JP3902947B2 - Microbial mediating method and apparatus for attracting mosquitoes - Google Patents

Description

^ａ： 蚊誘引の程度、百分率でほぼ測定された。
“−”は誘引を示さないもの、“＋”＝１０％、“＋＋”＝２０％、“＋＋＋”＝３０％。
^ｂ：入手不能
【００１６】
ＮＢ培基で生育されたＢＥ９５８６菌株の吸引作用を更に特定するため、バクテリア培養物を遠心分離し、上澄み液を臭覚計で検査した。表２に示すように、成虫メス蚊の８６．７％ものものがバクテリア培養物上澄み液に誘引された。この誘引率はＮＢ培基単独よりも約２０％高く、匂い源なしのブランク溶液のものよりも２５％高かった。これはバクテリア培養物の分解により放出された揮発成分が成虫メス蚊をとりわけ誘引し得ることを示している。この検査において、加熱自体は６１．７％の誘引を示し、これは先の非加熱匂い源のものよりも高かった。更に、加熱装置は、バクテリア分解物の良好な蒸発に寄与するものである。
【００１７】
表２．バクテリア培養物上澄み液に誘引された蚊の誘引率（臭覚計で測定）
上澄み液^ａ 肉汁^ｂ ブランク^ｃ
８６．７±４．２^ｄ ６７．５±４．２ ６１．７±１１．８
^ａ：１０，０００ｘｇ、１０分間の遠心分離で収集されたバクテリア培養物上澄み液。
^ｂ：バクテリアを成長させるための培基。
^ｃ：匂い源を臭覚計のポートに置かない。
^ｄ：誘引された成虫メス蚊の数／３０ｘ１００％。
この検査においては３回の繰り返しが行われた。各繰り返しにおいて、３０匹の蚊の新規なバッチがフライトチャンバーに放たれた。
【００１８】
図１は本発明の好ましい１例に係わる装置を示す模式図である。図１において、装置１００は上部仕切り室１０２と、底部仕切り室１０４に分割され、ネジ付き容器１０６により接続されている。シールド１０８が上部仕切り室１０２の頂部に支持手段、例えば延長壁部を備えた支持ストックにより接続され、蚊を通過チャンネルに導くようにしている。シールド１０８は、約１−２センチ離して上部仕切り室１０２から分離されている。シールド１０８の下において、上部仕切り室１０２の頂部は複数の通過チャンネル１１０を含み、これらは上部仕切り室１０２の内部空間に向けて開放されている。この通過チャンネル１１０は蚊が通過可能な大きさの開口部を有するが、入ってくる蚊が逃げないように内側に開口している。上部仕切り室１０２をネジ付き容器１０６に嵌入させたのち、第１のボトル１２０が上部仕切り室１０２の内部およびネジ付き容器１０６のグリッド１１２上に配置される。この第１のボトル１２０は、少なくとも匂いシミュレータと、炭酸ガス供給用の供給源ならびに糖源とを有する。好ましくは、このヒト匂いシミュレータと、炭酸ガス供給源は培地を備えた酵母の発酵により提供される。この培地は糖源として役立つ果汁であってもよい。
【００１９】
図１を参照すると、底部仕切り室１０４は、時間制御手段と、温度制御手段とを少なくとも備えた適当な加熱アッセンブリー１１４を含む。この時間制御手段は、使用者のスケジュールに基づく適用時間をセットアップする。温度制御手段は、特定の温度（セットアップ温度）まで加熱し、その温度に維持させるもので、例えば、少なくとも１つの金属ヒータ１１６を有する。この金属ヒータ１１６はロジック回路により制御される。調整可能な加熱アッセンブリー１１４は使用者のセットアップにより制御され、バクテリアの培養およびバクテリア分解物の蒸発のための規則的な熱勾配を発生させる。第２のボトル１２２が底部仕切り室１０４の内部および底部に配置される。この第２のボトル１２２は、宿主匂いシミュレータ、例えばバクテリア分解物を有する。培地で特定の微生物（バクテリア）を培養することにより、代謝生成物が発生し、培地を分解し、バクテリア分解物を生成させる。好ましくは、先に使用されたコリネバクテリア菌株および培養条件が用いられる。例えば、ＮＢ（ペプトン５ｇ＋牛肉抽出物１．５ｇ＋イースト抽出物１．５ｇ＋ＮａＣｌ５ｇ／Ｌ；ｐＨ＝７．４）で生育されたＢＥ９５８６菌株がバクテリア分解物を生成させるのに使用される。ヒータ１１６は底部仕切り室１０４の内側および第２のボトル１２２の上に設けられ、底部仕切り室１０４を加熱し、第２のボトル１２２内の微生物培養のための熱を供給する。逆漏斗１１８が用いられ、ヒータ１１６により供給された熱を底部仕切り室１０４内に集め、上部仕切り室１０２に熱を移動させ、酵母発酵のための熱を供給する。その結果、２つの仕切り室に２つの異なる熱領域が形成される。上部仕切り室１０２および底部仕切り室１０４の熱領域はそれぞれ約３０℃および３７℃であることが好ましい。この２つの仕切り室の熱領域の維持により、微生物の培養およびバクテリア培地で生成する誘引物質の発生のための熱が供給される。更に、この熱領域の維持は体温に似せさせ、蚊を誘引するための誘引媒体として作用する。
