Artificial KiwiPollination Technologies: A Review 獼猴桃人工授粉技術(shù)綜述

幾十年來，少數(shù)行業(yè)——主要是石果、果脯和獼猴桃——使用從手動施藥器到拖拉機(jī)安裝的噴霧系統(tǒng)等各種授粉技術(shù)成功收集和施用花粉。獼猴桃是人工授粉的旗艦作物，其雌雄異株性（雄花和雌花在不同的植物上）、缺乏花蜜和坐果的高潛力導(dǎo)致了人工授粉的早期探索。這項(xiàng)研究表明，用人工授粉補(bǔ)充昆蟲傳粉者可以提高坐果率和果實(shí)質(zhì)量[14,15]。新西蘭早期試驗(yàn)的成功導(dǎo)致了一系列花粉輸送裝置的開發(fā)，這些裝置減少了勞動力，使人工授粉成為許多種植者的重要工具，并已成為意大利[16]、中國南方[17,18]和韓國[19]使用的主要策略。在其他地方，它被用作補(bǔ)充授粉策略，新西蘭大約一半的獼猴桃種植者使用補(bǔ)充人工授粉。幾家新西蘭公司對獼猴桃花粉進(jìn)行商業(yè)收割和研磨，并將其供應(yīng)給國內(nèi)和全球種植者[20,21]。為獼猴桃開發(fā)的工具已經(jīng)適應(yīng)并用于其他種植系統(tǒng)。

文獻(xiàn)中也對梨果、石果、杏仁和椰棗的田間人工授粉進(jìn)行了探索，早期的工作也發(fā)生在樹堅(jiān)果中，最近Eyles等人對此進(jìn)行了綜述[25]。在蘋果中，田間試驗(yàn)很早就開始了，涉及噴霧機(jī)[26]、廣播拖拉機(jī)噴霧器[27]，甚至炸藥[26]——盡管結(jié)果往往令人失望，產(chǎn)量或質(zhì)量幾乎沒有改善。最近的工作有利于手持設(shè)備，以及安裝在車輛上的噴霧器和鼓風(fēng)機(jī)，這些設(shè)備在許多作物上都顯示出了產(chǎn)量效益[25,28]。總的來說，迄今為止，人工授粉的普及程度并不高，但隨著技術(shù)走出實(shí)驗(yàn)室，其普及速度正在加快。

▲Kiwi insect pollination

Most artificial pollination technologies require a high-quality source of pollen to be successful—a chicken-and-egg situation for crop producers in places that lack existing pollen harvesting and supply infrastructure, although a number of small-scale pollen collection methodologies exist. Despite these limitations, the last decade has seen many researchers, as well as small and start-up companies, take on the pollination challenge, evidenced by the increasing numbers of patents published regarding artificial pollination devices (Figure 1 and Figure 2; Appendix A).

大多數(shù)人工授粉技術(shù)需要高質(zhì)量的花粉來源才能成功，這對缺乏現(xiàn)有花粉采集和供應(yīng)基礎(chǔ)設(shè)施的地方的作物生產(chǎn)者來說是一種雞和蛋的局面，盡管存在一些小規(guī)模的花粉采集方法。盡管存在這些局限性，但在過去的十年里，許多研究人員以及小型和初創(chuàng)公司都面臨著授粉挑戰(zhàn)，這可以從越來越多的人工授粉設(shè)備專利中得到證明（圖1和圖2；附錄A）。

▲Kiwi insect pollination

2.花粉采集

The quantity of pollen required for artificial pollination depends on both the crop species and the device used to deliver it. Some crops, such as date palm and anemophilous (wind-pollinated) trees, produce large quantities of pollen that is relatively easy to collect. However, most crops, including almond, apple, and kiwifruit, produce a relatively small number of pollen grains per flower and require more labour [29]. This suggests two goals for practical artificial pollination: securing a supply of inexpensive, high-quality pollen, and ensuring that as little pollen as possible is wasted during application.

