typical catalase producing
strains). A sub-culture to appropriate agar plate at 24/48/72 hour time points will allow
the operator to determine at which concentration the components are produced at
bactericidal concentrations, as opposed to bacteriostatic levels. The composition will be
determined as bacteriocidal when no more than 0.001 % of the starting cell numbers are
recoverable from the broth.
This test allows the operator to determine the bacteriocidal concentration of the dose,
and also the concentrations of hydrogen peroxide required to produce the components
using an enzymatic system, without generating inhibitory levels of hydrogen peroxide.
Such information will be valuable if contemplating introducing an enzymatic system to
a sensitive environment, such as the mammalian lung.
Existing statistical models will allow the operator to then ‘scale up’ appropriately to
determine the necessary levels required to treat infections or large volumes of liquid etc,
for example, the udder or lung.
Example 14
The lower limits of each of the components in an enzymatic system, required to produce
inhibitory biocidal concentrations of the antimicrobial agents, were determined (for
example Table 1 and Table 5). To establish these lower limits for each component,
minimum inhibitory concentrations for each were calculated using doubling dilutions on
a 96-well plate, in a manner similar to that described in Example 1, wherein the
concentration of the component of choice is lowered until no effect on growth is noted.
In 10 ml LB broth growth medium (with 2% glucose), replete with 120 mg/L KI, 320
units LP, at least 0.5 unit glucose oxidase/ml is required to produce hydrogen peroxide.
Concentrations below this resulted in insufficient hydrogen peroxide being produced to
provide for the further production of the reactive oxygen species at a bactericidal
concentration. Similarly, the reduction of glucose levels requires an increase of glucose
oxidase levels to compensate; 1% glucose required 1 units/ml, while 0.5% glucose
required 2 units/ml activity glucose oxidase. In solutions where the glucose levels and
glucose oxidase levels are sufficient, the level of required iodide (or thiocyanate)
substrate was approximately 0.5 mM. At levels below this, there was insufficient
reactive oxygen species produced to result in effective bactericidal activity. The level of
LP required for a reaction to produce the reactive oxygen species at the required
concentrations was determined at 0.15 unit activity/ml (1mM KI present). Levels below
this resulted in little antibacterial activity. This embodiment of the invention suitable for
the therapeutic treatment of mastitis also included beta-galactosidase to convert the
lactose present in milk to glucose. An in vitro examination of the required level of this
enzyme was performed in milk (5% lactose), with 1 mM KI, 0.75 units/ml glucose
oxidase activity/ml (levels below this will produce a ‘bottleneck’ in the enzymatic
pathway resulting in insufficient reactive oxygen species being produced), and 1 unit
lactoperoxidase activity/ml present The required activity of beta-galactosidase lay at
approximately 1.5 units activity/ml. Beta-galactosidase activity at levels below this did
not result in the inhibition of bacterial growth or in killing of bacterial cells, but rather in
bacterial proliferation.
Example 15
It is possible to produce the antimicrobial reactive oxygen species of the composition of
the invention before adding it to the site of infections. This may be achieved by the
mixing of the required enzymatic components ensuring that the resulting reactive
oxygen species (ROS; hypothiocyanate, hypoiodate, or hypochlorate) is produced
outside of the treatment site. Further to this, any excess hydrogen peroxide left after the
reaction can be removed by the addition of catalase (which reacts with hydrogen
peroxide, producing oxygen gas and water). This may prove a very safe method of
delivering the chosen ROS without the potentially disadvantageous hydrogen peroxide
molecules.
Similarly, it is possible to introduce the catalase at the infection site also to help
‘quench’ the potential build-up of harmful hydrogen peroxide.
To demonstrate this, the potency of the KI-Dose-150 and Thio-Dose-150 compositions
were tested, using the protocol described in Example 1, in a broth growth medium
containing catalase (20 µl of a 4 mg/ml, >1,000 units/mg to 20 ml broth). The potency
of the doses was not reversed. A 1:1024 dilution of the doses was inhibitory in the
absence of catalase, and a 1:512 dilution of the doses was inhibitory in the presence of
catalase.
