AU2005235588B2 - Methods of inhibiting microorganism growth using moss and devices for water treatment - Google Patents

Description

WO 2005/102935 PCT/US2005/012915 METHODS OF INHIBITING MICROORGANISM GROWTH USING MOSS AND DEVICES FOR WATER TREATMENT Field of the Invention This invention relates to methods of inhibiting microorganism growth and to methods of water treatment using moss, particularly sphagnum moss. Background of the Invention Various biological control agents are known in the art for the control of microorganism growth. For example, it is desirable to inhibit fungal growth in food products, such as when grain is stored, and to inhibit bacterial growth in packaged foods, such as raw chicken. In other fluid absorbing products such as bandages or feminine hygiene products, it is desirable to include antimicrobial compositions so that pathological organisms cannot flourish. Water treatment is another area in which chemical, biological, and radiation treatments have been used to control or prevent bacterial growth. There are many types of water treatment systems, such as filtration and cleaning systems for swimming pools and aquariums. Many of these systems filter the water to remove suspended matter and reduce the cloudy appearance of the water. Preventing bacterial growth in water and removing contaminants from water are significant industrial, as well as household, problems. For example, industrial effluent should be cleaned to remove toxic compounds as well as to remove bacteria before it is dumped into lakes and rivers. Containers of water such as swimming pools, hot tubs, aquariums and the like must be kept clean to prevent the water from becoming cloudy and/or the container walls from becoming slimy. The water may be treated by active means such as a filter to remove particles and bacteria, and it may also be treated by passive means whereby a biocide is placed in a container and floated in the water.

WO 2005/102935 PCT/US2005/012915 It is common to use chemical means to keep the water clean and reduce bacterial growth. Ultraviolet light, chlorination, bromination, treatment with ions of copper and silver as well as treatment with ozone can be used to treat and/or disinfect water. These are typical biocides, that is, substances or energies that 5 destroy living organisms. Of course care must be taken with all these methods because of the possible toxicity or damage to the user. Chemicals require careful handling to avoid environmental contamination as well as contact with the user. "Sphagnum moss" is a generic expression that designates a range of botanical species that co-exist in a sphagnous bog. It should be noted that "peat 10 moss" refers generally to a decomposed or composted sphagnum moss. Sphagnum moss is commonly harvested for use in various products. The petals, and not the stems, of the moss preferably may be harvested. Typically large pieces of plant material (roots, twigs, etc.) are removed and the moss may be processed further after harvesting by forming an aqueous slurry to extract very fine particles. 15 Water is removed from the slurry and the moss is dried. The moss may be compressed prior to packaging or shipment. Various additives may be used to alter the absorption characteristics or mechanical properties of the moss. Because sphagnum moss is readily available and relatively inexpensive, it has been used in a variety of products, primarily for the absorption of fluids. 20 There is substantial need in the art for products that inhibit the growth of microorganisms such as bacteria, yeast, and algae. It would be desirable to have a means to maintain the clarity of water in a swimming pool, whirlpool bath, aquarium, and the like, for long periods of time, without shutting a system down for cleaning. The most desirable system would require very little maintenance and 25 would be relatively inexpensive. Summary of the Invention The invention provides a method of inhibiting microorganism growth comprising contacting a substance susceptible to microorganism growth with an 2 -3 amount of a non-decomposed moss effective to inhibit microorganism growth, wherein the moss is selected from the group consisting of sphagnum papillosum, sphagnum cristatum, and mixtures thereof. In one embodiment the invention provides a method of inhibiting microorganism 5 growth comprising contacting water susceptible to microorganism growth with an amount of a non-decomposed moss effective to inhibit microorganism growth, wherein the moss is selected from the group consisting of sphagnum papillosum, sphagnum cristatum, and mixtures thereof, and wherein the water is water in a spa, in a pool, or in an aquarium. The invention provides a method of inhibiting microorganism growth comprising to placing an amount of a non-decomposed moss effective to inhibit microorganism growth in a carrier and contacting the carrier with a substance susceptible to microorganism growth, wherein the moss is selected from the group consisting of sphagnum papillosum, sphagnum cristatum, and mixtures thereof. The invention provides a method of preparing moss for use in inhibiting is microorganism growth comprising: (i) drying non-decomposed moss; and (ii) sterilizing the moss. The invention provides a method of preparing moss for use in inhibiting bacterial growth comprising: (i) contacting non-decomposed moss with an acidic solution; and (ii) drying the moss. The invention provides a kit comprising sterilized, non decomposed moss and a carrier. 20 The invention provides a method of inhibiting microorganism growth comprising contacting water susceptible to microorganism growth with an amount of a non decomposed moss effective to inhibit microorganism growth, wherein the moss is selected from the group consisting of sphagnum papillosum, sphagnum cristatum, and mixtures thereof, and periodically shocking the water with an appropriate chemical agent. 25 The invention provides a method of treating water comprising contacting water with an amount of a non-decomposed moss effective to remove cations other than hydrogen ions from the water, wherein the moss is selected from the group consisting of sphagnum papillosum, sphagnum cristatum, and mixtures thereof.