人工授粉所需的花粉量取決于作物種類和用于輸送花粉的設(shè)備。一些作物，如椰棗和風(fēng)媒（風(fēng)媒授粉）樹，會產(chǎn)生大量相對容易收集的花粉。然而，大多數(shù)作物，包括杏仁、蘋果和獼猴桃，每朵花產(chǎn)生的花粉粒數(shù)量相對較少，需要更多的勞動力[29]。這為實(shí)用的人工授粉提出了兩個(gè)目標(biāo)：確保廉價(jià)、高質(zhì)量的花粉供應(yīng)，并確保在應(yīng)用過程中浪費(fèi)盡可能少的花粉。

▲Bees pollinate kiwifruit

Pollen is typically most viable at the time of anthesis [30], just as the anthers begin to release pollen. However, collecting flowers at this stage can result in significant pollen losses, as flowers can release the majority of their pollen on the day of anthesis [15,28]. To obtain the highest quantity of pollen per flower, it is generally preferable to harvest immediately prior to anthesis to prevent pollen losses [30].
花粉通常在開花時(shí)最具活力[30]，就像花藥開始釋放花粉一樣。然而，在這個(gè)階段收集花朵可能會導(dǎo)致花粉大量流失，因?yàn)榛ǘ淇梢栽陂_花當(dāng)天釋放大部分花粉[15,28]。為了獲得每朵花的最高花粉量，通常最好在開花前立即收獲，以防止花粉損失[30]。

▲Bees pollinate kiwifruit

Three approaches have been taken to collecting pollen: hand-picking or mechanically harvesting flowers just prior to anthesis and extracting the pollen; vacuuming pollen directly from flowers; and using pollen traps attached to honey bee hive entrances to obtain bee-collected pollen from the crop (Figure 3).
收集花粉有三種方法：在開花前手工采摘或機(jī)械收割花朵并提取花粉；直接從花中吸出花粉；并使用附著在蜜蜂蜂箱入口的花粉陷阱從作物中獲取蜜蜂采集的花粉（圖3）。
Hand-picking individual flowers, inflorescences, or panicles has been successful in plants that produce copious quantities of pollen. For date palm, entire panicles are harvested, dried, and then filtered [28]. The tassels, strobili, or catkins (male reproductive structures) of wind-pollinated plants can be handled similarly [24,31,32,33,34,35].
在產(chǎn)生大量花粉的植物中，手工采摘單個(gè)花朵、花序或圓錐花序是成功的。對于椰棗，整個(gè)穗被收獲、干燥，然后過濾[28]。風(fēng)媒傳粉植物的流蘇、球果或柳絮（雄性生殖結(jié)構(gòu)）可以類似地處理[24,31,32,33,34,35]。

▲Bees pollinate kiwifruit

Entomophilous plants (pollinated by insects) typically produce less pollen, making collection more challenging. Anthers can be manually excised from individual flowers—an approach employed in artificial pollination research [36,37], but the method is labour-intensive and is economical only for small-scale application (e.g., breeding programmes, vanilla and cacao pollination). Larger-scale pollination was enabled by methods of mechanically separating pollen from whole flowers for kiwifruit [15,23,38,39], cherimoya [30], date palm [22,28], and almond [40]. This typically involves drying the collected flowers, milling the flowers to separate the anthers from other floral structures, allowing the anthers to dehisce under controlled conditions, and using a filter- or cyclone-type cleaning machine that extracts the anthers and pollen, which can then be dried. The pollen is then extracted using a sieve attached to a vacuum. Anther-drying has been identified as a rate-limiting step in the pollen-milling process outlined above, but attempts to reduce drying time by increasing temperature or air-flow negatively affect viability beyond a certain point [15].
昆蟲學(xué)植物（由昆蟲授粉）通常產(chǎn)生的花粉較少，這使得采集更具挑戰(zhàn)性。花藥可以從單朵花上人工切除——這是人工授粉研究中采用的一種方法[36,37]，但這種方法勞動密集，僅適用于小規(guī)模應(yīng)用（如育種計(jì)劃、香草和可可授粉）。通過機(jī)械分離獼猴桃[15,23,38,39]、番荔枝[30]、椰棗[22,28]和杏仁[40]全花花粉的方法，實(shí)現(xiàn)了更大規(guī)模的授粉。這通常涉及干燥收集的花朵，研磨花朵以將花藥與其他花結(jié)構(gòu)分離，使花藥在受控條件下開裂，并使用過濾器或旋風(fēng)式清潔機(jī)提取花藥和花粉，然后可以干燥。然后用真空篩提取花粉?；ㄋ幐稍镆驯淮_定為上述花粉碾磨過程中的限速步驟，但試圖通過提高溫度或空氣流量來減少干燥時(shí)間，會對超過某一點(diǎn)的存活率產(chǎn)生負(fù)面影響[15]。

