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Diurnal Variations of Airborne Pollen and Spores in Taipei City, Taiwan

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Diurnal Variations of Airborne Pollen and Spores

in Taipei City, Taiwan

Yueh-Lin Yang(1), Tseng-Chieng Huang(2) and Su-Hwa Chen(1, 3, 4)

(Manuscript received 17 July, 2003; accepted 28 August, 2003)

ABSTRACT: The diurnal variation of airborne pollen and spores in Taipei City, Taiwan, was investigated during a two-year survey from 1993 to 1994. The pollen and spores were sampled using a Burkard seven-day volumetric pollen trap. The diurnal trends of the total amount of pollen and spores in 1993 and in 1994 were similar to each other, and peaked at 3 to 10 o’clock. The diurnal patterns of airborne pollen and spores of Broussonetia, Fraxinus, Cyathea and Gramineae in 1993 were similar to those in 1994. High concentrations of Broussonetia and Fraxinus were obtained from midnight to the next morning. Cyathea spores peaked from morning till noon, and Gramineae peaked in the afternoon. The diurnal patterns of airborne pollen of Bischofia, Juniperus, Mallotus, Morus, Trema and Urticaceae in 1993 were different to those in 1994. Regular diurnal patterns also associated with the taxa, which produce large pollen or spores, such as Gramineae and Cyathea. In contrast, Bischofia,

Juniperus, Mallotus, Morus, Trema and Urticaceae produce relatively small pollen and the diurnal

patterns of their airborne pollen were found irregular. The source plants Broussonetia and Fraxinus were close to the collection site so the diurnal patterns of their airborne pollen were regular, suggesting that the diurnal fluctuations of the pollen or spores in air might be affected by the source of plants and the sizes of pollen or spores. The transportation of the smaller pollen or spores in air is probably more easily affected by instability of air currents; they are therefore more likely to exhibit irregular diurnal patterns.

KEY WORDS: Airborne pollen and spore, Diurnal variation, Taipei.

INTRODUCTION

Aeropalynology has become important in the last few decades because of serious problem of pollen-induced atopic diseases (D’Amato and Liccardi, 1994; Stock and Morandi, 1988). In Taiwan, continuous aeropalynological investigations at various locations have yielded useful information on the pollen calendars for use in further aeroallergen studies (Chen and Huang, 1980; Tsou and Huang, 1982; Chen, 1984; Chen and Chien, 1986; Peng and Chen, 1997; Tsou et al., 1997; Huang, 1998; Yang and Chen, 1998; Kuoh et al., 1999; Chen and Huang, 2000). However, the allergenic effects of most dominant airborne pollen and spores in Taiwan have not yet been studied, only the pollen of Bermuda grass (Shen et al., 1988; Han et

al., 1993), rice (Tsai et al., 1990) and Ambrosia (Tsai et al., 1997) have been determined to be

allergens. The present investigation was focused on and the pollen of Bischofia, Broussonetia,

Fraxinus, Gramineae, Mallotus, Morus, Juniperus, Trema and Urticaceae and the spores of Cyathea, most of which were found to dominate not only in Taipei City (Yang and Chen,

1998) but also in other cities around Taiwan, such as Taipei county (Tansui) (Peng and Chen,

__________________________________________________________________________________________ 1. Department of Life Science, National Taiwan University, Taipei 106, Taiwan.

2. Institute of Plant Biology, National Taiwan University, Taipei 106, Taiwan.

3. Institute of Ecology and Evolutionary Biology, National Taiwan University, Taipei 106, Taiwan. 4. Corresponding author. Email: suchen@ccms.ntu.edu.tw

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Fig. 1. Location of Taipei City(★) and the other sampling locations in Taiwan, Tansui(☆), Taitung, Tainan, Pingtung(△), Hualien and Taitung.

1997), Taichung (Tsou et al., 1997), Tainan (Kuoh et al., 1999), Pingtung (Huang, 1998), Hualien and Taitung (Huang et al., 1998) (Fig. 1). Several of these pollen have been recognized as important airborne allergens of rhinitis in many other areas, including

Broussonetia in mainland China (Yang et al., 1998), Fraxinus, Gramineae and Urticaceae in

Europe (Peeters, 1998; D’Amato and Liccardi, 1994; D’Amato and Spieksma, 1991), Morus and Trema in India (Mondal et al., 1998; Chakraborty et al., 1998) and Juniperus in Europe and Australia (Patrizia et al., 1998; Pham et al., 1994).