【００２０】
蚊、Aedes aegypti種に対し匂いシミュレータと組み合わせたときの熱の作用の実験によれば、熱の蒸発と併用されたバクテリア分解物により蚊の６０％を誘引することができ、これは酵母の発酵により６０分間で誘引された蚊の４４％よりも大きいものであった。更に、バクテリアの分解、酵母の発酵、熱の蒸発の組み合わせにより相乗効果が生じ、臭覚計での１２時間の培養により捕捉された蚊は８５％に達した。バクテリア分解物を蚊の誘引物として或る時間、使用したところ、他の誘引物の場合と比較して、より多くの蚊を誘引することができたが、これは蚊の宿主探求行動における匂いの圧倒的影響によるものと思われる。
【００２１】
図２Ａは本発明の好ましい１例に係わる装置の斜視図；図２Ｂは図２Ａの装置の要部分解斜視図であり、図２Ｂは図２Ａの装置の要部分解斜視図である。
図２Ａを参照すると、装置２００には上部仕切り室２０２と、底部仕切り室２０４とが設けられ、ネジ付き容器２０６により接続されている。
図２Ｂを参照すると、装置２００が部分的に分解した斜視図として示され、装置の詳細が図示されている。第１のボトル２２０はグリッド固定具２２４の上に装着されている。ネジ付き容器２０６は、上部ネジ部２２６と、底部ネジ部２２８とを具備し、上部仕切り室２０２および底部仕切り室２０４をそれぞれ嵌合させると共に、上部ネジ部２２６と、底部ネジ部２２８との間にグリッド２１２を嵌合させている。第１のＯ−リング２３０と第２のＯ−リング２３２が、上部仕切り室２０２と、底部仕切り室２０４とをネジ付き容器でそれぞれシールするのに用いられている。グリッド固定具２２４はグリッド２１２上に配置され、上部仕切り室２０２をネジ付き容器２０６と嵌合させたのち、第１のボトル２２０が上部仕切り室２０２内に配置されるようになっている。なお、収集ウェブ２３４をグリッド固定具２２４とグリッド２１２との間に配置させ、死んだ蚊を収集するようにしてもよい。この収集ウェブ２３４は粘着物質を含んでもよく、これにより蚊又は殺虫剤を捕捉し、蚊を死亡させることもできる。更に、電気的グリッドを上部仕切り室２０２に設け、蚊を殺すようにしてもよい。
【００２２】
図２Ｂを参照すると、底部仕切り室は、着脱可能なアンダーキャリッジ２３８を備えたボトル固定具２３６を含んでいてもよい。第２のボトル２２２はボトル固定具２３６内に固定されている。着脱可能なアンダーキャリッジ２３８はボトル固定具２３６から取外すことができ、第２のボトル２２２を際充填したり、洗浄したりすることができる。ヒータ２１６および逆漏斗２１８はボトル固定具２３６の上に配置される。逆漏斗２１８はグリッド２１２の中央に面して狭い開口部を有し、底部仕切り室２０４に面して広い開口部を有する。それにより、チャンバーからあつめられた熱をグリッド２１２を介して上部仕切り室２０２に移動させることができる。
【００２３】
（誘引物放出ユニット）
本発明の他の好ましい例として、上記装置に更に、蚊用誘引物の放出、蒸発を促進させるための誘引物放出手段を含めることができる。この誘引物放出手段は、例えば、誘引物を細かな液滴として（例えば、約５−５０ミクロン）周囲に拡散させるためのスプレー機構を利用するものである。それにより、或る空間での誘引物の拡散速度および蒸発速度が高められ、誘引物の効率を向上させ、蚊を誘引する有効距離を増大させる。
【００２４】
本発明の誘引物放出手段の１例として誘引物放出ユニットが図３に他の好ましい例として模式図で示されている。図３において、誘引物放出（誘引物スプレー）ユニット３００は上記装置（図３で３０３として示す）の内部に、上部仕切り室の内部に、底部仕切り室の内部に、第２のボトルの内部に、あるいは上部仕切り室と底部仕切り室との間に配置される。更に、誘引物放出ユニット３００を電気的グリッドを結合させてもよい。
【００２５】
誘引物放出ユニット３００は、ステンレス鋼からなるスプレーノズル３０２と、小さなエアポンプ３０４とからなる。エアポンプ３０４は、エアカートリッジ又は他の同様の機能の機構で置換してもよい。スプレーノズル３０２は、外側チューブ３０６と、内側チューブ３０８とを具備し、これらは入れ子式になっている。
【００２６】
エアポンプ３０４は、チューブ３０９を介して空気をスプレーノズル３０２の内側チューブ３０８に加圧、導入するものである。外側チューブ３０６が蚊用誘引物（液状）内に挿入されるので、裂け目３１０が外側チューブ３０６の底に形成され、液状誘引物がサイホンの作用により、スプレーノズル３０２のキャップ３１２に達する。内側チューブ３０８に圧入された空気は小孔３１４を介して高速で噴射され、誘引物を非常に小さな液滴として放出させる（図３に矢線で示す）。この液滴は平均径が約５−５０ミクロンであり、従って、揮発性で、拡散が容易な霧状になる。
