Patent Description:
The present invention relates to a method for treating one or more cut flowers each comprising a stem, possibly leaves and a flower bud, said method comprising.

As should be understood from above, the present invention provides a method in which it is ensured that the flower bud is free from impregnation solution. This is an important and unique aspect of the present invention.

In the article "<NPL>, there is disclosed a method involving treating cuttings by use of vacuum impregnation. It should be noted that this article suggests treating the entire object, in this case cuttings, i.e. not cut flowers. The present invention, however, provides a method in which a flower bud of a cut flower is free from impregnation solution. This is very important because the flower buds are susceptible to the fungus disease botrytis, which will cause flowers to turn black and decay. Botrytis has ranges of temperature and relative humidity that are necessary for spore germination, infection and disease development. Spore germination and infection depends on a film of moisture for <NUM> to <NUM> hours, relative humidity of <NUM>% or greater, and temperatures between <NUM>-<NUM> with colonization of plant tissues occurring at temperatures up to <NUM>.

In relation to the above it may also be mentioned that in the results below and in <FIG> there is shown the importance of treating the cut flower according to the present invention, i.e. where only the stem or part of the stem (and leaves) are immersed in the impregnation solution and where the flower bud is kept out of / free from the impregnation solution.

Moreover, in <CIT> there is disclosed a method for preserving a plant from microorganisms, comprising causing essentially all of the liquid received by the plant stem to be passed through a filter having a porosity which is insufficient to permit the passage of microorganisms with the liquid to the plant.

Moreover, in <CIT> there is disclosed a method and apparatus which include steps and means for providing a supply of aqueous nutrient liquid to the cut end of each of one or more cuttings such as cut flowers and small branches for sustaining life processes, and for coupling the cut interface of each cutting to the liquid supply.

Furthermore, in <CIT> there is provided a method for treating a plant material, said method comprising the steps of exposing the plant material to vacuum impregnation in an aqueous solution; applying a pulsed electrical field (PEF) treatment to the plant material in the aqueous solution before, simultaneously as or after exposing the plant material to vacuum impregnation in an aqueous solution; applying a drying step to the PEF treated plant material for removing water/moisture from surfaces of the plant material before packing the treated plant material; and an active step for preventing microbial contamination of the aqueous solution.

Some specific embodiments of the present invention are provided below.

According to one specific embodiment of the present invention, the impregnation solution comprises at least one sugar. According to yet another embodiment, said at least on sugar is glucose, trehalose and/or fructose in a concentration of at least <NUM> wt%. in this regard it may also be mentioned that the impregnation solution according to the present invention preferably is an aqueous impregnation solution.

The impregnation solution may also comprise additives. In relation to the impregnation solution it should be noted that this may comprise at least one sugar without any additives, at least one sugar and additives, or only additives.

According to one embodiment, the impregnation solution comprises at least one additive being a vitamin, mineral, nutrient, such as silica, antimicrobial, or a combination thereof. According to yet another embodiment, the impregnation solution comprises at least one additive of folic acid, gamma-aminobutyric acid (GABA), ethylene blocker (controller), e.g. <NUM>-methylcyclopropene (<NUM>-MCP), amino acid, e.g. cysteine, plant hormone, e.g. IBA, an antiseptic agent, e.g. silver nitrate, a surfactant, or a combination thereof.

As may be understood from above, different additive types are possible according to the present invention. According to one embodiment of the present invention, at least one surfactant is included in the impregnation solution. This may be of interest to improve the weight gain, especially when treating at high pressures and less treatment time.

Method process parameters are also of interest according to the present invention. According to one embodiment, the method involves vacuum impregnation in a minimum pressure range of <NUM> - <NUM> mbar (<NUM>,<NUM> - <NUM>,<NUM> Pa).

According to yet another embodiment, the method is performed during a total treatment time of at least <NUM> minutes, e.g. at least <NUM> minutes or <NUM> minutes. Furthermore, according to yet another specific embodiment, the method involves vacuum impregnation in at least three phases, said at least three phases being a falling step when the pressure is decreased to a certain low pressure, then a holding step in which the low pressure is kept or substantially kept at the low pressure, and a pressure rising step where the pressure is increased to atmospheric level. According to one further embodiment, the falling step is performed in a range of <NUM> - <NUM> minutes, preferably the falling step is performed in a range of <NUM> - <NUM> minutes, preferably wherein the holding step is performed in a range of <NUM> seconds - <NUM> minutes, preferably wherein the holding step is performed in a range of <NUM> seconds - <NUM> minutes. Moreover, according to yet another embodiment, the rising step is performed in a range of <NUM> - <NUM> minutes, preferably in a range of <NUM> - <NUM> minutes.

The method according to the present invention may involve other steps. In some cases, it is of interest to include a PEF (pulsed electrical field) treatment. It should, however, be noted that only the vacuum impregnation is mandatory. Therefore, according to one embodiment, said method is performed without performing a prior, simultaneous or subsequent PEF (pulsed electrical field) treatment. Such a PEF step may, however, be part of the method according to the present invention. Therefore, according to yet another embodiment, the method also involves a step of applying PEF (pulsed electric field).

