A METHOD FOR THE CONSERVATIVE TREATMENT OF AT LEAST ONE SYMPTOMATIC FRUIT PLANT SHOWING SYMPTOMS OF A DISEASE

Abstract

A method for the conservative treatment of at least one symptomatic fruit plant showing symptoms of a disease, comprising the steps of identifying the symptomatic plant which has undergone a pruning step; identifying a period of quiescence or a period of resumption of vegetative growth of the symptomatic plant; and during the period of quiescence or resumption of vegetative growth, making at least one hole in the trunk of the symptomatic plant until reaching the xylem; finally, introducing into the xylem, by means of said at least one hole, an amount of treatment fluid such as to provoke the discharge of the same fluid from the pruned portions of the symptomatic plant and/or the discharge of sap from the same symptomatic plant.

Claims

1. A method for the conservative treatment of at least one symptomatic fruit plant showing symptoms of a disease, comprising: identifying the symptomatic plant which has undergone a pruning step; identifying a period of quiescence or a period of resumption of vegetative growth of the symptomatic plant; and during the period of quiescence or resumption of vegetative growth, making at least one hole in the trunk of the symptomatic plant until reaching a non-necrotic portion of the xylem; introducing into the non-necrotic portion of the xylem, by means of said at least one hole, an amount of treatment fluid such as to provoke the discharge of the same treatment fluid from the pruned portions of the symptomatic plant and/or the discharge of sap from the same symptomatic plant.

2. The method according to claim 1, wherein identifying the pruned symptomatic plant comprises: identifying said symptomatic plant during a vegetative period thereof; and marking said symptomatic plant with a distinctive element that makes it identifiable in a subsequent period of quiescence or resumption of vegetative growth.

3. The method according to claim 1, wherein the pruned symptomatic plant is obtained by pruning, which comprises: identifying a period of quiescence of the symptomatic plant; and cutting off one or more parts of the symptomatic plant so as to prepare pruned portions useful for the discharge of treatment fluid and/or sap during the step of introducing the same treatment fluid into the non-necrotic portion of the xylem; carrying out this step 15 days at most before the step of introducing an amount of treatment fluid into the non-necrotic portion of the xylem.

4. The method according to claim 3, wherein carrying out pruning takes place at a different moment from a step of pruning any other asymptomatic plants present nearby.

5. The method according to claim 1 wherein making at least one hole in the trunk of each symptomatic plant comprises the step of making from one to three holes depending on a diameter of the trunk of the symptomatic plant to be treated; each hole having a diameter ranging between 2 millimeters and 10 millimeters and a maximum depth of 20 millimeters.

6. The method according to claim 1, wherein making at least one hole in the trunk of each symptomatic plant comprises the step of making said at least one hole at a height from the base of the trunk comprised between 30 centimeters and 100 centimeters.

7. The method according to claim 1, wherein said treatment fluid comprises colloidal silver and/or fertilising substances and/or plant protection substances.

8. The method according to claim 1, further comprising: estimating the volume of the trunk of a corresponding asymptomatic plant; calculating the theoretic amount of treatment fluid necessary to treat the aforesaid estimated volume; measuring the amount of treatment fluid actually introduced into said symptomatic plant; comparing said measured amount with said theoretical amount in order to derive an estimation of the volume of a non-diseased trunk depending on the difference between the introduced amount of treatment fluid and the theoretical amount of treatment fluid.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0023] Additional features and advantages of the present invention will emerge more clearly from the appended drawings, which serve to illustrate, in combination with the description, the inventive principles at the basis of the invention.

[0024] FIG. 1 illustrates a schematic view of a cross section of the trunk of a fruit plant showing symptoms of a disease during a step of the conservative treatment method.

[0025] FIG. 2 illustrates a schematic view of different types of a same fruit plant, specifically a grapevine.

DETAILED DESCRIPTION

[0026] The present invention relates to a method for the conservative treatment of fruit plants showing symptoms of a disease.