▲播宏果業(yè)獼猴桃花粉旋風(fēng)分離采集花粉工序照片

Flowers are commonly sourced from growers (either to apply back to the same orchard, or sold for pollen processing), and increasingly, from orchards grown specifically to supply pollen. There are, however, several challenges with orchards dedicated to pollen production, including lower financial return than fruiting orchards and a very brief, high-labour demand for harvesting flowers. As a result, a combination of dedicated pollen production and fruiting orchards is likely to remain in use [41,42,43]. Anecdotally, harvest rates for manual picking vary wildly with the experience of pickers and orchard management practices. A mixed-sex kiwifruit orchard (not dedicated to pollen production), for example, could yield between 20 and 200 kg-flower/ha, with a typical yield of 30–40 kg-flower/ha from a well-trained team in a well-managed orchard. Picking rates vary from less than 1 kg-flower/day up to 40 kg-flower/day, although again this is heavily dependent on experience and orchard practice. Pollen yield for good male cultivars reportedly varies from 8.5 g/kg-flower up to 10.5 g/kg-flower with careful attention to the process. Poor-producing cultivars may yield only 4 g/kg-flower (pers. comm. Mat Johnston).
花卉通常來自種植者（要么用于回用同一果園，要么用于花粉加工），而且越來越多地來自專門為供應(yīng)花粉而種植的果園。然而，專門用于花粉生產(chǎn)的果園存在一些挑戰(zhàn)，包括比果園更低的經(jīng)濟(jì)回報(bào)，以及收獲花朵的勞動力需求非常短暫和高。因此，專門的花粉生產(chǎn)和果園很可能會繼續(xù)使用[41,42,43]。據(jù)傳，人工采摘的收獲率因采摘者的經(jīng)驗(yàn)和果園管理實(shí)踐而異。例如，一個(gè)混合性別的獼猴桃園（不專門用于花粉生產(chǎn)）每公頃可以生產(chǎn)20到200公斤的花，在管理良好的果園里，訓(xùn)練有素的團(tuán)隊(duì)每公頃的典型產(chǎn)量為30到40公斤的花。采摘率從每天不到1公斤花到每天40公斤花不等，盡管這在很大程度上取決于經(jīng)驗(yàn)和果園實(shí)踐。據(jù)報(bào)道，良好雄性品種的花粉產(chǎn)量從8.5克/千克花到10.5克/千克花不等，要仔細(xì)注意這一過程。產(chǎn)量低的品種可能只生產(chǎn)4克/公斤的花（通訊員馬特·約翰斯頓）。

▲Kiwi insect pollination

Recently, a mechanical pollen harvesting device has been developed for almond, which uses a tree shaker to dislodge flowers at full bloom, collecting them on a tarp beneath the tree [40,42]. Flowers are dislodged at various states of maturity, so pollen recovery rates are lower on a per-flower basis, but bulk harvesting significantly reduces the cost of collection. Harvesting machinery has also been developed for maize flowers, removing tassels for later milling and application in the production of hybrid maize seed [35]. More than 80 L of pollen can be collected each day with this machinery, a high yield made possible by the fact that maize is wind-pollinated and therefore produces large quantities of pollen [35].

最近，一種用于杏仁的機(jī)械花粉采集裝置已經(jīng)開發(fā)出來，該裝置使用樹木搖床在盛開時(shí)移走花朵，將它們收集在樹下的防水布上[40,42]?；ǘ湓诟鞣N成熟狀態(tài)下都會脫落，因此每朵花的花粉回收率較低，但批量收獲顯著降低了采集成本。還開發(fā)了玉米花收割機(jī)械，去除穗以備后續(xù)碾磨，并應(yīng)用于雜交玉米種子的生產(chǎn)[35]。使用這種機(jī)器每天可以收集超過80升的花粉，玉米是風(fēng)媒傳粉的，因此可以產(chǎn)生大量花粉，從而實(shí)現(xiàn)高產(chǎn)[35]。

Mechanical harvesting techniques are relatively new, so the primary driver of pollen cost is labour. In November 2022, during the pollination season, the price was NZD 8250/kg (USD 5200/kg) for kiwifruit pollen in New Zealand, and USD 7500–8500/kg for pipfruit and stonefruit pollen from the USA [44]. In contrast, date pollen is available at USD 150–225/kg in the USA and Mexico [28].