WO 2005/102935 PCT/US2005/012915 The invention provides a device for use in water comprising: (i) a carrier having an interior cavity and one or more openings allowing ingress to and egress from the interior cavity; and (ii) a moss contained within the interior cavity, wherein the carrier completely encloses the moss. 5 The invention provides a method of inhibiting microorganism growth comprising placing in water susceptible to bacterial growth a device for inhibiting microorganism growth in water, the device comprising: (i) a carrier having an interior cavity and one or more openings allowing ingress to and egress from the interior cavity; and (ii) a moss contained within the interior cavity, wherein the 10 carrier completely encloses the moss, and wherein the device comprises an amount of the moss effective to inhibit microorganism growth in the water. The invention provides a kit comprising sterilized, non-decomposed moss and a device for use in water comprising a carrier having an interior cavity and one or more openings allowing ingress to and egress from the interior cavity, wherein 15 the interior cavity can completely enclose the moss. The invention provides a method of inhibiting microorganism growth comprising placing in water susceptible to microorganism growth a device for inhibiting microorganism growth in water, the device comprising: (i) a carrier having an interior cavity and one or more openings allowing ingress to and egress 20 from the interior cavity; and (ii) a moss contained within the interior cavity, wherein the carrier completely encloses the moss, wherein the device comprises an amount of the moss effective to inhibit microorganism growth in the water, and periodically shocking the water with an appropriate chemical agent. The invention provides a method of treating water comprising placing in 25 water a device comprising: (i) a carrier having an interior cavity and one or more openings allowing ingress to and egress from the interior cavity; and (ii) a moss contained within the interior cavity, wherein the carrier completely encloses the moss, and wherein the device comprises an amount of the moss effective to remove cations other than hydrogen ions from the water. 4 WO 2005/102935 PCT/US2005/012915 It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are intended to provide further explanation of the invention as claimed. 5 Brief Description of the Drawings Figure 1A illustrates a perspective view of one embodiment of a device that can be used in the invention. Figure 1B illustrates a side view, and FIG. IC illustrates a cross-sectional view along line C-C of Figure 1B. Figure 2A illustrates a perspective view of another embodiment of a device 10 that can be used in the invention and Figure 2B shows a side view of the moss used within the device shown in Figure 2A. Figure 3 illustrates a perspective view of another embodiment of a device that can be used in the invention. 15 Detailed Description of the Preferred Embodiments We have discovered species of sphagnum moss that can be used to inhibit microorganism growth. The moss can be used to control microorganism growth in water such as in a swimming pool, spa, aquarium, and the like. Spas are also known as whirlpools or hot tubs. It is believed that particular species of moss are 20 particularly effective at inhibiting and/or preventing the growth of bacteria and other microorganisms. In this invention, "bacteriostatic" refers to a material that inhibits the growth of bacteria. In common lexicography, the term "antibacterial" generally refers to a bacterial growth inhibitor. Both terms should be distinguished from 25 "bactericidal" which refers to materials that kill bacteria upon contact. In this invention, "water treatment" refers to a process by which water is kept clean, clear, and pleasant smelling in swimming pools, aquariums, whirl pool baths, hot tubs, and the like. When the water is agitated, less foaming is observed. 5 WO 2005/102935 PCT/US2005/012915 The moss is believed to inhibit growth of bacterial and other microorganisms and it also may absorb compounds and substances that decrease water clarity. In this invention, sphagnum papillosum (S. papillosum) and/or sphagnum cristatum (S. cristatum) can be used in water treatment devices. In preferred 5 embodiments, the moss is enclosed or encapsulated in a mesh material that prevents the moss from disintegrating in an aqueous environment. Thus the moss can be held in a desired place in a pool, hot tub, whirlpool bath, and the like. Preferred mesh materials include those comprising polymers such as nylon or polypropylene, with mesh sizes ranging from about 0.1 to 1 mm. Polymers are 10 generally preferred because they are inexpensive and may be resistant to degradation. Suitable for use in this invention are S. papillosum, which can be harvested from bogs in northern Minnesota, U.S.A., and S. cristatum, which is commercially available as a compressed bale from Sutton's Moss of Dobson, Westland, New 15 Zealand. These species of moss can be used by themselves or together in the devices and systems of this invention. Typically and preferably the moss is cleaned to remove small particles, such as dirt, and larger debris, such as roots and leaves. Commercially available moss may be fumigated before it is packaged by a manufacturer in order to destroy seeds. 20 In a preferred embodiment, the moss is cut by mechanical means into a desired size and shape. The moss preferably is then sterilized by autoclaving, exposure to ethylene oxide, or by other means known to one of skill in the art. Sterilization destroys living organisms in the moss and thus avoids any problems of undesirable or foreign bacteria being introduced into the environment where a 25 device of this invention is used. The moss is then ready for use in a water treatment system or other applications. We have found that a convenient, easy, effective, and inexpensive way of treating water is to place a portion of S. papillosum or S. cristatum in a floatation device that permits water to flow around and through the moss. Another way to 6 WO 2005/102935 PCT/US2005/012915 use it is to encapsulate it in mesh and weight the mesh so that the moss will remain in the water. Any suitable means that will maintain contact of the moss with water is suitable for use. This device is then placed in the swimming pool, whirlpool, hot tub, etc., where it can come into contact with the water. We have found that 5 treatment is remarkably effective in preventing bacterial growth and in keeping the water clean, clear and free of odor and foam. This is all the more remarkable because this is a passive system when compared to a filtration system which forces water through the moss. Of course it is to be understood that active filtration could be done with the device of this invention to treat the water. 10 When used in swimming pools, hot tubs, and the like, the water treatment devices described herein are preferably used in conjunction with materials that kill bacteria. This is because these environments may have large bacteria loads introduced at various times. Accordingly, standard practice is to filter the water, flush water lines, and test the water as necessary. The pH can be adjusted by using 15 commercially available solutions. The water treatment devices of this invention are most desirably used in conjunction with an oxidizer, such as potassium monopersulfate, referred to as "chlorine free shock". Potassium monopersulfate is known to increase the efficiency of chlorine purification products, but we have found that it is also particularly effective when used with the sphagnum moss 20 devices described above. The sphagnum moss of this invention can be used in any composition, material, device, or method where the inhibition of microorganisms is desirable. Uses include the inhibition of microorganism growth, the reduction and/or prevention of odors, water treatment, and control of mold and fungal growth; and 25 control of fermentation. Such devices and materials include absorbent products, such as diaper liners, feminine hygiene products, bandages, and wound dressings. In such products, the moss can be enclosed between membranes of differing liquid transmission characteristics. That is, for example, one membrane may be permeable to fluid and another membrane may be permeable to vapor. The moss 