As a comparison, the test was performed using only hydrogen peroxide (0.85 M), both
in the presence and absence of catalase. The catalase level was sufficient to completely
reverse the inhibitory nature of hydrogen peroxide, indicating that the catalase levels
used for the experiment were sufficient to ‘quench’ the activity, and thus, would be
appropriate component to ‘mop up’ excess hydrogen peroxide produced if the iodide or
thiocyanate substrate is used up, but not inhibit the reaction per se when substrate is still
present.
This may serve to protect mammalian tissue.
Example 16
A further example of a pre-activated system was employed as follows: solutions (4 ml
volumes) containing 0.85 M H O plus none or 2.5 M NaCl/5 µl chloroperoxidase
(~10,000 Units/ml) were allowed incubate. The solutions were then split and either
catalase treated (50 µl of a 4 mg/ml, >1,000 units/mg) or were not catalase treated. The
relative antimicrobial properties of the solutions were then tested using the protocol as
described in Example 1 using E. coli supplemented broth. Inhibition of the bacteria was
noted at >1:640 dilutions for hydrogen peroxide only, hydrogen peroxide +
chloroperoxidase/NaCl, and the catalase treated hydrogen peroxide +
chloroperoxidase/NaCl samples. However, there was no inhibition noted for the catalase
treated hydrogen peroxide sample. This result would suggest that it is possible to
remove any excess hydrogen peroxide by means of catalase treatment, without reducing
the potency of the reactive oxygen species. The solutions were allowed to incubate for
longer, after which time (72 hours) the result was repeated. This would suggest that this
form of the ROS was relatively stable and could be prepared in advance of use.
Example 17
The protocol described in Example 1 was used to test ‘KI-Dose-150’, a version lacking
iodide and lactoperoxidase, as well as version lacking glucose oxidase. All three were
tested against Candida glabrata, Candida krusei, Candida tropicalis, Candida albicans
and Saccharomyces cerevesiae. Protocols were carried out for the Candida strains and
Saccharomyces strain in nutrient broth and LB broth respectively, each supplemented
with 2% glucose using the method described in Example 1. Results are presented in
Table 5. It is clear from Table 5 that all strains are inhibited by the actions of ‘KI-Dose-
150’ and that the reactive oxygen species are thus antimicrobial and not just
antibacterial. The levels of hydrogen peroxide produced in these dilutions of the
composition were themselves non-inhibitory to the tested strains.
Table 5 Susceptibility of fungal and yeast strains to ‘KI-Dose-150’. The MIC value
represents the minimum level of reactive oxygen species (hypoiodate) required to
kill the strains (millimoles per litre produced over 24 hours)
Candida albicans 0.25 – 0.5 mM
Candida tropicalis 0.12 – 0.25 mM
Candida glabrata 0.25 – 0.5 mM
Candida krusei 0.25 – 0.5 mM
Saccharomyces cerevisiae 0.12 – 0.25 mM
Example 18
The results presented in Example 3 demonstrate that there are three crucial levels of
H O . These levels can be described using a schematic model, as illustrated in Figure 7.
Firstly, there is a higher threshold level of H O , at or above which inhibition of
bacterial growth occurs as a direct result of the concentration of H O in the growth
medium. This is not the preferable mechanism of action for an antimicrobial
composition, as H O is toxic to host cells, and has been linked to mammalian tissue
damage, for example.
The second threshold level of H O is that required for the effective production of the
antimicrobial reactive oxygen species. The experiments presented herein (Example 3)
describe the distinct advantage that is conferred by the use of an enzymatic method of
H O production, wherein the levels of H O can be maintained within this required
2 2 2 2
‘window’ (Fig. 7) for a longer period of time (i.e. these are concentrations of H O that
are effective at allowing the production of the required concentration of reactive oxygen
species, but that are not toxic in themselves).
Lastly, the third threshold level of H2O2 is one at which there is insufficient H2O2 to
inhibit or provide for the production of the reactive oxygen species using an enzymatic
system.
Using a more direct source of peroxide (such as the sodium percarbonate or hydrogen
peroxide itself) results in a high initial concentration of H O that quickly decreases to a
level that is ineffective for the production of the desired reactive oxygen species (Fig. 7).