【００２７】
この装置３０３は、誘引物が大きな固まりで拡散されるのを防止するための外側シェルを有する。それにより、微細な液滴のみが周囲に拡散されることになる。従って、各液滴は急速、かつ、容易に蒸発し、誘引物の効率を高め、蚊を誘引する有効距離を増大させる。
【００２８】
従って、誘引物放出ユニットは誘引物を微細な液滴として外部に拡散させるから、或る空間での誘引物の拡散速度および蒸発速度が高められ、蚊を誘引する有効距離を増大させ、蚊用誘引物の効率を最大限に向上させることができる。
【００２９】
蚊誘引物質と組み合わせた場合の誘引物放出ユニットの効果を試験するため、蚊、Aedes aegypti種に対し３．５ｍ ｘ３．５ｍ ｘ ３ｍの部屋で実験を行った。その結果、蚊の捕捉率が３０％（誘引物放出ユニットを有しない場合）から、９０％（誘引物放出ユニットを有する場合）に増大させることができた。
【００３０】
従って、本発明の誘引物放出ユニットは、蚊用誘引物の拡散を増大させ、蚊の誘引を向上させ、それにより蚊の捕捉率を増大させることができる。更に、上述の蚊放出手段によるスプレー機構に代えて、気泡放出機構を使用し、蚊用誘引物の拡散を助けるようにしてもよい。溶液を有する特定の発泡剤間の化学的反応を介して、ガス、例えば炭酸ガスなど発生させ、周囲への誘引物の吹き付けを生じさせるようにしてもよい。従って、誘引物の放出が向上し、蚊の誘引を更に強化させることができる。この気泡吹き付け機構の１つの利点は、電力を必要としないから、殺虫剤又は粘着剤との組み合わせで屋外での使用に適している。
【００３１】
以上、本発明の趣旨を逸脱することなく、本発明の構成に対し種々の変更、改良が可能であることは当業者に自明であろう。上記記載に鑑み、本発明はそのような変更、改良も特許請求の範囲およびその均等物に含まれる限り、本発明により包含されることを意図している。
【図面の簡単な説明】
【図１】本発明の好ましい１例に係わる装置を示す模式図。
【図２】図２Ａは本発明の好ましい１例に係わる装置の斜視図；図２Ｂは図２Ａの装置の要部分解斜視図。
【図３】本発明の好ましい他の例に係わる装置における餌放出ユニットを示す模式図。
【符号の説明】
１００ 装置
１０２ 上部仕切り室
１０４ 底部仕切り室
１０６ 蝶ネジ容器
１０８ シールド
１１０ 通過チャンネル
１１２ グリッド
１１６ 金属ヒータ
１１８ 逆漏斗
１２０ 第１のボトル
１２２ 第２のボトル[0001]
BACKGROUND OF THE INVENTION
The present invention relates to means for insect control. In particular, the present invention relates to a microorganism-mediated mosquito attracting method for controlling and destroying mosquitoes.
[0002]
[Background Art and Problems to be Solved by the Invention]
There has been a great demand for insect control in human history. It is necessary to control harmful insects such as mosquitoes and prevent the spread of diseases such as malaria and yellow fever. In public health facilities around the world, strong efforts have been made to eliminate mosquito-related illnesses, but due to the difficulty in controlling mosquitoes, the efforts as a whole have not been successful. Besides eliminating mosquito-related illnesses, another reason to get rid of mosquitoes is to eliminate the harm of mosquito bites. Accordingly, there has been a long-standing need for effective mosquito control measures, including attracting, capturing and destroying active mosquitoes.