機(jī)械收割技術(shù)相對較新，因此花粉成本的主要驅(qū)動力是勞動力。2022年11月，在授粉季節(jié)，新西蘭的獼猴桃花粉價(jià)格為8250新西蘭元/公斤（5200美元/公斤），美國的梨果和石果花粉價(jià)格為7500-8500美元/公斤[44]。相比之下，在美國和墨西哥，棗花粉的價(jià)格為150-225美元/公斤[28]。

In the pursuit of less-expensive material for artificial pollination, there has been considerable interest in pollen collected by honey bees, despite its variable viability and purity. The impurities stem from two sources: honey bees mix pollen with nectar to form pollen pellets on their legs, and additionally may not be foraging exclusively on the target crop. Trials have successfully demonstrated fruit set using bee-collected pollen in kiwifruit [45,46,47], peach [48], apple [48,49], pear [48,50], almond [51,52], and canola [53]. Researchers found, however, that fruit drop was higher and fruit weight lower in flowers fertilised with bee-collected pollen instead of pure pollen. Consequently, higher application rates are required. Several studies have noted lower fruit set from bee-collected pollen, which was improved by washing it and formulating it to remove excess sugars, which otherwise appear to inhibit pollen germination [30,49,53]. A recent study found that pollen on bees’ bodies is much more able to achieve fruit set than that stored on their corbiculae; bees that do not pack their pollen with sugars (e.g.,?Megachile rotundata, Megachilidae;?Halictus?spp., Halictidae) do not show the same detrimental effect on pollination potential [53], but it has not yet been possible to collect pollen from these species at sufficient scale. More research into the handling and processing of bee-collected pollen is needed before it can be used for large-scale pollination.

為了尋找更便宜的人工授粉材料，人們對蜜蜂收集的花粉產(chǎn)生了相當(dāng)大的興趣，盡管其存活率和純度各不相同。這些雜質(zhì)來自兩個(gè)來源：蜜蜂將花粉與花蜜混合，在腿上形成花粉粒，而且可能不會只在目標(biāo)作物上覓食。試驗(yàn)已成功證明使用蜜蜂采集的花粉在獼猴桃[45,46,47]、桃[48]、蘋果[48,49]、梨[48,50]、杏仁[51,52]和油菜[53]中坐果。然而，研究人員發(fā)現(xiàn)，用蜜蜂采集的花粉而不是純花粉受精的花朵，落果率更高，果實(shí)重量更低。因此，需要更高的申請率。幾項(xiàng)研究發(fā)現(xiàn)，蜜蜂采集的花粉坐果率較低，通過清洗和配制花粉以去除多余的糖來改善坐果率，否則這些糖似乎會抑制花粉萌發(fā)[30,49,53]。最近的一項(xiàng)研究發(fā)現(xiàn)，蜜蜂身上的花粉比儲存在球莖上的花粉更容易坐果；不將花粉包裹在糖中的蜜蜂（例如，圓斑大蜂、圓斑大蚊科、Halictus spp.、Halictidae）對授粉潛力沒有同樣的不利影響[53]，但還不可能以足夠的規(guī)模從這些物種中收集花粉。在將蜜蜂采集的花粉用于大規(guī)模授粉之前，需要對其處理和加工進(jìn)行更多的研究。

Pollen can also be vacuumed directly from some flowers, catkins, or strobili. The viability of pollen collected in this way is generally much higher than that with other methodologies [30,38]. Furthermore, in some designs, the vacuum may be reversed to apply collected pollen immediately without further processing or storage. Vacuum collection has successfully been employed to collect quantities of larch [54], Douglas fir [55], olive (manual [23], mechanised [30]), kiwifruit [23,38,56], and cannabis [57] pollen. Pollen yield varies with plant species, with yields 500 cc/h being reported for Douglas fir [55], 140 g/h being reported in kiwifruit [38] and 100–200 g/h in olive (cultivar-dependent [23]). A handful of prototype mechanical pollen-harvesting systems have been developed to vacuum pollen from trees. These rely on surrounding the tree with a vacuum and filtration system, while using a tree shaker to release the pollen (olive [30], larch [54]). These mechanised systems can harvest up to ten times the quantity of pollen as handheld vacuum devices can, although the pollen tends to be of somewhat lower quality [54].

花粉也可以直接從一些花、柳絮或球果中抽出。以這種方式收集的花粉的存活率通常遠(yuǎn)高于其他方法[30,38]。此外，在某些設(shè)計(jì)中，可以顛倒真空狀態(tài)，立即施加收集到的花粉，而無需進(jìn)一步加工或儲存。真空收集已成功用于收集大量落葉松[54]、花旗松[55]、橄欖（手動[23]、機(jī)械化[30]）、獼猴桃[23,38,56]和大麻[57]花粉?；ǚ郛a(chǎn)量因植物種類而異，道格拉斯冷杉的產(chǎn)量為500毫升/小時(shí)[55]，獼猴桃的產(chǎn)量為140克/小時(shí)[38]，橄欖的產(chǎn)量為100-200克/小時(shí)（取決于品種[23]）。已經(jīng)開發(fā)了一些原型機(jī)械花粉采集系統(tǒng)，用于從樹木中真空采集花粉。這些依賴于用真空和過濾系統(tǒng)包圍樹木，同時(shí)使用樹木搖床釋放花粉（橄欖[30]，落葉松[54]）。這些機(jī)械化系統(tǒng)可以收獲的花粉量是手持真空設(shè)備的十倍，盡管花粉的質(zhì)量往往較低[54]。

Different processes are explored in Figure 3.