7 WO 2005/102935 PCT/US2005/012915 can be incorporated into polymers and used as face masks. The moss can be encapsulated in membranes and used in food preservation products such as packaging wraps and liners to absorb liquid and odors. The moss can be used in water treatment products to keep water clean in storage tanks, aquariums, 5 swimming pools, whirlpool baths, spas, and the like, as well as in water filtration devices. The moss can be used for waste water and sewage treatment. The moss can be shaped into, for example, discs or pellets, and used to absorb water from grain and other food products. The moss also can be used for fermentation control (such as in liquids or grains). The moss can be used for the control of fungal or 10 microorganism diseases in lawns and gardens. The moss can be used for mold control products such as in storage containers or ductwork linings. The invention provides a method of inhibiting microorganism growth comprising contacting a substance susceptible to microorganism growth with an amount of a non-decomposed moss effective to inhibit microorganism growth, 15 wherein the moss is selected from the group consisting of sphagnum papillosum, sphagnum cristatum, and mixtures thereof. The moss can be compressed and can be in the form of strips. The moss can be sterilized by autoclaving, sterilized by chemical treatment, or sterilized by treatment with ethylene oxide. The moss can be washed with an acidic solution, especially a solution of acetic acid. The moss 20 can be washed with an acidic solution and then washed with a salt solution. The substance susceptible to microorganism growth can be water. The water can be in a spa, pool, or aquarium. The substance susceptible to microorganism growth can be a portion of the human body such as skin, a surface wound, an internal body cavity, or the site of an internal injury. The substance 25 susceptible to microorganism growth can be grain. The invention provides a method of inhibiting microorganism growth comprising placing an amount of a non-decomposed moss effective to inhibit microorganism growth in a carrier and contacting the carrier with a substance susceptible to microorganism growth, wherein the moss is selected from the group 8 WO 2005/102935 PCT/US2005/012915 consisting of sphagnum papillosum, sphagnum cristatum, and mixtures thereof. The carrier can be a device that is implanted into the human body, a polymer matrix, a biomatrix, or one or more membranes. The invention provides a method of preparing moss for use in inhibiting 5 microorganism growth comprising: (i) drying non-decomposed moss; and (ii) sterilizing the moss. The method can further comprising compressing the moss, compressing the moss and cutting the moss into strips, sterilizing the moss by autoclaving, chemical treatment, or treatment with ethylene oxide. The moss can be sphagnum moss. The moss can be selected from the group consisting of 10 sphagnum papillosum, sphagnum cristatum, and mixtures thereof. The invention provides a method of preparing moss for use in inhibiting bacterial growth comprising: (i) contacting non-decomposed moss with an acidic solution; and (ii) drying the moss. The method can comprise contacting the non decomposed moss with a salt solution after step (i). In one embodiment, the acidic 15 solution is a solution of acetic acid. The moss can be sphagnum moss. The moss can be selected from the group consisting of sphagnum papillosum, sphagnum cristatum, and mixtures thereof. The invention provides a kit comprising sterilized, non-decomposed moss and a carrier. The moss can be compressed and can be in the form of strips. 20 The invention provides a method of inhibiting microorganism growth comprising contacting water susceptible to microorganism growth with an amount of a non-decomposed moss effective to inhibit microorganism growth, wherein the moss is selected from the group consisting of sphagnum papillosum, sphagnum cristatum, and mixtures thereof, and periodically shocking the water with an 25 appropriate chemical agent. The chemical agent can be potassium monopersulfate. The invention provides a method of treating water comprising contacting water with an amount of a non-decomposed moss effective to remove cations other than hydrogen ions from the water, wherein the moss is selected from the group consisting of sphagnum papillosum, sphagnum cristatum, and mixtures thereof. 9 WO 2005/102935 PCT/US2005/012915 The cations can be calcium or iron ions, and substantially all of the calcium or iron ions can be removed from the water. The moss can be compressed and can be in the form of strips. The moss can be sterilized by autoclaving, sterilized by chemical treatment, or sterilized by treatment with ethylene oxide. The moss can 5 be washed with an acidic solution, especially a solution of acetic acid. The moss can be washed with an acidic solution and then washed with a salt solution. The water can be in a spa, pool, or aquarium. The invention provides a method of treating water comprising placing in a carrier an amount of a non-decomposed moss effective to remove cations other 10 than hydrogen ions from the water and contacting the carrier with water, wherein the moss is selected from the group consisting of sphagnum papillosum, sphagnum cristatum, and mixtures thereof. The invention provides a device for use in water comprising: (i) a carrier having an interior cavity and one or more openings allowing ingress to and egress 15 from the interior cavity; and (ii) a moss contained within the interior cavity, wherein the carrier completely encloses the moss. The carrier can comprise a float. The carrier can comprise a float and a cylindrical portion beneath the float, the cylindrical portion having an interior cavity and one or more openings allowing ingress to and egress from the interior cavity. The moss can be enclosed within a 20 mesh bag. The carrier can comprise one or more weights. The moss can be non-decomposed moss. The moss can be sphagnum moss. The moss can be selected from the group consisting of sphagnum papillosum, sphagnum cristatum, and mixtures thereof. The moss can be compressed and can be in the form of strips. The moss can be sterilized by autoclaving, sterilized by 25 chemical treatment, or sterilized by treatment with ethylene oxide. The moss can be washed with an acidic solution, especially a solution of acetic acid. The moss can be washed with an acidic solution and then washed with a salt solution. The invention provides a method of inhibiting microorganism growth comprising placing in water susceptible to microorganism growth a device for 10 WO 2005/102935 PCT/US2005/012915 inhibiting microorganism growth in water, the device comprising: (i) a carrier having an interior cavity and one or more openings allowing ingress to and egress from the interior cavity; and (ii) a moss contained within the interior cavity, wherein the carrier completely encloses the moss, and wherein the device 5 comprises an amount of the moss effective to inhibit microorganism growth in the water. The water can be in a spa, pool, or aquarium. The water can be pumped through the device. The invention provides a kit comprising sterilized, non-decomposed moss and a device for use in water comprising a carrier having an interior cavity and one 10 or more openings allowing ingress to and egress from the interior cavity, wherein the interior cavity can completely enclose the moss. The kit can comprise one or more pH test strips and/or potassium monopersulfate. The invention provides a method of inhibiting microorganism growth comprising placing in water susceptible to microorganism growth a device for 15 inhibiting microorganism growth in water, the device comprising: (i) a carrier having an interior cavity and one or more openings allowing ingress to and egress from the interior cavity; and (ii) a moss contained within the interior cavity, wherein the carrier completely encloses the moss, wherein the device comprises an amount of the moss effective to inhibit microorganism growth in the water, and 20 periodically shocking the water with an appropriate chemical agent. The chemical agent can be potassium monopersulfate. The invention provides a method of treating water comprising placing in water a device comprising: (i) a carrier having an interior cavity and one or more openings allowing ingress to and egress