[0003]
Female mosquitoes seek human hosts and get blood as a meal for eggs. Mosquitoes find the host through a combination of chemicals that characterize this host. Volatile substances generated from the human host are considered to be mosquito attractants. This volatile material contains 300-400 compounds and emanates from the secretions of the skin glands and / or the skin microflora. Mosquitoes can detect this attractant from a distance as long as 90 meters by its olfactory mechanism.
[0004]
Conventional control methods have only been able to attack mosquito populations as a whole or remove mosquito sources by chemical means. These methods are cumbersome, labor intensive, and often the environment is destroyed by the hazardous amount of toxic chemicals. Other attempts have been made to make mosquito traps. Light, warm air, carbon dioxide, octenol, water vapor, and lactic acid are used as attractants to trap mosquitoes with traps.
[0005]
[Means for Solving the Problems]
The present invention provides a method for controlling female mosquitoes that consume blood and a mosquito that does not require a host, using bacterial degradation products and yeast fermentation products as attractants. In the present invention, a combination of heat and a pseudo-attractant is used to achieve a particularly effective attraction. Furthermore, in the present invention, an attractant release mechanism is used in combination, and this attractant release mechanism facilitates spreading the mosquito attractant around. Furthermore, the present invention provides a mosquito trapping method for controlling mosquitoes and destroying mosquitoes after trapping.
[0006]
Another object of the present invention is to provide a method and apparatus for generating an attractant for mosquitoes, and for generating something that mimics the surface temperature and smell of a human body. A controlled heating assembly is used to generate an appropriate thermal gradient for microbial culture and attractant evaporation. This attractant release can be further facilitated by an attractant release unit. This attractant includes at least a yeast fermentation product and a microbial culture. This attractant is non-toxic to the human body and generates a mosquito attractant with natural products from fermentation and degradation. The present invention can be combined with an electrocution grid for destroying attracted mosquitoes and an insecticidal web.
[0007]
As specifically or broadly described herein, the present invention provides a portable mosquito control system for capturing mosquitoes that can be used indoors and outdoors, the system comprising a plurality of channels, An upper partition chamber in which an opening for introducing and capturing mosquitoes is formed in the channel; a bottom partition chamber; and a threaded container for connecting the upper partition chamber and the bottom partition chamber . This threaded container comprises at least an upper screw, a lower screw, and a grid provided between the upper screw and the lower screw. The mosquito control system further includes a first fixture holding a first bottle containing at least a yeast fermentation product, a second fixture holding a second bottle containing at least a microorganism culture, Controllable heating means for generating heat for the microbial culture and the yeast fermented product.
[0008]
Here, as specifically or broadly described, the present invention includes an attractant release unit for facilitating the release of the attractant to the surroundings. This attractant releasing unit utilizes a spray mechanism that diffuses the attractant as fine droplets (mists) around it. Therefore, the diffusion rate and evaporation rate of the attractant in a certain space are increased, increasing the efficiency of the attractant for mosquitoes and increasing the effective distance for attracting mosquitoes. The attractant release unit has a spray nozzle and a pump. The spray nozzle has an inner tube and an outer tube. The outer tube acts like a siphon, drawing liquid from outside the spray nozzle and raising the liquid above the spray nozzle. Air or gas is introduced into the outer tube by a pump and is injected at high speed from the top hole of the inner tube. Accordingly, the liquid attractant is diffused as fine droplets (mists), which promotes the attractant diffusion and evaporation. The above and following descriptions are merely examples, and are intended to explain the scope of the claims in more detail.
[0009]
DETAILED DESCRIPTION OF THE INVENTION
The accompanying drawings are included to make the invention easier to understand and form part of the specification. FIG. 1 is a schematic view showing an apparatus according to a preferred example of the present invention. 2A is a perspective view of an apparatus according to a preferred example of the present invention, and FIG. 2B is an exploded perspective view of a main part of the apparatus of FIG. 2A. FIG. 3 is a schematic view showing an attractant discharging unit in an apparatus according to another preferred example of the present invention.
[0010]
Corynebacteria present in human sweat are known to generate methanethiol that is released as a cheese and foot odor. These microorganisms are thought to be responsible for generating human odors from respiration. Evidence for direct microorganisms involved in generating volatile attractants in the human host has been demonstrated from the enhancement of attractants by sweat culture. Therefore, it is beneficial to identify these microorganisms, and these microorganisms are used as a means to attract blood-sucking mosquitoes to resemble human odors.