After collection and processing, binucleate pollen can be put into cold storage and kept viable, often for several years. Storage conditions for particular species have been explored thoroughly in the literature on germplasm maintenance and plant breeding (recently reviewed by [58]). As long as the cold chain is maintained, it is not uncommon to be able to store pollen at ?20 °C for 1–6 years with little loss of viability [23,28,58], giving producers flexibility to apply pollen from one year to the next, helping to mitigate synchronicity and production risks.

圖3探討了不同的過程。
經(jīng)過收集和處理后，雙核花粉可以冷藏保存，通常可以保存數(shù)年。在種質(zhì)資源維護(hù)和植物育種的文獻(xiàn)中，對特定物種的儲存條件進(jìn)行了深入探討（最近由[58]綜述）。只要冷鏈得以維持，能夠在-20°C下儲存花粉1-6年而幾乎不損失活力的情況并不罕見[23,28,58]，這使生產(chǎn)者能夠靈活地將花粉從一年應(yīng)用到下一年，有助于降低同步性和生產(chǎn)風(fēng)險(xiǎn)。

3. Pollen Application3.花粉施用

Many methods to pollinate plants have been explored. Broadly, there are two main approaches: pollen can be applied dry (possibly diluted with a neutral carrier, such as charcoal, to help manage application rates), or wet (generally suspended in an aqueous liquid, often with additives to ensure isotonic balance with pollen cells) (Figure 4). A third option is available for selected, self-compatible crops—such as tomato—where vibrating the floral structures, either through direct contact or with a puff of air, shakes loose pollen to fertilize the flower [59].
人們已經(jīng)探索了許多給植物授粉的方法。從廣義上講，有兩種主要方法：花粉可以干施（可能用中性載體如木炭稀釋，以幫助控制施用量），也可以濕施（通常懸浮在水性液體中，通常含有添加劑以確保與花粉細(xì)胞的等滲平衡）（圖4）。第三種選擇適用于選定的自兼容作物，如番茄，通過直接接觸或一股空氣振動花朵結(jié)構(gòu)，搖動松散的花粉使花朵受精[59]。