Example 19
The conversion of substrate to the antimicrobial reactive oxygen species (ROS) was
estimated by direct measurement of the relevant substrate concentration during
conversion and, for example, after 24 hours. The various antimicrobial reactive oxygen
species are relatively short-lived, but have variable half-lives depending on the substrate
used, so a direct titration was not useful. For example, Thiocyanate concentrations, at 1x
(1.36 mM) and 5x (6.8 mM) levels, were compared before and after incubation in a
solution containing glucose, lactoperoxidase, and glucose oxidase. These were
compared to a standard concentration curve of thiocyanate levels (0, 0.0625, 0.125,
0.25, 0.5, 1, 2, and 5x concentrations) using a colourometric assay as follows:
Five grams ferric chloride was suspended in 50 ml water. Any undissolved ferric
chloride was removed by centrifugation, leaving ~30 ml ferric chloride solution. To
cuvettes, 150 µl of the ferric solution was added, followed by the addition of 700 µl
water. A volume of 10x thiocyanate was added to each cuvette (200 µl, 160 µl, 100 µl,
40 µl, 20 µl, 10 µl, 5 µl, 25 µl (1:10), 12.5 µl (1:10), 0 µl). The final volume in the
cuvette was brought to 1,050 µl by the addition of water. For the sample, 50 µl of the
previously incubated 1x or 5x dilutions were added, plus 150 µl water. The optical
density was recorded at 460 nm, and the concentrations were then calculated using a
standard curve. The resulting standard curve had an r2 value of >0.99, (see Figure 8)
indicating that it was an accurate method of determining an unknown concentration of
thiocyanate.
The 1x dose (left incubating overnight with the enzyme system), read as 0.17 x dose
after 24 hours. Similarly, the 5x dose (left incubating overnight with the enzyme
system), read as a 1.1 x dose after 24 hours. Both of these results would indicate that,
under these conditions, there was an 80-85% drop in thiocyanate levels. Assuming a 1:1
ratio of thiocyante loss to ROS production (in this case, OSCN-), this allows the
determination of the ROS levels produced to be in the region of 1 mM, and 5 mM over
the 24 hours for the 1x and 5x doses, respectively. This value can be adapted using a
higher substrate concentration, whilst maintaining efficiency in conversion, at least
within the range tested here.
The specific levels of ROS disclosed here as providing bactericidal and fungicidal
activity are greater than the levels produced using the LP system elsewhere. The
concentration dependent microcidal effect described in this application; and the ability
to determine minimum inhibitory concentrations for the ROS against target strains and
in various media and settings, allows the use of the composition of the invention as a
targeted bacteriocidal and microcidal therapeutic and antimicrobial composition, as
opposed to applications with merely general non-specific bacteriostatic effects.
Example 20
The ability to achieve potentially therapeutic doses of the reactive oxygen species in
vivo was investigated, again using a milk model. The intramammary infusion method
was used to introduce the described protoype of Example 4, [150 mg KI, 4 mg
lactoperoxidase (320 units), 2 mg glucose oxidase (400 units), and Beta-galactosidase,
(1,350 Units)] to a bovine udder. This was performed after milking of the animal. At the
next milking, a sample of milk was obtained. Aliquots (10 ml volumes) of the milk were
spiked with approximately 10 cfu/ml of bacterial strains (E. coli, P. aeruginosa, or S.
dysgalactiae) and allowed incubate overnight at 37 °C whilst shaking. A total viable
count was performed using agar plates. The milk was completely inhibitory to the
strains. This would indicate the presence of the reactive oxygen species in the milk at a
concentration sufficient to kill these mastitis causing organisms. This is important in
demonstrating the technology as a therapeutic, Further to this, because the reactive
oxygen species are relatively short-lived, it is likely that the concentration would have
been higher in the udder itself, increasing the effectiveness of the treatment further.
Compositions suitable for administration.