[0011]
For male mosquitoes, nectar is the only food, and many types of female mosquitoes take carbohydrate meal before eating blood. In the process of searching for a host, sugar appears to be an energy source, and the first difference in energy conservation also affects the host's response to volatiles. It has been reported in dose-dependent responses that carbon dioxide is an attractant regardless of the type of mosquito. In the present invention, the mosquito attractant includes a human odor simulator resembling a volatile substance of a human host, a sugar source, and a carbon dioxide supply source. The human odor simulator is supplied by a specific bacterial degradation product, and the steadily increasing carbon dioxide concentration and the scented sugar meal can be supplied by yeast fermentation using fruit juice used as a culture medium.
[0012]
【Example】
Several experiments were conducted on mosquitoes as follows.
Mosquitoes: Aedes aegypti was maintained at 23-25 ° C. and examined under conditions of 60-80% relative humidity, 12 hours bright / 12 hours dark. Adults were housed in a cocoon covered with 30 cm3 of gauze and bred with a 10% (v / v) sugar solution. In the bioassay, 4-8 day old female mosquitoes that had not been given blood were opened in a 2-port olfactometer. The olfactometer consisted of a flight chamber (1.6m x 0.6m x 0.6m) in which mosquitoes were released. Air from the room is filtered through charcoal, passed through one of two distilled water bottles, two port bodies (diameter 5 cm, 30 cm apart), then introduced into the flight chamber I let you. The odor source was placed at the port and the temperature was maintained at 30 ° C. by the circulating water system. On the other hand, the room temperature was maintained at 23-25 ° C. The bioassay was observed for 15 minutes after the mosquito was released. All parts of the olfactometer were cleaned with 75% alcohol between successive tests and blown with strong wind for 20 minutes. In addition, treatment and control positions were alternated between ports after each test to counteract the effects of biased direct responses from unknown sources.
[0013]
(Bacteria)
Two corynebacteria, Brevibacterium epidermidis (BE) and B. cerevisiae. The strains of linens (BL) were obtained from Deutsche Sammlung von Mikrooranismen and Zellkulturen GmbH, Braunschweig, Germany, Food Industry Research & Development Biotechnology, Taiwan. Bacteria were grown in three different media: TSB, MB, NB. The components of the three culture media are TSB (trypton 15 g + soyton 5 g + NaCl 5 g / L; pH = 7.3); MB (milk powder 50 g + peptone 2.5 g + NaCl 5 g / L; pH = 7.2); NB (peptone 5 g + beef 1.5 g of extract + 1.5 g of yeast extract + 5 g / L of NaCl; pH = 7.4). These were stirred at 30 ° C. and 200 rpm for 2 days.
For the most efficient mosquito attraction, 4 mL of 2 day old bacterial culture from different combinations was tested with an olfactometer to test different combinations of bacteria and culture.
[0014]
As shown in Table 1, most of the strains grew on any of these three media. However, the BE9585 strain did not grow and no attracting action was observed. Of these, only the BE9586 strain was found to have an attracting action in all of these media, and those cultured with the NB media showed the greatest attraction rate. In general, when no heating means was provided, the attracting action did not exceed 30%.
[0015]
Table 1. Bacterial media that attract adult female mosquitoes

^a : The degree of mosquito attraction was measured almost as a percentage.
“−” Indicates no attraction, “+” = 10%, “++” = 20%, “++++” = 30%.
^b : Not available [0016]
To further identify the aspirating action of BE9586 strain grown on NB medium, the bacterial culture was centrifuged and the supernatant was examined with an olfactometer. As shown in Table 2, as many as 86.7% of the adult female mosquitoes were attracted to the bacterial culture supernatant. This attraction was about 20% higher than the NB medium alone and 25% higher than that of the blank solution without odor source. This indicates that the volatile components released by the degradation of the bacterial culture can particularly attract adult female mosquitoes. In this examination, heating itself showed an attraction of 61.7%, which was higher than that of the previous unheated odor source. Furthermore, the heating device contributes to good evaporation of bacterial degradation products.
[0017]
Table 2. Attraction rate of mosquitoes attracted by bacterial culture supernatant (measured with olfactometer)
Supernatant liquid ^a gravy ^b blank ^c
86.7 ± 4.2 ^d 67.5 ± 4.2 61.7 ± 11.8
^a : 10,000 xg bacterial culture supernatant collected by centrifugation for 10 minutes.
^b : Culture medium for growing bacteria.
^c : Do not place an odor source at the port of the olfactometer.
^d : Number of attracted adult female mosquitoes / 30 × 100%.
The test was repeated three times. In each iteration, a new batch of 30 mosquitoes was released into the flight chamber.