[0027] Any modifications or variants which, in the light of the description, should be evident to the person skilled in the art must be considered as falling within the scope of protection established by the present invention, according to considerations of technical equivalence.

[0028] In botany, mainly in reference to arboreal or fruit-bearing plants, the annual cycle of the plants is characterised by a phase of vegetative development (also known as “vegetative period”) alternating with a rest period (also known as “period of quiescence” or “period of winter quiescence”).

[0029] Therefore, in the present description, the term “vegetative period” relates to a period in which a growth activity of all the plant organs is present.

[0030] In contrast, in the present description, the term “period of quiescence” relates to a period of the biological cycle in which in the whole plant, or in some of the organs thereof, vital functions are suspended or greatly slowed (also known as vegetative stasis, or rest, or dormancy).

[0031] In the case of fruit plants, the vegetative period generally begins in spring and lasts until the natural loss of leaves. In greater detail, this period is composed in turn of another two sub-phases: a phase of more or less intense vegetative activity, and a reproductive phase which regards the formation and development of buds containing the flower primordia.

[0032] Consequently, the period of quiescence begins with the falling of leaves and continues throughout the winter, ending with the start-up of vegetative activity the following spring.

[0033] The present invention relates to a method for the conservative treatment of symptomatic plants 1 showing symptoms of a disease. The method is preferably aimed at fruit plants having a trunk 2 of a small diameter, more precisely with a maximum diameter of about 15 centimetres.

[0034] For example, the method is applicable in the management of esca disease, a widespread disease with large negative effects on the survival and productivity of grapevines.

[0035] In particular, the conservative treatment method comprises the steps of: [0036] identifying the symptomatic plant 1 which has undergone a pruning step; [0037] identifying a period of quiescence or a period of resumption of vegetative growth of the symptomatic plant 1; and [0038] during the period of quiescence, for example preferably in concomitance with the fruit grower's pruning (generally autumn/winter), or the resumption of vegetative growth, making at least one hole 3 in the trunk 2 of the symptomatic plant 1 until reaching the xylem 4; [0039] introducing into the xylem 4, by means of said at least one hole 3, an amount of treatment fluid such as to provoke the discharge of the same treatment fluid from the pruned portions of the symptomatic plant 1 and/or the discharge of sap from the same symptomatic plant 1.

[0040] Advantageously, carrying out the operating steps during a period of the plant in which the pressure inside the xylem vessels is considerably reduced, or even nil, enables the treatment fluid to be very easily introduced into the xylem vessels of the symptomatic plant 1 without having to overcome operating obstacles, as better explained further below. Even more advantageously, the low pressure inside the xylem vessels due to the period of intervention (i.e. the implementation of the conservative treatment method in the period of quiescence or resumption of vegetative growth), together with the presence of pruned portions on the symptomatic plant 1, enable an operator to introduce the treatment fluid into the xylem vessels 4 of the symptomatic plant 1 with a low degree of difficulty, since the manual pressure to be exerted in order to introduce the treatment fluid is relatively low.

[0041] According to one aspect of the invention, in order to prevent the symptomatic plants 1 from propagating the disease, and the asymptomatic plants, if present, from being infected, the operator must carry out the conservative treatment in the periods in which the performance and effectiveness thereof are maximum.

[0042] More precisely, the operator must perform microinjections on the trunk 2 of the symptomatic plant 1 in order to introduce the treatment fluid following the pruning step in the period of quiescence, preferably within a few days after it has been carried out, or, alternatively, in the subsequent period of resumption of vegetative growth.

[0043] The step of injecting the treatment product is preferably carried out manually. In other words, the operator exerts a very small pressure, corresponding to a push of the hand, on the plunger of a syringe 6, which is provided with special needles 7, and attached to a tube that connects it to a reservoir 8 containing the treatment fluid.