from the interior cavity; and (ii) a moss 25 contained within the interior cavity, wherein the carrier completely encloses the moss, and wherein the device comprises an amount of the moss effective to remove cations other than hydrogen ions from the water. The cations can be calcium or iron ions, and substantially all of the calcium or iron ions can be removed from the water. The moss can be compressed and can be in the form of strips. The moss 11 WO 2005/102935 PCT/US2005/012915 can be sterilized by autoclaving, sterilized by chemical treatment, or sterilized by treatment with ethylene oxide. The moss can be washed with an acidic solution, especially a solution of acetic acid. The moss can be washed with an acidic solution and then washed with a salt solution. The water can be in a spa, pool, or 5 aquarium. Figures 1 A to 1 C illustrate a suitable device of this invention. Figure 1A shows device 10 floating in water and Figures 1B and 1C shows side and cross sectional views, respectively. Device 10 is adapted to receive a segment of compressed sphagnum moss 15 that has been cut into a desired dimension. The 10 moss is shown in phantom in Figure 1A and 1B. A convenient dimension for the moss used in device 10 is about 6 x 1/4 x inches (15.2 x 0.63 x 0.63 cm). A piece of moss this size weighs about 5 grams. Moss 15 is enclosed in nylon mesh 16, sized to permit the compressed moss to expand. The mesh size is such that it will retain even small particles of moss and prevent it from breaking apart and floating 15 away. Device 10 comprises a plastic material that is impact resistant, does not dissolve in water, and can be shaped into a desired shape. Device 10 is commercially available as a "floater" from MP Industries of Huntington Beach, CA. It should be noted that floaters of this type are commonly used with pellets or 20 discs of pool cleaning agents, such as those containing chlorine. Device 10 has been adapted for use with sphagnum moss by adding holes to facilitate passage of water into the device. Device 10 comprises float portion 20 and flow through portion 30. Float portion 20 is cylindrical, and may be any desired dimension, though typically it is 25 larger in diameter than flow-through portion 30. A useful dimension for the float portion is about 5 inches (12.7 cm) in diameter. Flow-through portion 30 is a two-part elongated cylinder having core or hollow center 32. First part 33 is attached to floatation portion 20 and is provided with screw threads onto which second part 35 affixes. In this way the length of the 12 WO 2005/102935 PCT/US2005/012915 flow-through portion can be changed. Second part 35 is fixed in position by means of adjustable collar 34. Second part 35 also has removable cap 37, which is weighted so that device 10 floats in the water as illustrated in Figure 1. Slots 38 and holes 39 permit water to flow through the cylinder. The slots 5 and holes may be any desired dimension and can be positioned as desired. A useful length of the flow through portion is about 7 inches (17.8 cm). Cap 37 is removable so that the desired size of the sphagnum moss can be inserted into portion 30. Once exposed to water, the compressed moss expands. The density of expanded moss is such that water can flow through it. Device 10 is sufficient to 10 treat up to about 350 gallons of water (for example, in a whirlpool or spa) for up to 30 days. Figure 2A illustrates device 50 floating in water. Device 50 comprises cylindrical portion 60 having core or hollow center 62. Slots 64 and holes 66 permit water to enter the hollow center. Moss 55, shown in phantom in Figure 2A, 15 is encapsulated by mesh 52, as most clearly shown in Figure 2B. The moss expands when in contact with the water, filling hollow center 62. Cylindrical portion 60 is shown sealed at one end, with removable cap 57 at the other end. Cap 57 may be weighted so that the maximum length of device 60 stays in contact with the water. 20 Figure 3 shows device 70 attached to wall W of a swimming pool, aquarium, hot tub, or the like. Moss 75 is encapsulated by mesh 72 and the mesh is affixed to bracket 77. The mesh is of a sufficient size that particles or fragments of moss will stay within the mesh. The bracket hangs from the wall and the device can remain fixed at this location. Alternatively, device 70 could lie on the bottom 25 of the pool or tub. It could be affixed there or could be held down by a weight. It also could be placed in-line with a filter. 13 WO 2005/102935 PCT/US2005/012915 EXAMPLES Example 1 S. papillosum moss, harvested from northern Minnesota, and was prepared 5 for bacterial inhibition testing. The moss species was validated by the University of Minnesota and again upon receipt. All samples were placed in plastic bags. All raw moss was stored at 4'C until processed by lab personnel. All pre-dried outside moss samples were stored at room temperature until processed. 10 The following equipment was used: a) Blender, 1.25 L capacity (commercially available as Osterizer@ from Oster) b) Distilled Water (available from Premium Water, Inc.) c) Tissue Sieve, 1 cup capacity (commercially available as Cellector@ E-C Apparatus Corp.) 15 d) 1 L Glass Beaker (commercially available as Pyrex@) e) Sterile Polystyrene Petri Dishes 100 x 15 mm (commercially available from Falcon) f) Sterile Polystyrene Petri Dishes 150 x 15 mm (commercially available from VWR) 20 g) Autoclave (commercially available from Market Forge) h) Metal Lab Scoop (16.5cm) / commercially available as Adison Tissue Forceps from VWR) i) Laminar Flow Hood (commercially available from Baker) 25 Procedure: 1) Raw moss was taken out of the bag by hand and picked clean of any visible, roots, leafs and debris and placed in the blender. The blender was then filled with moss until it reached approximately the 1 L mark. 14 WO 2005/102935 PCT/US2005/012915 2) The blender was then filled with 1 L of distilled water and shaken manually with the lid on for 30 seconds and drained to remove any remaining dirt and debris. The process was repeated 2 more times to thoroughly wash the moss. 3) The blender was then filled with distilled water again and the moss was 5 blended using the pulse mode on settings 4 and 5 for 30 seconds each until the moss was homogenized throughout the sample. 4) The blender was then drained of water. Any remaining water was then squeezed out by hand from the moss using the tissue sieve. The squeezed moss was then placed in a clean 1L beaker. Steps 1 to 4 were repeated until the 1L 10 beaker was filled with processed moss. The beaker was then autoclaved for 20 minutes at 121' C at 15 psi (103.4 MPa) using the liquid setting and allowed to cool at room temperature. 5) Once cooled, the moss was brought to the laminar flow hood and carefully placed in labeled, pre-weighed Petri dishes using a sterile lab scoop and forceps. 15 Special care was taken not contaminate the moss and to pack each dish in a uniform manner. Once packed, the dishes remain uncovered for at least 72 hours until the moss was dry. The dried dishes were covered and kept in the flow hood until used. 20 Example 2 S. cristatum moss, obtained from Sutton's Moss, Canada, (harvested in New Zealand) was prepared for bacterial inhibition testing. The moss species was validated upon receipt. Handling of the moss samples was identical to that described above in Example 1. 25 The following equipment was used: a) Sterile syringes, individually wrapped 30 cc or 60 cc (commercially available from Becton Dickenson) b) Sterile syringe filters, 0.45 ptm (micrometer) and 0.20 ptm (commercially available as Acrodisc from Pall Gellman) 15 WO 2005/102935 PCT/US2005/012915 c) Adison tissue forceps (commercially available from VWR) d) 50cc polypropylene graduated test tubes, sterile pack (commercially available from Falcon) e) Wax film (Parafilm@, commercially available from American National 5 Can) f) Laminar flow hood (commercially available from Baker Company) g) Pipetman with sterile graduated polypropylene tips, 25mL (commercially available from Becton Dickenson) h) 10 M HCl and 10 M NaOH 10 i) pH Meter (commercially available from Beckman Omega 40) Reagents and Solutions Preparations: (Depending on liquid used for treatment) a) BactoTM Tryptic Soy Broth, 30g/L (Becton Dickenson) / MEM-Alpha (Gibco) 15 b) Phosphate Buffered Saline (lx), pH 7.1 (commercially available from Gibco