[0018]
FIG. 1 is a schematic view showing an apparatus according to a preferred example of the present invention. In FIG. 1, the apparatus 100 is divided into an upper partition chamber 102 and a bottom partition chamber 104 and connected by a threaded container 106. A shield 108 is connected to the top of the upper compartment 102 by a support means, for example a support stock with an extension wall, to guide the mosquitoes to the passage channel. The shield 108 is separated from the upper compartment 102 about 1-2 cm apart. Under the shield 108, the top of the upper compartment 102 includes a plurality of passage channels 110 that are open toward the interior space of the upper compartment 102. The passage channel 110 has an opening that is large enough to allow mosquitoes to pass through, but is open on the inside so that incoming mosquitoes do not escape. After the upper partition chamber 102 is fitted into the threaded container 106, the first bottle 120 is placed inside the upper partition chamber 102 and on the grid 112 of the threaded container 106. The first bottle 120 has at least an odor simulator, a carbon dioxide supply source, and a sugar source. Preferably, the human odor simulator and the carbon dioxide supply source are provided by fermentation of yeast with a medium. The medium may be fruit juice that serves as a sugar source.
[0019]
Referring to FIG. 1, the bottom compartment 104 includes a suitable heating assembly 114 having at least time control means and temperature control means. This time control means sets up the application time based on the user's schedule. The temperature control means heats up to a specific temperature (setup temperature) and maintains the temperature, and includes, for example, at least one metal heater 116. The metal heater 116 is controlled by a logic circuit. The adjustable heating assembly 114 is controlled by the user's setup to generate a regular thermal gradient for bacterial culture and bacterial degradation product evaporation. The second bottle 122 is disposed inside and at the bottom of the bottom partition chamber 104. This second bottle 122 has a host odor simulator, such as a bacterial degradation product. By culturing a specific microorganism (bacteria) in the medium, a metabolite is generated, and the medium is decomposed to generate a bacterial decomposition product. Preferably, the previously used Corynebacterium strain and culture conditions are used. For example, strain BE9586 grown in NB (5 g peptone + 1.5 g beef extract + 1.5 g yeast extract + 5 g NaCl / pH; pH = 7.4) is used to produce bacterial degradation products. The heater 116 is provided inside the bottom partition chamber 104 and above the second bottle 122, heats the bottom partition chamber 104, and supplies heat for culturing microorganisms in the second bottle 122. A reverse funnel 118 is used to collect the heat supplied by the heater 116 in the bottom compartment 104, transfer the heat to the top compartment 102, and supply heat for yeast fermentation. As a result, two different thermal regions are formed in the two compartments. The hot regions of the upper partition chamber 102 and the bottom partition chamber 104 are preferably about 30 ° C. and 37 ° C., respectively. By maintaining the heat zone of the two compartments, heat is supplied for the cultivation of microorganisms and the generation of attractants generated in the bacterial medium. Furthermore, the maintenance of this heat zone resembles body temperature and acts as an attracting medium for attracting mosquitoes.
[0020]
Experiments on the action of heat when combined with an odor simulator against mosquitoes, Aedes aegypti species, can attract 60% of mosquitoes by bacterial degradation combined with heat evaporation, which is the fermentation of yeast Was greater than 44% of mosquitoes attracted in 60 minutes. In addition, a combination of bacterial degradation, yeast fermentation, and heat evaporation produced a synergistic effect, reaching 85% of mosquitoes captured by 12-hour culture on an olfactometer. When bacterial degradation products were used as mosquito attractants for some time, they were able to attract more mosquitoes compared to other attractants, but this is an odor in the mosquito's host-seeking behavior. It seems to be due to the overwhelming influence of.
[0021]
2A is a perspective view of an apparatus according to a preferred example of the present invention; FIG. 2B is an exploded perspective view of a main part of the apparatus of FIG. 2A, and FIG. 2B is an exploded perspective view of a main part of the apparatus of FIG.
Referring to FIG. 2A, the apparatus 200 is provided with an upper compartment 202 and a bottom compartment 204, which are connected by a threaded container 206.
Referring to FIG. 2B, the device 200 is shown as a partially exploded perspective view illustrating details of the device. The first bottle 220 is mounted on the grid fixture 224. The threaded container 206 includes an upper screw portion 226 and a bottom screw portion 228, and the upper partition chamber 202 and the bottom partition chamber 204 are fitted into each other, and between the upper screw portion 226 and the bottom screw portion 228. A grid 212 is fitted to the grid. A first O-ring 230 and a second O-ring 232 are used to seal the upper compartment 202 and the bottom compartment 204 respectively with a threaded container. The grid fixture 224 is disposed on the grid 212, and after the upper partition chamber 202 is fitted to the threaded container 206, the first bottle 220 is disposed in the upper partition chamber 202. The collection web 234 may be disposed between the grid fixture 224 and the grid 212 to collect dead mosquitoes. The collection web 234 may include an adhesive material, which can trap mosquitoes or insecticides and kill mosquitoes. Furthermore, an electrical grid may be provided in the upper partition chamber 202 to kill mosquitoes.