Most application literature measures results directly in terms of fruit or seed set, as pollen requirements have been characterized for relatively few crops [60,61,62,63]. Research has shown that liquid-carrier (or dry diluent composition) formulation, temperature, time of day, weather, stigma receptivity, and flower age all influence pollination efficacy [41,61,64,65,66,67,68]. These factors are largely ignored in much of the work published on alternative pollination systems.
大多數(shù)應(yīng)用文獻(xiàn)的測量結(jié)果直接與果實(shí)或結(jié)實(shí)有關(guān)，因?yàn)榛ǚ坌枨蟮奶卣魇窍鄬^少的作物[60,61,62,63]。研究表明，液體載體（或干稀釋劑組合物）配方、溫度、時(shí)間、天氣、柱頭接受性和花齡都會影響授粉效果[41,61,64,65,66,67,68]。在許多關(guān)于替代授粉系統(tǒng)的研究中，這些因素在很大程度上被忽視了。
Dry application has two important advantages over wet pollen application:
干施比濕施花粉有兩個(gè)重要優(yōu)點(diǎn)：
Dry pollen delivered to non-target areas (e.g., petals, leaves) often remains viable and can be redistributed to the stigmas by bees [69], while pollen remains viable only for a short time once it becomes wet (30–100 min; [15,70]);
遞送到非目標(biāo)區(qū)域（如花瓣、葉子）的干花粉通常仍然存活，并可以被蜜蜂重新分配到柱頭[69]，而花粉一旦變濕，只能在短時(shí)間內(nèi)存活（30-100分鐘；[15,70]）；
Suitable aqueous carrier solutions have been demonstrated for kiwifruit [36], cherry [70], pear [71,72], pistachio [32], and date palm [28], but new solutions must be created, or customized, and validated for each crop.
獼猴桃[36]、櫻桃[70]、梨[71,72]、開心果[32]和椰棗[28]已經(jīng)證明了合適的水性載體溶液，但必須為每種作物創(chuàng)造、定制和驗(yàn)證新的溶液。
Insect pollinators take advantage of naturally occurring electrostatic forces, which help transfer pollen from bee to flower [73]. Research and commercial application have demonstrated that electrostatically charging dry pollen can improve the proportion captured by the flower by 5- to 10-fold [70,74,75,76]. However, droplets in aqueous systems generally have larger mass, making it more difficult to attach a sufficient charge to the pollen to affect its trajectory.
昆蟲傳粉者利用自然產(chǎn)生的靜電力，這有助于將花粉從蜜蜂轉(zhuǎn)移到花朵[73]。研究和商業(yè)應(yīng)用表明，帶靜電的干花粉可以將花朵捕獲的比例提高5到10倍[70,74,75,76]。然而，水性系統(tǒng)中的液滴通常具有更大的質(zhì)量，這使得更難在花粉上附著足夠的電荷來影響其軌跡。
The main advantages of aqueous systems are:
水性系統(tǒng)的主要優(yōu)點(diǎn)是：
Enabling more targeted delivery, efficacy during damp conditions where insect pollinators may be scarce [15,23,38];
在昆蟲傳粉者可能稀缺的潮濕條件下實(shí)現(xiàn)更有針對性的遞送和療效[15,23,38]；
The additional liquid mass increases momentum for targeted delivery, reducing the risk the pollen is dispersed by wind.
額外的液體質(zhì)量增加了靶向遞送的動量，降低了花粉被風(fēng)吹散的風(fēng)險(xiǎn)。
The majority of the artificial pollination systems in Figure 4 are used to supplement available bees, but for some crops, these systems perform adequately by themselves, including kiwifruit [16,19,23,77,78,79,80], olive [23], date palm [28], walnut [33,81], tomato [59], and hybrid maize seed [35].
圖4中的大多數(shù)人工授粉系統(tǒng)用于補(bǔ)充可用的蜜蜂，但對于某些作物，這些系統(tǒng)本身就可以充分發(fā)揮作用，包括獼猴桃[16,19,23,77,78,79,80]、橄欖[23]、椰棗[28]、核桃[33,81]、番茄[59]和雜交玉米種子[35]。
In cases where insect pollinators are abundant, bees perform equivalently or better than artificial pollination for kiwifruit [56,82,83] and kiwiberry [84,85], but when conditions are not optimal, particularly in years where local conditions limit pollinator activity, correctly applied supplemental pollination can increase seed number and fruit size [16,19,23,78,79,80]. Pollen is typically applied in two or more passes through the orchard [86], but a single pass at petal fall has been effective in Italian kiwifruit orchards [23].
在昆蟲傳粉者豐富的情況下，蜜蜂對獼猴桃[56,82,83]和獼猴桃[84,85]的授粉效果與人工授粉相當(dāng)或更好，但當(dāng)條件不是最佳時(shí)，特別是在當(dāng)?shù)貤l件限制傳粉者活動的年份，正確應(yīng)用補(bǔ)充授粉可以增加種子數(shù)量和果實(shí)大小[16,19,23,78,79,80]?；ǚ弁ǔＴ诠麍@中分兩次或多次施用[86]，但在意大利獼猴桃果園中，花瓣落下時(shí)單次施用是有效的[23]。

3.1. Hand-Pollination

Manual pollination with a paintbrush, stick, or pole tipped with a feather-brush is labour-intensive [12,23,41,87]. This cost can be sustained by some high-value crops (Table 1) [11], particularly when pollen does not need to be collected (e.g., tomato), the pollen is produced in abundance and collection costs are low (e.g., date), or the market value of the crop is very high (e.g., vanilla). Where mechanisation is available (even if only in the form of a vibratory wand), it is often more effective and economical than manual pollination [23,59,72,86,87].