TM

) c) HPLC Grade Water (commercially available from J.T. Baker) Procedure 20 a) All liquids used for treatment were either autoclaved or filter sterilized and stored at a proper temperature prior to use in this protocol. All treatment steps were done with in the laminar flow hood using aseptic technique. Tissue forceps used were autoclaved prior to use. b) After weighing the dried moss, the treatment liquid was pipetted into the 25 Petri dish at a concentration of one milliliter of treatment liquid to every 50 mg dried moss. If a concentration other that 50mg/mL was used, the process changed accordingly. c) The Petri dish of moss was wrapped in wax film (Parafilm@) and refrigerated at 4'C for one hour. 16 WO 2005/102935 PCT/US2005/012915 d) The Petri dish was removed from the refrigerator and the moss was scooped and packed into a 30cc or 60cc syringe using sterile tissue forceps. The plunger of the syringe was re-inserted and the liquid was squeezed into a sterile 50 mL polypropylene test tube until all possible liquid was extracted. 5 e) The extract liquid was filtered through a 0.45 pim syringe filter, then a 0.2 pm syringe filter and stored at 4'C until used. f) Filtered samples were pH adjusted using 1.0 M HC1/ NaOH and were sterile filtered with a 0.2 pm syringe filter and stored again at 4'C until used in the bacteria inhibition assay. 10 Example 3 This experiment determined the amount of bacterial growth in Tryptic Soy Broth (TSB) by an inhibition assay. All S. papillosum and S. cristatum moss extracts used in this assay were 15 prepared as described above. TSB was also prepared, autoclaved and stored at 4'C prior to use. The following equipment was used: a) Beckman@ DU-64 Spectrophotometer b) Incubator Oven (commercially available from Boekel Instruments Model 20 #133000) c) 5 mL and 50mL Polystyrene Tubes (commercially available from Falcon) d) 10pL and 1 mL polypropylene tips (commercially available from Pipetman) Reagents and Solutions: 25 a) Bacto@ Tryptic Soy Broth (TSB), 30 g/L (commercially available from Becton Dickenson) b) Escherichia Coli frozen culture stock grown in TSB for a minimum of 3 log growth phases (Clinical isolate) 17 WO 2005/102935 PCT/US2005/012915 c) Staphylococcus Aureus frozen culture stock grown in TSB for a minimum of 3 log growth phases. (ATCC Strain #29213 (American Type Culture Collection of Manassas, VA)) d) Distilled Water (commercially available from Premium Water Inc.) 5 e) TSB extract of S. papillosum moss and New Zealand moss Procedure: 1) TSB nutrient broth was prepared by adding 30 g/L Bacto@ Tryptic Soy Broth to distilled water. The solution was stirred with a stir-bar until all the powder 10 was dissolved and autoclaved at 121'C for 20 minutes. S. papillosum extract was prepared as described in B, above. One mL of the solutions, TSB or moss-treated TSB sample, was pipetted into 3 to 5 mL polystyrene test tubes. 2) Frozen aliquots ofE. coli and S. aureus stored at -20'C were allowed to thaw to room temperature. Once thawed, 100 iL of each bacterial stock was 15 added to a 10 mL aliquot of TSB. Each tube was then capped, thoroughly mixed, labeled and placed in the incubator at 37 0 C. 3) Ten pL of bacteria stock was pipetted into the one mL solutions and the tubes were incubated at 37'C for the desired time. One tube in each sample and time point did not receive bacteria in order to serve as the blank. 20 4) The solutions were removed from the 37'C oven at the assigned time points and placed in an ice bath. Samples were then immediately read on the spectrophotometer at 550 nm. The absolute OD value was sample minus the blank. Inhibition was measured as percent decrease in OD value vs. the appropriate TSB control sample. 25 Example 4 The following data illustrate the effect of treatment of bacterial growth media (i.e., Tryptic Soy Broth) with various moss species according to the procedure in Example 3. Non-sphagnum species are very poor at preventing E. 18 WO 2005/102935 PCT/US2005/012915 coli growth. Of the moss tested below, the most effective sphagnum mosses to prevent E. coli growth were S. papillosum and S. cristatum. "N" refers to the number of tests, "Range" presents the highest and lowest numbers obtained for these tests; and "Mean" refers to the mean value of the tests. 5 Sphagnum Species % Inhibition of Bacterial Growth Mean N Range S. papillosum (MN) 48 10 26-71 S. cristatum (NZ- Sutton Moss) 45 8 31-62 10 S. magellanicum (WI - Mosser Lee) 34 7 21-43 S. fuscum (MN) 20 1 S. falcatulurn (NZ) 7 2 2-11 Non- Sphagnum Species 15 Sheet Moss (WI - Mosser Lee) 4 1 Spanish Moss (WI - Mosser Lee) -2 1 Example 5 TSB was treated with S. papillosum and the ability of this solution to 20 support bacterial growth was measured according to Example 3. The percent inhibition of bacterial growth for E. coli (clinical isolate) and S. aureus (ATCC Strain # 29213) is reported. A TSB Control sample and moss-treated TSB solutions (MT-TSB) are reported below. The OD of a blank (B) is subtracted from the measured OD (Meas.) of the sample to obtain the reported Value. 