[0022]
Referring to FIG. 2B, the bottom compartment may include a bottle fixture 236 with a removable undercarriage 238. The second bottle 222 is fixed in the bottle fixture 236. The removable undercarriage 238 can be removed from the bottle fixture 236, and the second bottle 222 can be refilled and washed. A heater 216 and reverse funnel 218 are disposed on the bottle fixture 236. The reverse funnel 218 has a narrow opening facing the center of the grid 212 and a wide opening facing the bottom compartment 204. Thereby, the heat collected from the chamber can be moved to the upper partition chamber 202 via the grid 212.
[0023]
(Attractor release unit)
As another preferred example of the present invention, the apparatus may further include an attractant releasing means for promoting the release and evaporation of the mosquito attractant. This attractant releasing means utilizes, for example, a spray mechanism for diffusing the attractant as fine droplets (for example, about 5 to 50 microns). Thereby, the diffusion rate and evaporation rate of the attractant in a certain space are increased, improving the efficiency of the attractant and increasing the effective distance for attracting mosquitoes.
[0024]
An attractant releasing unit as an example of the attractant releasing means of the present invention is shown in a schematic diagram as another preferred example in FIG. In FIG. 3, the attractant release (attractant spray) unit 300 is located inside the above apparatus (shown as 303 in FIG. 3), inside the upper compartment, inside the bottom compartment, and inside the second bottle. Alternatively, it is disposed between the upper partition chamber and the bottom partition chamber. Furthermore, the attractant discharge unit 300 may be coupled with an electrical grid.
[0025]
The attractant discharge unit 300 includes a spray nozzle 302 made of stainless steel and a small air pump 304. The air pump 304 may be replaced with an air cartridge or other similar functional mechanism. The spray nozzle 302 includes an outer tube 306 and an inner tube 308, which are nested.
[0026]
The air pump 304 pressurizes and introduces air into the inner tube 308 of the spray nozzle 302 via the tube 309. Since the outer tube 306 is inserted into the mosquito attractant (liquid), a tear 310 is formed at the bottom of the outer tube 306, and the liquid attractant reaches the cap 312 of the spray nozzle 302 by the action of siphon. The air injected into the inner tube 308 is jetted at high speed through the small holes 314, causing the attractant to be released as very small droplets (indicated by arrows in FIG. 3). The droplets have an average diameter of about 5-50 microns, and are therefore volatile and misty for easy diffusion.
[0027]
This device 303 has an outer shell to prevent the attractant from spreading in large chunks. Thereby, only fine droplets are diffused around. Thus, each droplet evaporates quickly and easily, increasing the efficiency of the attractant and increasing the effective distance for attracting mosquitoes.
[0028]
Therefore, the attractant releasing unit diffuses the attractant to the outside as fine droplets, so that the diffusion rate and evaporation rate of the attractant in a certain space are increased, increasing the effective distance for attracting mosquitoes, The efficiency of attractants can be maximized.
[0029]
In order to test the effect of the attractant release unit when combined with a mosquito attractant, experiments were conducted in a 3.5 m x 3.5 m x 3 m room for mosquitoes and Aedes aegypti species. As a result, the capture rate of mosquitoes could be increased from 30% (when no attractant release unit was provided) to 90% (when an attractant release unit was provided).
[0030]
Therefore, the attractant release unit of the present invention can increase the diffusion of the attractant for mosquitoes, improve the attraction of mosquitoes, and thereby increase the capture rate of mosquitoes. Furthermore, instead of the spray mechanism by the mosquito discharge means described above, a bubble discharge mechanism may be used to help spread the mosquito attractant. A gas such as carbon dioxide gas may be generated through a chemical reaction between a specific blowing agent having a solution to cause blowing of an attractant to the surroundings. Therefore, the release of the attractant is improved and the attraction of mosquitoes can be further enhanced. One advantage of this bubble blowing mechanism is that it does not require power and is therefore suitable for outdoor use in combination with an insecticide or adhesive.
[0031]
It will be apparent to those skilled in the art that various modifications and improvements can be made to the configuration of the present invention without departing from the spirit of the invention. In view of the above description, the present invention is intended to be encompassed by the present invention as long as such modifications and improvements are encompassed by the claims and their equivalents.