3.1. 人工授粉
用畫筆、棍子或羽毛刷尖端的桿子進(jìn)行人工授粉是勞動密集型的[12,23,41,87]。一些高價(jià)值作物可以承受這種成本（表1）[11]，特別是在不需要收集花粉（如番茄）、花粉大量生產(chǎn)且收集成本低（如棗）或作物的市場價(jià)值很高（如香草）的情況下。在機(jī)械化可用的情況下（即使只是以振動棒的形式），它通常比人工授粉更有效、更經(jīng)濟(jì)[23,59,72,86,87]。

3.2. Handheld Devices

Handheld devices, such as blowers, sprayers, and vibratory wands, are quicker and easier to use for applying pollen than simple hand tools, such as paintbrushes, significantly reducing labour costs. Within these technologies is a constellation of inventive processes, but we found that four general categories of applicators are commonly used in commercial settings: vibratory wands (particularly for indoor tomato production); pneumatic devices tipped with a brush or feather-brush (for orchard crops); handheld blowers (often utilising commercial leaf blowers as a base component); and modified agricultural sprayers (Table 2). Directed broadcast of pollen using a handheld leaf blower has been estimated to deliver only 1% of pollen to stigmatic surfaces [101]; for dry application, some of the remaining 99% may then be redistributed by bees [69]. Other approaches have been explored, including a bubble gun [102], and a handheld electrostatic pollinator that can both collect and apply pollen [103]. However, both require further research to overcome the technical challenges (e.g., poor targeting and damage to floral structures from coronal discharge) before they could become commercial realities. A different handheld electrostatic pollinator was used successfully for the indoor cultivation of hybrid larch seed, but requires an external pollen supply [31].

3.2. 手持裝置
手持式設(shè)備，如鼓風(fēng)機(jī)、噴霧器和振動棒，比簡單的手動工具（如畫筆）更快、更容易用于施加花粉，大大降低了勞動力成本。在這些技術(shù)中，有一系列創(chuàng)造性的工藝，但我們發(fā)現(xiàn)，在商業(yè)環(huán)境中通常使用四類施用器：振動棒（特別是用于室內(nèi)番茄生產(chǎn)）；帶刷子或羽毛刷的氣動裝置（用于果園作物）；手持式鼓風(fēng)機(jī)（通常使用商用吹葉機(jī)作為基礎(chǔ)組件）；以及改良的農(nóng)業(yè)噴霧器（表2）。據(jù)估計(jì)，使用手持式吹葉機(jī)定向傳播花粉只能將1%的花粉輸送到柱頭表面[101]；對于干施，剩下的99%中的一部分可能會被蜜蜂重新分配[69]。已經(jīng)探索了其他方法，包括氣泡槍[102]和可以收集和施用花粉的手持式靜電授粉器[103]。然而，在它們成為商業(yè)現(xiàn)實(shí)之前，兩者都需要進(jìn)一步的研究來克服技術(shù)挑戰(zhàn)（例如，靶向性差和冠狀放電對花結(jié)構(gòu)的破壞）。另一種手持式靜電授粉器已成功用于雜交落葉松種子的室內(nèi)栽培，但需要外部花粉供應(yīng)[31]。

3.3. Vehicle-Mounted Devices

Sprayers, blowers, and fans of various kinds have been developed for large-scale pollination (Table 3). These devices require far fewer person-hours than equivalent handheld devices [28,86]. Early trials with apples used spray planes [26], and broadcast tractor sprayers [27]). In kiwifruit, broadcast systems were developed in the 1980s and had significant uptake by growers in the USA, Italy, and New Zealand for supplementing insect pollinators (replacing them in Italy, southern China, and Korea [16,17,18,19]) owing to their lower labour costs than hand application. In the Middle East, several inventions, including directed high-pressure sprayers drawn by tractors [28], have also performed as well as or better than the standard practice of manually pollinating date palm. Most of these devices are made to be towed behind a tractor, but some are also able to be mounted on farm ATVs for increased manoeuvrability, or on autonomous robotic platforms to reduce operator costs (e.g., XAG’s R150, Guangzhou, Guangdong, China, a small, multipurpose autonomous spraying and mowing robot). XAG’s ground-based pollen sprayer traversed a row of an apple orchard in 10 min, while hand pollination would take more than 2 h; however, pollination efficacy was not reported [93]. Broadcast wet sprayers are considered a last resort for pollination, and have lower efficiency in kiwifruit than dry applicators unless high rates of pollen are used [23], and also failed to deposit any pollen on the stigma of the much smaller Japanese plum flowers [14].