A solution containing containing 1-100,000 Units activity glucose oxidase, 1 – 100,000
Units activity of lactoperoxidase, and 0.1-10,000mg thiocyanate/iodide, and 0.01-
100,000 Units activity of beta-galactosidase would be suitable to be administered to the
udder of an animal as an intramammary infusion
A solution containing containing 1-100,000 Units activity galactose oxidase, 1 –
100,000 Units activity of lactoperoxidase, and 0.1-10,000mg thiocyanate/iodide, and
0.01- 100,000 Units activity of beta-galactosidase would be suitable to be administered
to the udder of an animal as an intramammary infusion
A solution containing containing 1-100,000 Units activity glucose oxidase, 1 – 100,000
Units activity of lactoperoxidase, and 0.1-10,000mg thiocyanate/iodide, and 0.01-
100,000 mg glucose would be suitable to be administered to the udder of an animal as
an intramammary infusion
A solution containing containing 1-100,000 Units activity glucose oxidase, 1 – 100,000
Units activity of lactoperoxidase, and 0.1-10,000mg thiocyanate/iodide, and 0.01-
100,000 mg glucose would be suitable to be administered to the lungs for the treatment
of bacterial infection as a nebulised spray.
The same solution as above containing supplemented lactoferrin (0.01 – 100,000 mg),
prednisone (0.01 – 100,000 mg), or prednisolone (0.01 – 100,000 mg), catalase (1-
1,000,000 Units) or a combination of two or more of these.
A solution containing containing 1-100,000 Units activity glucose oxidase, 1 – 100,000
Units activity of chloroperoxidase, and 0.1-10,000mg chloride ion, and 0.01- 100,000
mg glucose to be administered to the lungs for the treatment of bacterial infection as a
nebulised spray.
The same solution as above containing supplemented lactoferrin (0.01 – 100,000 mg),
prednisone (0.01 – 100,000 mg), or prednisolone (0.01 – 100,000 mg), or a combination
of two or more of these.A solution containing containing 1 – 100,000 Units activity of
lactoperoxidase, and 0.1-10,000mg thiocyanate/iodide, and 0.01- 100 ml hydrogen
peroxide would be suitable to be administered to the lungs for the treatment of bacterial
infection as a nebulised spray.
A poultice impregnated with 1-100,000 Units activity glucose oxidase, 1 – 100,000
Units activity of lactoperoxidase and an accompanying gel containing 0.1-10,000mg
thiocyanate/iodide, and 0.01- 100,000 mg glucose to be applied to the poultice prior to
its use in treating burns or open wounds of a patient.
A poultice impregnated with 1-100,000 Units activity glucose oxidase, 1 – 100,000
Units activity of chloroperoxidase and an accompanying gel containing 0.1-10,000mg
chloride ion, and 0.01- 100,000 mg glucose to be applied to the poultice prior to its use
in treating burns or open wounds of a patient.
The same poultices as above containing supplemented lactoferrin (0.01 – 100,000 mg),
prednisone (0.01 – 100,000 mg), or prednisolone (0.01 – 100,000 mg), catalase (1-
1,000,000 Units) or a combination of two or more of these.A variety of medical devices
may be coated/impregnated with 1-100,000 Units activity glucose oxidase, 1 – 100,000
Units activity of lactoperoxidase before insertion into the body of a patient.
A pre-prepared composition containing iodide/thiocyanate ions (0.1-10,000mg) allowed
to react fully with hydrogen peroxide (0.01 – 100 ml) in the presence of lactoperoxidase
(0.01 – 1,000,000 Units). The composition is catalase treated (0.01 – 1,000,000 Units)
to remove excess hydrogen peroxide, before the composition is used to treat infection
sites.
A pre-prepared composition containing chloride ions (0.1-10,000mg) allowed to react
fully with hydrogen peroxide (0.01 – 100 ml) in the presence of chloroperoxidase (0.01
– 1,000,000 Units). The composition is catalase treated (0.01 – 1,000,000 Units) to
remove excess hydrogen peroxide, before the composition is used to treat infection
sites.
A pre-prepared composition containing chloride ions (0.1-10,000mg) allowed to react
fully with sodium percarbonate (0.01 – 100,000 mg) in the presence of chloroperoxidase
(0.01 – 1,000,000 Units). The composition is catalase treated (0.01 – 1,000,000 Units)
to remove excess hydrogen peroxide, before the composition is used to treat infection
sites.