25 Test Material E. coli S. aureus B Meas. Value B Meas. Value TSB 0.063 0.744 0.681 0.063 0.250 0.187 (Control) 0.726 0.663 0.257 0.194 19 WO 2005/102935 PCT/US2005/012915 Mean 0.672 0.191 SD 0.013 0.005 MT-TSB 0.109 0.662 0.553 0.109 0.279 0.170 5 (5 mg/mL) 0.714 0.605 0.285 0.176 Mean 0.579 0.173 SD 0.037 0.004 % Inhibition 13.84 9.19 10 MT-TSB 0.131 0.575 0.444 0.131 0.278 0.147 (10 mg/mL) 0.748 0.617 0.274 0.143 Mean 0.531 0.145 SD 0.122 0.003 % Inhibition 21.06 23.88 15 MT-TSB 0.173 0.662 0.489 0.173 0.276 0.101 (25 mg/niL) 0.652 0.479 0.284 0.111 Mean 0.484 0.107 SD 0.007 0.006 20 % Inhibition 27.98 43.83 MT-TSB 0.243 0.599 0.356 0.243 0.355 0.112 (50 mg/mL) 0.564 0.321 0.352 0.109 Mean 0.339 0.111 25 SD 0.025 0.002 % Inhibition 49.63 41.99 MT-TSB 0.284 0.388 0.104 0.284 0.361 0.077 (75 mg/Mi) 0.430 0.146 0.355 0.071 20 WO 2005/102935 PCT/US2005/012915 Mean 0.125 0.074 SD 0.030 0.004 % Inhibition 81.40 61.15 5 MT-TSB 0.274 0.322 0.048 0.274 0.322 0.048 (100 mg/mL) 0.339 0.065 0.310 0.036 Mean 0.057 0.042 SD 0.012 0.008 % Inhibition 91.59 77.95 10 Example 6 This example demonstrates that treatment with moss does not kill the bacteria but it does inhibit their growth. A fluorescence assay, commercially available from Molecular Probes, Eugene, Oregon, Kit No. L-7012, was used to 15 determine the viability of bacteria. This system uses mixtures of green and red fluorescent nucleic acid stains that have differing ability to penetrate viable and non-viable bacterial cells. The green fluorescent strain, which emits at 500 nm, binds to both viable and non-viable bacteria. The red fluorescent strain, which emits at 650 nm, binds only to non-viable bacteria. Therefore, a bacterial sample 20 containing a higher proportion of non-viable bacteria will have an altered staining ratio. The data show that for both E. coli and S. aureus, the ratio of viable to non viable bacteria remains the same as in the control sample. Procedure: 25 1. 100 tL was incubated in 10 mL of media (pH controlled TSB and S. papillosum sample, as prepared in Examples 1 and 2, respectively) for 3 hours at 37 0 C. 2. This mixture was centrifuged to concentrate the bacteria, which was then resuspended in 10 mL phosphate buffered saline (PBS). 21 WO 2005/102935 PCT/US2005/012915 3. Three mL of resuspended bacteria were added to each of three cuvettes. 4. 40 ptL Styo-9 dye was mixed with 40 ptL Propidium Iodide dye. Caution should be used as these compounds are believed to be carcinogens. 5. 9 pL of the mixed dye solution was added to each cuvette and stored in the 5 dark for 15 minutes. 6. Two PBS cuvettes were prepared with no dye and two PBS cuvettes were prepared with dye to be used as blanks. 7. The solutions were mixed thoroughly. The fluorescence intensity is measured at 500 nm (with absorption at 480 nm) and at 650 rim (with absorption at 10 490 nm). The ratio of these two values relates to the degree of viability of the bacterial culture. The following tables report the fluorescence intensity at two wavelengths for bacterial samples in two different media. The intensity of fluorescence at 500 nm 15 over the intensity of the fluorescence at 650 nm creates a ratio which relates to the degree of viability of the bacterial culture. The mean of three TSB and three moss treated TSB samples (MT-TSB) is reported below. In each case, the percent of inhibition is compared to a control sample. 20 Viability Assay for E. coli (clinical isolate) Media 500 nrm 650 nm Ratio 500/650 TSB 505.117 5.783 87.3228 MT-TSB of S. papillosum 130.1833 1.5167 85.8352 25 Viability Assay for S. aureus (ATCC Strain #29213) Media 500 rim 650 m Ratio 500/650 TSB 80.117 3.533 22.6745 MT-TSB of 22 23 S. papillosum 45.055 2.0667 21.7984 The data show that there is no significant change in the ratios between TSB and the moss-treated TSB, indicating that the effect of the moss is bacteriostatic rather than 5 bactericidal. Example 7 Various microorganisms were treated with S. papillosum TSB (concentration of 50 mg/mL) according to Example 3. The percent inhibition of microorganism growth is 1o reported. Both a TSB Control sample and moss-treated TSB solutions (MT-TSB) are reported below. The "Value" is obtained by subtracting the optical density (OD) of a blank (B) from the measured OD (Meas.) of a sample.