Other steps may also be part of the method according to the present invention. According to one specific embodiment, the method involves a subsequent washing step comprising immersing said one or more cut flowers into water to wash sugars from the surface of the cut flower, and wherein the immersing is performed so that the flower bud is excluded from being immersed. Moreover, according to another embodiment, the cut flowers are directly subjected to a cooling step after the washing step, said cooling step being a recovering step. The cooling step may suitably be performed at a temperature of <NUM>- <NUM>, such as suitably in a range of <NUM>-<NUM>. Moreover, according to one embodiment, the cooling step is performed during at least <NUM> hours, preferably at least <NUM> hours, such as in the range of <NUM> - <NUM> hours. Furthermore, the cooling should be performed in a controlled storing environment. According to one embodiment, the storing environment involves a humidity of above <NUM>%. Moreover, the cooling and transportation may be performed in a modified atmosphere. Furthermore, the cooling may suitably be performed in an aerated room so that the surfaces of the leaves dry on themselves.

In relation to the above it should be mentioned that the cooling step may also be seen as a recovery step in a cooled or low temperature.

Moreover, according to yet another embodiment, freezing is applied instead of cooling. Cooling is, however, preferred.

Moreover, according to yet another embodiment, the impregnation is a partial impregnation, preferably wherein the impregnation is a partial impregnation where the weight gain is <NUM>% of the full impregnation weight gain.

Prevention of microbial contamination is important. According to one embodiment of the present invention, the method also comprises an active step for preventing microbial contamination of the (aqueous) impregnation solution. According to one specific embodiment, the active step for preventing microbial contamination involves adding one or more antimicrobial agents to the impregnation solution, preferably wherein the active step for preventing microbial contamination involves an active treatment of the impregnation solution. Moreover, according to yet another embodiment, the impregnation solution is recirculated and reused, preferably as an active step for preventing microbial contamination.

The present invention is also directed to a system for treating one or more cut flowers. Therefore according to the present invention there is also disclosed a system for treating one or more cut flowers each comprising a stem, possibly leaves and a flower bud, said system comprising a treatment unit arranged for performing the method according to the present invention, wherein the treatment unit is arranged to allow for stable standing positions of cut flowers and has means for adjusting the level of an impregnation solution so that flower buds of the cut flowers are not immersed in the impregnation solution. According to one specific embodiment, the treatment unit is arranged for performing also a washing step. This may be of interest to wash off the sugar(s).

Moreover, the present invention also refers to a cut flower treated by the method according to the present invention.

Roses (variety: Athena) were purchased form a local distributor. The roses were transported from Kenya. The roses arrived at the test site <NUM> days after harvest.

The treatment according to the present invention was applied to the roses immediately after the arrival. The roses were placed vertically in an impregnation solution, making sure that the flower bud was not immersed in the impregnation solution, thus only the stem and leaves were immersed. The impregnation solution contained sugar (fructose at a concentration of <NUM>-<NUM> wt%). Vacuum was applied reaching a minimum pressure range of <NUM> - <NUM> mbar, and with a total treatment time of about <NUM> minutes.

After that the vacuum impregnation treatment was finished, the roses were taken out from the impregnation solution. They were then immersed in water, again excluding the flower buds, to wash the sugars from the surface and then placed in a cold room for <NUM> hours to recover. They were in this case not dried in any way.

After <NUM> hours the roses were moved to room temperature in order to evaluate the results at the end user conditions. They were stored in a vase, with only the lower part of the stems immersed in water, and the water was renewed every two days.

Results show a clear improvement of the general appearance of roses that were impregnated with sugar prior to storage (see <FIG>). The browning and wilting of the flower buds are delayed for the treated roses compared to the control. Also, the treated leaves preserve freshness better.

In <FIG> there is shown roses stored at room temperature for <NUM> days after the treatment (Right: roses treated according to the present invention, left: control roses, i.e. not treated).

In <FIG> there is shown roses from yet another trial. In this case the roses were stored at room temperature for <NUM> days after the treatment (Right: roses treated according to the present invention, left: control roses, i.e. not treated).

In another trial, relating to <FIG>, the following was performed and with the parameters stated below.

Flower buds of samples treated with the flower bud in the impregnation solution were completely rotten after <NUM> days at room temperature. As may be seen, for samples treated without the flower bud in impregnation solution, i.e. by the method according to the present invention, the flower buds are healthy and vigour after <NUM> days at room temperature.

The results of the different trials after <NUM> days at room temperature are shown in <FIG>. Again, and as may be seen, the flowers treated according to the present invention, i.e. with vacuum impregnation and where the flower buds are not in the impregnation solution exhibit the best features and appearance. Moreover, it may be seen that impregnating the flower buds with the impregnation solution leads to shorted vase life.

A system according to the present invention may be of different types.

According to one specific embodiment, the system for treating one or more cut flowers comprises a treatment unit arranged to allow for stable standing positions of cut flowers and has means for adjusting the level of an impregnation solution so that flower buds of the cut flowers are not immersed in the impregnation solution.

Claim 1:
A method for treating one or more cut flowers each comprising a stem, possibly leaves and a flower bud, said method comprising
- arranging one or more cut flowers in an impregnation solution so that at least a portion of the stem of said one or more cut flowers are immersed in the impregnation solution, but where the flower bud is free from impregnation solution; and
- applying vacuum impregnation, in a minimum pressure range of <NUM> - <NUM> mbar (<NUM>,<NUM> - <NUM>,<NUM> Pa), to the impregnation solution when said at least portion of the stem are immersed into the impregnation solution.