A pre-prepared composition containing thiocyanate/iodide ions (0.1-10,000mg) allowed
to react fully with sodium percarbonate (0.01 – 100,000 mg) in the presence of
lactoperoxidase (0.01 – 1,000,000 Units). The composition is catalase treated (0.01 –
1,000,000 Units) to remove excess hydrogen peroxide, before the composition is used to
treat infection sites.
A pre-prepared composition containing chloride ions (0.1-10,000mg) allowed to react
fully with glucose (0.01 – 100,000 mg) and glucose oxidase (0.1-1,000,000 Units) in the
presence of chloroperoxidase (0.01 – 1,000,000 Units). The composition is catalase
treated (0.01 – 1,000,000 Units) to remove excess hydrogen peroxide, before the
composition is used to treat infection sites.
A pre-prepared composition containing thiocyanate/iodide ions (0.1-10,000mg) allowed
to react fully with glucose (0.01 – 100,000 mg) and glucose oxidase (0.1-1,000,000
Units) in the presence of lactoperoxidase (0.01 – 1,000,000 Units). The composition is
catalase treated (0.01 – 1,000,000 Units) to remove excess hydrogen peroxide, before
the composition is used to treat infection sites.
The above pre-prepared solutions supplemented with lactoferrin (0.001 mg -10,000 mg),
prednisone (0.001 mg -10,000 mg), or prednisolone (0.001 mg -10,000 mg), either
individually or a combination of two or more.
The words “comprises/comprising” and the words “having/including” when used herein
with reference to the present invention are used to specify the presence of stated
features, integers, steps or components but does not preclude the presence or addition of
one or more other features, integers, steps, components or groups thereof.
It is appreciated that certain features of the invention, which are, for clarity, described in
the context of separate embodiments, may also be provided in combination in a single
embodiment. Conversely, various features of the invention which are, for brevity,
described in the context of a single embodiment, may also be provided separately or in
any suitable sub-combination.
In this specification where reference has been made to patent specifications, other
external documents, or other sources of information, this is generally for the purpose of
providing a context for discussing the features of the invention. Unless specifically
stated otherwise, reference to such external documents is not to be construed as an
admission that such documents, or such sources of information, in any jurisdiction, are
prior art, or form part of the common general knowledge in the art.
Claims (33)
1. A microbiocidal composition comprising a reactive oxygen species selected from the group consisting of hypothiocyanate (hypothiocyanite, SCNO ), hypoiodate 5 (IO ) and hypochlorite (CLO ), the composition being capable of delivering the reactive oxygen species to a level of at least 0.4 millimoles per litre, over a 24 hour period.
2. A composition as claimed in claim 1 capable of delivering the reactive oxygen species to a level of at least 0.5 millimoles per litre, over a 24 hour period.
3. A composition as claimed in claim 1 or 2 wherein the reactive oxygen species is produced by the reaction of a peroxidase, a substrate for the peroxidase and hydrogen peroxide. 15
4. A composition as claimed in claim 3,wherein the peroxidase enzyme is selected from the group comprising a lactoperoxidase, a chloroperoxidase, a bromoperoxidase and an iodooxidase.
5. A composition as claimed in claim 4 comprising a lactoperoxidase enzyme and 20 further comprising iodide or thiocyanate ions.
6. A composition as claimed in claim 4 comprising a chloroperoxidase enzyme and further comprising chloride ion. 25
7. A composition as claimed in any of claims 3 to 6 where the source of hydrogen peroxide is a solution of the hydrogen peroxide.
8. A composition as claimed in any one of claims 3 to 7 where the hydrogen peroxide is released by a hydrogen peroxide releasing compound selected from the 30 group comprising percarbonates, citric acid and perhydrates, or by enzymatic methods.
9. A composition as claimed in any of claims 3 to 8 where the hydrogen peroxide is produced by an enzymatic reaction between a sugar and its appropriate oxidoreductase.
10. A composition as claimed in claim 9 wherein the oxidoreductase is galactose oxidase and/or glucose oxidase. 5
11. A composition as claimed in claim 10 further comprising free monosaccharide sugar(s).
12. A composition as claimed in any of claims 3 to 11 further comprising a disaccharide sugar, and its corresponding glycoside hydrolase to produce a source of 10 hydrogen peroxide.