3.3. 車載設(shè)備
已經(jīng)開發(fā)了各種噴霧器、鼓風(fēng)機(jī)和風(fēng)扇，用于大規(guī)模授粉（表3）。這些設(shè)備所需的人時(shí)比同等的手持設(shè)備少得多[28,86]。早期對蘋果的試驗(yàn)使用了噴霧機(jī)[26]和廣播拖拉機(jī)噴霧器[27]）。在獼猴桃中，廣播系統(tǒng)是在20世紀(jì)80年代開發(fā)的，由于其比手工應(yīng)用更低的勞動力成本，美國、意大利和新西蘭的種植者大量采用該系統(tǒng)來補(bǔ)充昆蟲傳粉者（在意大利、中國南方和韓國取代了它們[16,17,18,19]）。在中東，一些發(fā)明，包括拖拉機(jī)牽引的定向高壓噴霧器[28]，也與人工授粉椰棗的標(biāo)準(zhǔn)做法一樣好或更好。這些設(shè)備中的大多數(shù)都是拖在拖拉機(jī)后面的，但也有一些能夠安裝在農(nóng)場ATV上以提高機(jī)動性，或者安裝在自主機(jī)器人平臺上以降低操作員成本（例如，XAG的R150，中國廣東廣州，一種小型多用途自主噴灑和割草機(jī)器人）。XAG的地面花粉噴霧器在10分鐘內(nèi)穿過一排蘋果園，而人工授粉需要2個(gè)多小時(shí)；然而，沒有報(bào)道授粉效果[93]。噴灑式濕式噴霧器被認(rèn)為是授粉的最后手段，除非使用高花粉率，否則在獼猴桃上的效率低于干式噴霧器[23]，而且也沒有在小得多的日本梅花的柱頭上沉積任何花粉[14]。

By their nature, non-targeted systems are wasteful, as pollen grains that settle on leaves, orchard structures, and branches do not fertilise the flower (pollen grains that land on petals, which can be redistributed by bees, are in the minority). To address this, researchers have investigated directed broadcast of electrostatically charged pollen, primarily for almonds, but also for apple, pear, sweet cherry, kiwifruit, and pistachio. Directing the pollen into the canopy reduces the amount of pollen lost to the wider environment, while positively charging the pollen increases attraction to pointed structures (such as styles), increasing pollen deposition [108]. Most of the work investigating electrostatic charge in pollination has involved an Israeli group led by Gan-Mor [74,75,108], and two US groups [109,110]. The application of electrostatic charge has increased pollen deposition on stigmas and improved the fruit set of almond, pistachio, date, apple, cherry, and pear under poor pollination conditions [70,94,110]. In general, for insect-pollinated crops other than kiwifruit and date palm, broadcast pollination is applied in addition to bee pollination, where it may improve fruit or nut set in years where pollination is poor [70,110]. However, there have been few studies on the effects of electrostatically charged pollen application on insect-pollinated crops without the assistance of bees; a trial from the grey literature suggests that the systems are no substitute for insect pollinators—almond yields were 1.3% without pollination, 17% with electrostatic pollination, and over 50% with insect pollination [111].

從本質(zhì)上講，非目標(biāo)系統(tǒng)是浪費(fèi)的，因?yàn)槁湓谌~子、果園結(jié)構(gòu)和樹枝上的花粉粒不會給花施肥（落在花瓣上的花粉顆粒是少數(shù)，可以被蜜蜂重新分配）。為了解決這個(gè)問題，研究人員研究了帶靜電花粉的定向傳播，主要用于杏仁，也用于蘋果、梨、甜櫻桃、獼猴桃和開心果。將花粉引入樹冠可以減少花粉流失到更廣泛環(huán)境中的量，而帶正電的花粉可以增加對尖端結(jié)構(gòu)（如花柱）的吸引力，增加花粉沉積[108]。研究授粉中靜電荷的大部分工作都涉及由Gan-Mor領(lǐng)導(dǎo)的以色列小組[74,75108]和兩個(gè)美國小組[109110]。在授粉條件較差的情況下，施加靜電荷增加了柱頭上的花粉沉積，并改善了杏仁、開心果、棗、蘋果、櫻桃和梨的坐果率[70,94110]。一般來說，對于獼猴桃和椰棗以外的昆蟲授粉作物，除了蜜蜂授粉外，還應(yīng)用了廣播授粉，這可能會在授粉不良的年份提高果實(shí)或堅(jiān)果的結(jié)實(shí)率[70110]。然而，在沒有蜜蜂幫助的情況下，關(guān)于靜電花粉施用對昆蟲授粉作物的影響的研究很少；灰色文獻(xiàn)的一項(xiàng)試驗(yàn)表明，這些系統(tǒng)不能替代昆蟲傳粉者——不授粉時(shí)杏仁產(chǎn)量為1.3%，靜電授粉時(shí)為17%，昆蟲授粉時(shí)為50%以上[111]。

Table 3

Representative pollination devices mounted to tractors with and without electrostatic charge capability.

表3
安裝在具有和不具有靜電荷能力的拖拉機(jī)上的代表性授粉裝置。