[Brief description of the drawings]
FIG. 1 is a schematic view showing an apparatus according to a preferred example of the present invention.
2A is a perspective view of an apparatus according to a preferred example of the present invention; FIG. 2B is an exploded perspective view of a main part of the apparatus of FIG. 2A.
FIG. 3 is a schematic view showing a bait releasing unit in an apparatus according to another preferred embodiment of the present invention.
[Explanation of symbols]
100 apparatus 102 upper compartment 104 bottom compartment 106 thumbscrew container 108 shield 110 passage channel 112 grid 116 metal heater 118 reverse funnel 120 first bottle 122 second bottle

Claims (3)

A portable mosquito control system for capturing mosquitoes that can be used indoors and outdoors,
It includes a plurality of channels, an upper compartment in which the channel is open toward the inside in order that is captured by introducing mosquitoes;
A bottom compartment;
A threaded container for connecting the upper compartment and the bottom compartment, is provided between the at least top negate di, and lower negate di, and upper negate di and lower negate di grid and, shall become comprises a;
A first fixture for holding a first bottle, wherein the first bottle contains at least a first mosquito attractant, and the first mosquito attractant contains at least a yeast fermentation product. When;
A second fixture for holding a second bottle, wherein the second bottle contains at least a second mosquito attractant, and the second mosquito attractant includes at least a microbial culture. When;
Controllable heating means for generating heat for the microbial culture and yeast fermentation;
An attractant release unit for assisting release of the first mosquito attractant and the second mosquito attractant , comprising a spray nozzle and a pump. A method for controlling mosquitoes by capturing mosquitoes, the method comprising:
Providing a mosquito trap comprising at least means for introducing mosquitoes and means for capturing mosquitoes;
A mosquito attractant for attracting mosquitoes, wherein the medium is TSB (trypton 15 g + soyton 5 g + NaCl 5 g / L; pH 7.3), MB (milk powder 50 g + peptone 2.5 g + NaCl 5 g / L; pH 7.2), and NB (peptone 5 g + beef extract 1.5 g + yeast extract 1.5 g + NaCl 5 g / L; pH 7.4), and Brevibacterium is a group consisting of BE9586, BE20659, BE20660, BL20158, BL20425 and BL20426 The combination of BE20660 and TSB culture medium, the combination of BE20659 and MB culture medium, the combination of BE9586 and NB culture medium, the combination of BE9586 and MB culture medium, the culture of BE9586 and TSB Pair with group Combination of BL20158 and MB culture, BL20425 and MB culture, BL20426 and TSB culture, BL20426 and MB culture, or BL20426 and NB culture In combination with and containing a bacterial degradation product produced by Brevibacterium growing on the culture medium ;
Containing the mosquito attractant in the mosquito trap so that the mosquito attracted by the mosquito attractant is captured by the mosquito trap;
An attractant releasing means for facilitating the release of the mosquito attractant, wherein the means for blowing air to promote diffusion of the mosquito attractant is provided;
Providing heat for cultivating the mosquito attractant, which promotes the emission of odors from the mosquito attractant so that the heat resembles body temperature and acts as a mosquito attracting element thing;
A method comprising: A method for attracting mosquitoes, the method comprising:
A mosquito attractant for attracting mosquitoes , wherein the medium is TSB (trypton 15 g + soyton 5 g + NaCl 5 g / L; pH 7.3), MB (milk powder 50 g + peptone 2.5 g + NaCl 5 g / L; pH 7.2), and NB (peptone 5 g + beef extract 1.5 g + yeast extract 1.5 g + NaCl 5 g / L; pH 7.4), and Brevibacterium is a group consisting of BE9586, BE20659, BE20660, BL20158, BL20425 and BL20426 The combination of BE20660 and TSB culture medium, the combination of BE20659 and MB culture medium, the combination of BE9586 and NB culture medium, the combination of BE9586 and MB culture medium, the culture of BE9586 and TSB Pair with group Combination of BL20158 and MB culture, BL20425 and MB culture, BL20426 and TSB culture, BL20426 and MB culture, or BL20426 and NB culture In combination with and containing a bacterial degradation product produced by Brevibacterium growing on the culture medium ;
It generates the bacterial degradation product, comprising: providing a heat for releasing mosquito attractants evaporated該蚊for attractants, a combination of odors from bacteria degradation products resembling該蚊attractants Gahi DOO Including at least the heat mimicking body temperature and acting as a mosquito attracting element;
An attractant releasing means for facilitating the release of the mosquito attractant, wherein the means for blowing air to promote diffusion of the mosquito attractant is provided;
A method comprising:

Images