WO 2005/102935 PCT/US2005/012915 Two studies were done and are denoted (1) and (2) below. Test Material (1) E. coli S. aureus (clinical isolate) ATCC # 29213 5 B Meas. Value B Meas. Value TSB 0.034 0.694 0.660 0.034 0.273 0.239 (Control) 0.718 0.684 0.257 0.253 Mean 0.672 0.246 SD 0.017 0.010 10 MT-TSB 0.219 0.542 0.323 0.219 0.362 0.143 0.572 0.353 0376 0.157 Mean 0.338 0.150 SD 0.021 0.010 15 % Inhibition 49.7 39.02 Test Material (2) E. coli S. aureus B Meas. Value B Meas. Value TSB 0.043 0.693 0.650 0.043 0.332 0.289 20 (Control) 0.667 0.624 0.327 0.284 Mean 0.637 0.287 SD 0.018 0.004 MT-TSB 0.247 0.492 0.245. 0.247 0.394 0.147 25 0.498 0.251 0.428 0.181 Mean 0.248 0.164 SD 0.004 0.024 % Inhibition 61.07 42.76 24 WO 2005/102935 PCT/US2005/012915 Test Material (1) S. epidermidis P. aeruginosa ATTC # 12228 ATTC #10145 B Meas. Value B Meas. Value TSB 0.034 0.388 0.354 0.034 0.175 0.141 5 (Control) 0.412 0.375 0.167 0.133 Mean 0.366 0.137 SD 0.017 0.006 MT-TSB 0.219 0.542 0.323 0.219 0.321 0.102 10 0.572 0.353 0.331 0.112 Mean 0.338 0.107 SD 0.021 0.007 % Inhibition 53.26 21.90 15 Test Material (2) S. epidermidis P. aeruginosa B Meas. Value B Meas. Value TSB 0.043 0.349 0.306 0.043 0.204 0.161 (Control) 0.327 0.284 0.186 0.143 Mean 0.295 0.152 20 SD 0.016 0.013 MT-TSB 0.247 0.428 0.181 0.247 0.371 0.124 0.444 0.197 0.340 0.093 Mean 0.189 0.109 25 SD 0.011 0.022 % Inhibition 35.93 28.62 25 26 Test Material (1) C. albicans A. amstelodami ATTC# 10231 ATTC# 1001 B Meas. Value B Meas. Value TSB 0.034 0.068 0.034 0.034 0.053 0.019 5 (Control) 0.069 0.035 0.047 0.013 Mean 0.035 0.016 SD 0.001 0.004 MT-TSB 0.219 0.249 0.030 0.219 0.231 0.012 10 0.245 0.026 0.229 0.010 Mean 0.028 0.011 SD 0.003 0.001 % Inhibition 18.84 31.25 15 Test Material (2) C. albicans A. amstelodami B Meas. Value B Meas. Value TSB 0.043 0.1019 0.058 0.043 0.067 0.024 (Control) 0.057 0.044 0.071 0.028 Mean 0.051 0.026 20 SD 0.010 0.003 MT-TSB 0.247 0.275 0.028 0.247 0.268 0.021 0.292 0.045 0.254 0.007 Mean 0.037 0.014 25 SD 0.012 0.010 % Inhibition 28.43 46.15 WO 2005/102935 PCT/US2005/012915 Example 8--Effect of Acid Treatment of the Moss Compressed sticks of S. cristatum moss (obtained from Sutton's Moss, Canada (harvested in New Zealand)) were soaked in four increasing concentrations 5 of Fe (Fe standard in concentrated HC1, 0, 0.5,5,50 mg/L, available from Ricca Chemicals, Arlington, Texas) at 50 mg moss/ml in distilled water. The soaked moss was stored overnight at 4 C. The Fe solutions were extracted by syringe, filtered and measured for Fe by inductively coupled plasma atomic emission spectrometry analysis. The results showed that the moss bound significant 10 amounts of Fe, up to 15 mg/L in the 50 mg/L sample. This experiment was run with distilled water washed moss resulting in similar results. However, it was noted that the Fe spiked samples had a low pH. Since optimal binding is at pH 4 to 6, we adjusted the pH up to between 4 and 7 on the next experiment. When the pH of the Fe samples was brought up, the Fe started to precipitate. The moss 15 removed all of the Fe from the sample (up to 25 mg/L). It was then decided that ions bound to the moss before use could affect the cation binding tests and methods to remove the cations from the moss should be investigated. When developing the method for acid washing Sphagnum moss (not peat moss, which is decomposed moss), two different acids were first used. One batch 20 of moss (approx. 5g) was constantly stirred in 3.5 L of distilled water pH adjusted to 1 with concentrated HN0 3 . For the other batch of moss, a 2% solution of glacial acetic acid was used. The washes were stirred for 1 hour, then the supernatant was filtered off and new wash solution was put on the moss. This was repeated for a total of four acid washes. The acid washes were followed by 4 25 distilled water washes carried out the same way. At the end of the distilled water washes, the conductivity was similar to that of distilled water. The two acids removed similar amounts of ions; therefore acetic acid was routinely used for washing the moss thereafter. 27 WO 2005/102935 PCT/US2005/012915 It was decided that a metal that was soluble at neutral pH would be better suited to test binding capacity and, test for improvement of binding with acid washed Sphagnum moss vs. non-washed moss. Calcium was chosen for this purpose. The moss used was the S. cristatum moss described earlier in this 5 example, the acid used was a 2% solution of glacial acetic acid, and the wash was performed as described in the preceding paragraph. The first test showed the opposite of what was expected, the non-washed moss bound the most and the acid washed moss bound the least. When the pH of the samples was checked, it was discovered that the binding ability correlated with pH. The acid washed moss 10 reduced the pH of the solutions, which affected the ion binding. To eliminate this problem, acid washed moss was washed with a high salt solution to displace the H ions with Na. The high salt solution was 1M sodium acetate and approximately 5 g of moss was constantly stirred in 3.5 L of this sodium acetate solution for one hour, and then the wash was repeated. These two sodium acetate washes were 15 followed by four washes with distilled water, each wash for one hour, and each was carried out the same way. The acid/salt-washed moss was tested; the pH of the extract did not drop and showed a significant improvement of binding over distilled water and non-washed moss as can be seen in the following table (concentrations of Ca are in ppm). 20 Starting Resulting Moss treatment LCa Average [Cal Stdev pH Control 0 -1.08 0.61 6.02 25 Acetic Acid, Acetate Washed 0 -0.97 0.45 7.62 No wash 0 -0.14 0.51 5.26 Distilled water washed 0 0.36 1.32 5.13 28 WO 2005/102935 PCT/US2005/012915 Acetic Acid, Acetate washed 100 -1.40 0.25 6.62 No wash 100 11.24 0.00 4.81 Distilled water washed 100 16.89 1.17 4.54 5 Control 100 88.76 0.05 6.65 Acetic Acid, Acetate washed 200 -0.33 0.87 6.17 No wash 200 46.47 5.88 4.82 10 Distilled water washed 200 53.55 4.42 4.61 Control 200 198.10 1.83 6.76 The pH of the extracts varied by up to 2 pH units, so it was still difficult to distinguish between the effects of acid washing and pH. Therefore a new method 15 to test for binding of the moss was developed that would allow adjustment of pH while the moss was still in the sample solutions. This was accomplished by using multi-well plates, small stir bars and 10 mg/ml moss concentrations. After the solutions were on the moss for approximately one-half hour, the pH's of the solutions were all adjusted to within 0.25 pH units of 6.5. This allowed for the 20 testing of acid/salt washed moss and acid only washed moss. The results are shown below. The averages shown are the averages of two samples. Starting Resulting Moss treatment {a]. Average [Cal Stdev Acetic Acid/Na acetate 25 washed 0.00 6.93 0.72 Acetic Acid washed 0.00 6.16 0.16 Distilled water washed 0.00 6.85 0.31 No wash 0.00 8.54 1.56 Control 0.00 8.10 0.31 30 29 WO 2005/102935 PCT/US2005/012915 Acetic Acid/Na acetate washed 100.00 6.78 0.31 Acetic Acid washed 100.00 6.82 0.26 Distilled water washed 100.00 20.73 1.09 5 No wash 100.00 26.25 0.72 Control 100.00 92.27 1.56 Acetic Acid/Na acetate washed 500.00 307.28 7.25 10 Acetic Acid washed 500.00 319.25 8.13 Distilled water washed 500.00 375.18 3.36 No wash 500.00 382.85 4.38 Control 500.00 454.30 8.91 15 With the pH's adjusted to be within 0.5 pH units of each other; the pH effect is eliminated and the significantly improved binding capacity of the acid washed mosses can be seen. The acid/salt washed moss bound slightly better than the acid only washed moss and the distilled washed slightly better than the non-washed moss, but barely enough to be significant. 20 Thus, the moss was shown to bind both Fe and Ca ions, and therefore is effective in water treatment because the removal of one or both of these ions is a goal of water treatment. The above description and the drawings are provided for the purpose of describing embodiments of the invention and are not intended to limit the scope of 25 the invention in any way. It will be apparent to those skilled in the art that various modifications and variations can be made without departing from the spirit or scope of the invention. Thus, it is intended that the present invention cover the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents. 30