13. A composition as claimed in claim 12 wherein the glycoside hydrolase is Beta- galactosidase, and the disaccharide sugar is lactose. 15
14. A composition as claimed in any preceding claim wherein a glycoside hydrolase and/or an oxidoreductase is adapted to react with sugars present at the infection site.
15. A composition as claimed in claim 9 wherein the additional source of hydrogen peroxide is derived from the reaction of a polyol (sugar alcohol) with its relative oxidase 20 enzyme.
16. A composition as claimed in claim 15 wherein the polyol is glycerol and its relative oxidase enzyme is glycerol oxidase, or wherein the polyol is mannitol and its relative oxidase enzyme is mannitol oxidase.
17. A composition as claimed in any of claims 3 to 16 wherein the hydrogen peroxide is produced from the enzymatic reaction of L-amino acids with L-amino acid oxidase or xanthine (or hypoxanthine) and xanthine oxidase. 30
18. A composition as claimed in any preceding claim further comprising either hypoxanthine or xanthine or both.
19. A composition as claimed in claim 18 further comprising free amino acids.
20. A composition claimed in any preceding claim additionally comprising lactoferrin, or a glucocorticoid. 5
21. A composition claimed in claim 20 wherein the glucocorticoid is prednisolone or prednisone.
22. A composition as claimed in any preceding claim adapted for intramammary infusion or nebulisation, for use as an antimicrobial solution, emulsion or dried product, 10 for use as an antimicrobial solution to be added to a poultice for a burn lesion to the skin, for use as an antimicrobial solution to be used as a nasal rinse, for use as an antimicrobial solution to be used as a surface cleaner.
23. An intramammary infusion delivery device loaded with a composition as 15 claimed in any preceding claim.
24. A composition as claimed in any one of claims 1 to 22, where the solution is prepared as an emulsion, or dried product. 20
25. A composition as claimed in any one of claims 1 to 22 and 24 wherein the compounds are adhered to the surface of a medical device.
26. A composition as claimed in any any one of claims 1 to 22, 24 and 25 where the components are adapted for delivery sequentially or cumulatively to the infection site.
27. A composition as claimed in any one of claims 1 to 22 and 24 to 26 where the components are allowed to react before addition to the infection site.
28. A composition as claimed in any one of claims 1 to 22 and 24 to 27 where the 30 components are allowed react before addition to the infection site, and treated with catalase to remove excess hydrogen peroxide.
29. Use of a reactive oxygen species selected from the group consisting of - - - hypothiocyanate (hypothiocyanite, SCNO ), hypoiodate (IO ) and hypochlorite (CLO ), in the manufacture of a medicament for the treatment of microbial infections, wherein the medicament is capable of delivering the reactive oxygen species to a level of at least 5 0.4 millimoles per litre, over a 24 hour period.
30. A use as claimed in claim 29 wherein the medicament is adapted for intramammary infusion or nebulisation, for use as an antimicrobial solution, emulsion or dried product, for use as an antimicrobial solution to be added to a poultice for a burn 10 lesion to the skin, for use as an antimicrobial solution to be used as a nasal rinse, or for use as an antimicrobial solution to be used as a surface cleaner.
31. A microbiocidal composition as claimed in any one of claims 1 to 22 and 24 to 28, substantially as herein described with reference to any example thereof.
32. An intramammary infusion delivery device as claimed in claim 23 substantially as herein described with reference to any example thereof.
33. A use as claimed in claim 29 or claim 30 substantially as herein described with 20 reference to any example thereof.
Applications Claiming Priority (3)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| EP11162678.4 | 2011-04-15 | ||
| EP11162678A EP2510944A1 (en) | 2011-04-15 | 2011-04-15 | Treatment of bacterial infections |
| PCT/EP2012/056946 WO2012140272A1 (en) | 2011-04-15 | 2012-04-16 | Treatment of microbial infections |
Publications (2)
| Publication Number | Publication Date |
|---|---|
| NZ616550A NZ616550A (en) | 2016-04-29 |
| NZ616550B2 true NZ616550B2 (en) | 2016-08-02 |
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