[0044] Advantageously, the discharge of the treatment fluid and/or sap from the pruned portions (from the “fresh” cuts made during the period of quiescence or from the same pruning cuts in the period of resumption of vegetative growth) offers the operator immediate confirmation of the correct performance of the injection procedure and, therefore, of the correct progress of the treatment method.

[0045] According to one aspect of the invention, the step of making at least one hole 3 in the trunk 2 of each symptomatic plant 1 comprises the step of making from one to three holes 3 according to the diameter of the trunk 2 of the symptomatic plant 1 to be treated. In other words, the number of holes 3 to be made on the trunk 2 of the symptomatic plant 1 increases with increases in the diameter of the same symptomatic plant 1. In this manner, it is possible to make a number of holes 3 of a small size on the trunk 2 so that the method is the least invasive possible and, at the same time, the whole volume of the symptomatic plant 1 can be treated with the introduction of the treatment fluid.

[0046] In particular, each hole 3 has a diameter ranging between 2 millimetres and 10 millimetres and a maximum depth of 20 millimetres in order to minimise the invasiveness of the conservative treatment method on the symptomatic plant 1.

[0047] According to another aspect of the invention, the step of making at least one hole 3 in the trunk 2 of each symptomatic plant 1 comprises the step of making the hole 3 at a height of about one metre from a base of the trunk 2, i.e. from the ground, comprised between 30 centimetres and 100 centimetres, preferably less than one metre and greater than 50 centimetres.

[0048] FIG. 1 schematically illustrates a cross section of the trunk of a symptomatic plant 1, for example a grapevine affected by esca disease, in which a portion 5 of the xylem 4 is in a state of necrosis and, therefore, not suitable for enabling the injection of the treatment product.

[0049] Each hole 3 is bored into the trunk 2 preferably with the use of an electric drill so as to achieve a precise perforation that is the least invasive possible for the plant.

[0050] If the hole is drilled in the portion 5 of the plant in a state of necrosis, the operator will not be able to perform the injection of the treatment fluid and, therefore, will have to drill a new hole in a different portion of the trunk 2.

[0051] At the end of the injection, depending on the variety of the fruit plant and the phenological phase, the holes can be closed off with a special plug made of corn starch.

[0052] According to one aspect of the invention, the treatment fluid the operator introduces into the xylem 4 of the symptomatic plant 1 comprises a fertilising product enriched with thermal water containing sodium chloride, bromide and iodide and fatty acids, i.e. a resistance-inducing fertiliser.

[0053] According to another aspect of the invention, the treatment fluid comprises colloidal silver and/or fertilising substances and/or plant protection and/or stimulant substances.

[0054] The treatment fluid preferably comprises a resistance-inducing fertiliser that enables the fruit plants (for example grapevines, kiwis, pears . . . ) to be maintained in optimal vegetative conditions, thus making it able to respond positively to conditions of high stress.

[0055] Even more preferably, the treatment fluid comprises colloidal silver, as this substance, when injected through the xylem vessels, is capable of inhibiting and blocking the development of the disease within the fruit plant so as to preserve the plant's root system and, consequently, its productivity without there being any need to manage the additional costs of uprooting diseased plants, disposing of them and replanting healthy plants.

[0056] Colloidal silver does not have a biocidal (antibacterial or antifungal) function capable of eliminating dry rot or bacteria or fungi present in wood (as a plant protection product might do). In fact, colloidal silver travels through the xylem vessels of healthy wood (and not diseased wood), forming a barrier that confines and separates any diseased portion 5 of the wood (for example, a portion in a state of necrosis) from the healthy wood. In this manner, it prevents the dissemination of the disease in the plant, thus preventing the weakening thereof, a reduction in productivity and the alteration/unusability of the fruit.

[0057] In other words, the treatment fluid containing colloidal silver enables the xylem vessels of healthy wood to be preserved so as to protect the plant against the progression of the disease, which is slowed down until coming to a halt.