Claims (20)

1. A method of inhibiting microorganism growth comprising contacting water susceptible to microorganism growth with an amount of a non-decomposed moss effective to inhibit microorganism growth, wherein the moss is selected from the group s consisting of sphagnum papillosum, sphagnum cristatum, and mixtures thereof, and wherein the water is water in a spa, in a pool, or in an aquarium.

2. The method of claim 1, wherein the moss is sphagnum papillosum.

3. The method of claim 1, wherein the moss is sphagnum cristatum.

4. The method of claim 1, wherein the moss comprises sphagnum papillosum io only.

5. The method of claim 1, wherein the moss comprises sphagnum cristatum only.

6. The method of claim 1, wherein the moss comprises a mixture of sphagnum papillosum and sphagnum cristatum only. is

7. The method of any one of the preceding claims, wherein the moss is compressed.

8. The method of claim 7, wherein the moss is in the form of strips.

9. The method of any one of the preceding claims, wherein the moss has been sterilized. 20

10. The method of any one of the preceding claims, wherein the moss has been washed with an acidic solution, such as a solution of acetic acid.

11. The method of claim 10, wherein the moss has been washed with an acidic solution and then washed with a salt solution.

12. The method of any one of the preceding claims, wherein the non-decomposed 25 moss is placed in a carrier before contacting the carrier with the water.

13. The method of claim 12, wherein the water is pumped through the carrier.

14. The method of claim 13, wherein the carrier is a polymer matrix, a biomatrix, or one or more membranes.

15. The method of claim 12, wherein the carrier has an interior cavity and one or 30 more openings allowing ingress to and egress from the interior cavity, the moss contained within the interior cavity, and the carrier completely enclosing the moss.

16. The method of claim 12, wherein the carrier comprises a float.

17. The method of claim 12, wherein the carrier comprises a float and a cylindrical portion beneath the float, the cylindrical portion having an interior cavity and 35 one or more openings allowing ingress to and egress from the interior cavity. - 32

18. The method of claim 12, wherein the carrier is a mesh.

19. The method of claim 12, wherein the carrier comprises one or more weights.

20. A method of inhibiting microorganism growth, said method substantially as hereinbefore described with reference to any one of the examples and/or the figures. 5 Dated 31 May 2010 Embro Corporation Patent Attorneys for the Applicant/Nominated Person 10 SPRUSON & FERGUSON