[0058] According to one aspect of the invention, the step of identifying the pruned symptomatic plant 1 comprises the sub-steps of: [0059] identifying the symptomatic plant 1 during a vegetative period thereof; and [0060] marking the symptomatic plant 1 with a distinctive element that makes it identifiable in a subsequent period of quiescence or resumption of vegetative growth.

[0061] Generally, the first symptoms of a disease that appear are easily detectable by expert eyes during the vegetative period, in the spring/summer.

[0062] Therefore, marking a symptomatic plant 1 is particularly useful in cases in which the treatment is carried out at a later time, for example in the period of quiescence, as is actually preferably the case.

[0063] For this purpose, according to one possible example, marking can be done with the use of tape that is resistant to atmospheric conditions, capable of lasting for a number of years, and bears an indication of the type of disease afflicting the plant. In this manner, the pruning operations on symptomatic plants 1 can be advantageously managed separately from any treatments to be carried out neighbouring asymptomatic plants, for example in a field or orchard.

[0064] According to another aspect of the invention, the pruned symptomatic plant 1 is obtained by means of a pruning step comprising the following sub-steps: [0065] identifying a period of quiescence of the symptomatic plant 1; and [0066] pruning the symptomatic plant 1 by cutting off some parts so as to prepare pruned portions useful for the discharge of treatment fluid and/or sap during the step of introducing the same treatment fluid into the xylem 4. Preferably, this step is carried out 15 days at most before the step of introducing an amount of treatment fluid into the xylem 4.

[0067] In other words, in the event that the pruning of the symptomatic plant 1 is carried out in the period of quiescence, it is preferable that the step of making a hole in the trunk 2 and the step of introducing the treatment fluid (the latter, in particular, between the two steps) take place no later than 15 days after the pruning step, preferably within a week of the latter. In this manner, the xylem vessels in the pruned portions will be open and, following the introduction of the treatment fluid into the xylem 4, will enable the discharge thereof and/or the discharge of sap from the same pruned portions.

[0068] In the event that the period between pruning and the conservative treatment is prolonged beyond that limit of about 15 days, it is possible that the xylem vessels in the pruned portions might cicatrise, thus complicating or even precluding the introduction of the treatment fluid, as the discharge thereof and/or the discharge of sap from the pruned portions would be obstructed. Therefore, in such a case it is advisable to postpone carrying out the conservative treatment with the treatment fluid and to wait for the beginning of the period of resumption of vegetative growth, as in this period the xylem vessels in the pruned portions tend to reopen naturally and, therefore, allow the discharge of sap (in fact, this period is also defined as the “bleeding” period, since the reopening of the xylem vessels brings about a minimal leakage of sap from the previously pruned portions of the plant).

[0069] In the example of a grapevine affected by esca disease, the implementation of the treatment method advantageously allows the lignification of the plant's branches and the resumption of the vegetative activity of the shoots, which develop a vegetative area in full activity, the development and formation of clusters with continuity (in particular intact, turgid and completely coloured grapes), and an excellent cost-benefit ratio compared to traditional techniques (for example, uprooting and replanting).

[0070] In any case, the symptomatic plants 1 identified must be pruned taking care to use different tools (for example shears) from the ones used for asymptomatic plants. Alternatively, it is possible to use the same shears, adopting the precaution of disinfecting them thoroughly, for example with a 15% solution of quaternary ammonium salts, to avoid transmitting the disease to asymptomatic plants.

[0071] In addition, the pruning of symptomatic plants 1 must take place at a different time from any pruning operations on asymptomatic plants and in a controlled manner with respect to the latter, so as not to allow transmission of the disease.

[0072] The pruning useful for the application of the conservative treatment method claimed herein is carried out during the period of quiescence, preferably about 20 days earlier than the fruit grower's normal pruning, or during the period of resumption of vegetative growth.

[0073] Advantageously, pruning in the winter period, for example in the month of November, enables the sap of the symptomatic plant 1 to be discharged from the pruned portions (so-called pruning “wounds”) in order to act as a “natural disinfectant” at the site of the cuts made at the end of the execution of the conservative treatment.

[0074] The pruning residues of symptomatic plants 1 must be taken out of the field in order to be managed separately to avoid contaminating asymptomatic plants.

[0075] Even more advantageously, carrying out the treatment during the period of quiescence (i.e. generally during the winter) advantageously allows the operator to have access to the symptomatic plants when the entire field is not subjected to plant protection treatments, generally spring/summer treatments which abound in harmful substances (the summer treatment generally involves the use of various elements that are harmful to humans in the event of inhalation or direct contact with the skin). In fact, though the operator is equipped with all the necessary protections, there always continues to be a minimal risk of contamination, while the use of a full-body protective suit or coverall provided with integrated head protection would considerably complicate the execution of the treatment method.

[0076] According to one aspect of the invention, the method comprises the further steps of: [0077] determining the type of symptomatic plant 1 that needs to be treated; [0078] estimating the volume of the trunk of a corresponding asymptomatic plant; [0079] calculating the theoretical amount of treatment fluid necessary to treat the aforesaid estimated volume; [0080] measuring the amount of treatment fluid actually introduced into said symptomatic plant 1; [0081] comparing said measured amount with said theoretical amount in order to derive an estimation of the volume of a non-diseased trunk 2 depending on the difference between the introduced amount of treatment fluid and the theoretical amount of treatment fluid.

[0082] In other words, the treatment method is advantageously capable of also providing an estimate of the condition of the wood making up the symptomatic plant 1 to be treated.

[0083] FIG. 2 illustrates, in a schematic view, a comparison among three different types of grapevines: guyot, having an average height L1 of about 80 centimetres, cordon, having an average height L2 of about 120 centimetres, and pergola having an average height L3 of about 170 centimetres.

[0084] The three types of grapevines taken into consideration, having three trunks 2 with different lengths, do not have same total volume of wood. Therefore, for each type, a calculation was made of the average value of the total volume of wood treatable with the introduction of a fluid treatment along the respective trunk 2. Consequently, for each average value of the total volume of wood a calculation was made of the average value of the treatment fluid introducible along the totality of the volume, as if it were free of any disease and thus of defects (for example portions 5 in a state of necrosis) which preclude a correct flow of treatment fluid.

[0085] In other words, for each type of fruit plant it is possible to calculate the average value of the amount of treatment fluid capable of flowing through the xylem vessels between the hole 3 made on the trunk 2 and the pruned portions of the asymptomatic plant. This average value identifies the maximum amount of treatment fluid capable of flowing through the trunk 2 of an asymptomatic plant of a respective type.

[0086] The syringe 6 used to introduce the treatment fluid generally has a reservoir 8 with a capacity of about 5 millilitres. Graduated syringes are preferably used in order to dispense a precise dose of treatment fluid into the fruit plant according to the average value of the volume of wood of the trunk 2.

[0087] Generally, at least 6 millilitres of treatment fluid are introduced into the xylem 4 of the plant. Preferably and advantageously, about 12 millimetres are introduced therein, by carrying out several repetitions of the injection if the capacity of the reservoir 8 of the syringe 6 is lower than the amount that needs to be introduced.

[0088] Knowing the actual amount of treatment fluid inserted in the reservoir 8 of the syringe 6 will enable the operator to estimate the amount of healthy wood of the symptomatic plant 1 simply by determining the value of the amount of treatment fluid introduced through the same symptomatic plant 1.

[0089] For example, if three quarters of the average value of the amount of treatment fluid flow through the symptomatic plant 1, the operator will be able to deduce that the progression of the disease is relatively low and, if stopped over time, the productivity of the fruit plant will still be acceptable. If, by contrast, the treatment fluid able to flow through the symptomatic plant 1 is only half or less of the average value of the amount calculated for an asymptomatic plant, the diseased plant is at a very advanced stage of disease which will make a possible future removal thereof necessary, since the productivity will be considerably compromised.