More than two million people live in Taipei, the capital and largest city in Taiwan, and are exposed to possible allergenic pollen and spores. Avoidance is practical as long as the time of daily maximal aeroallergen concentration - that is, the diurnal variation - is provided (Jaeger, 1990; Stock and Morandi, 1988). Apart from the extensive investigations of a limited number of taxa of airborne pollen and spores by Peng (1994), Peng and Chen (1997) and Huang (1998), only the annual variations of the airborne pollen and spores concentrations of a few dominant taxa in Taiwan have been studied (Huang et al., 1998). This study seeks to analyze the diurnal changes in concentration of airborne pollen and spores of individual dominant taxa. The diurnal variations of airborne pollen and spores in Taipei City are compared with those in Taipei county (Tansui) in the northwestern tip of Taiwan, from which some pollen may be transported to nearby Taipei City or vice versa, and those in Pingtung City, in the tropical south of Taiwan (Fig. 1).

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MATERIALS AND METHODS

Pollen concentrations were monitored from January 14, 1993 to December 31, 1994 using a Burkard seven-day recording volumetric pollen trap. The trap was located on the roof of a building, about 9 m above ground level, in Hondau Junior High School in Taipei City (25°03´N, 121°31´E) (Fig. 1). The flow rate through the trap was adjusted to 10 L per min and the pollen collections were checked weekly. A tape was attached to the roller, which moved at a rate of 2 mm / hr. After one-week of collection, the tape on the roller had spun for 336 mm and the segment of this length was cut into seven 48 mm-long pieces, which were removed to glass slides to identify and count the adhered pollen and spores. According to Peng and Chen (1996), the number of pollen and spores collected in an hour on a transverse band of a tape was used to estimate the number of pollen in m3 of air.

The diurnal variations of total airborne pollen and spores during the study period were calculated, and the diurnal variations of ten individual dominant taxa were analyzed. Data on rainless days, with relatively high counts during the flowering season, were used to analyze diurnal variation. The number of pollen and spores per hour on all selected days were summed and the mean values per hour were calculated. Table 1 lists the three selected days in the flowering seasons of Bischofia, Broussonetia, Cyathea, Fraxinus, Gramineae, Juniperus,

Mallotus, Morus, Trema and Urticaceae. The references for identification of airborne pollen

and spores included Pollen Flora of Taiwan (Hang, 1972), Spore Flora of Taiwan (Huang, 1981) and a SEM survey of airborne pollen grains in Taipei City (Chen, 1988).

The sizes of pollen grains and spores were measured using ten samples of each taxon on slides, in which the pollen and spores were embedded in glycerine- gelatine.

Most parts of Taipei City are at low altitude, and vegetation is influenced by excessive urbanization and biotic interference. The common sources of airborne pollen and spores include native species and trees along the avenues in the city or in the mountainous areas around the city.

Table 1. Three selected days of ten dominant pollen and spore taxa.

Taxon 1993 1994 Bischofia 2/28, 3/12, 3/14 3/16, 3/26, 3/28 Broussonetia 3/24, 3/26, 3/28 4/4, 4/6, 4/12 Cyathea 8/18, 9/4, 9/12 7/2, 7/6, 7/8 Fraxinus 5/22, 5/24, 5/30 5/22, 5/24, 5/26 Gramineae 11/8, 11/10, 11/14 11/6, 11/8, 11/12 Juniperus 2/6, 2/18, 2/20 2/10, 2/22, 3/5 Mallotus 9/10, 9/12, 10/2 9/20, 9/22, 9/24 Morus 2/19, 2/20, 3/4 2/4, 2/22, 3/12 Trema 4/24, 4/28, 4/30 5/8, 5/10, 5/14 Urticaceae 3/6, 3/14, 3/24 3/26, 4/6, 4/8 RESULTS

Total concentration of airborne pollen and spores

In this two-year survey, approximately 43% of all airborne pollen and spores recorded were found from 3 to 10 o’clock (Fig. 2); the maximum concentration was at 9 o’clock and the minimum concentration was at 19 o’clock. The diurnal trend of total pollen and spores in 1993 was similar to that in 1994, and that the correlation was high significant (r=0.92. p<0.01).

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0 10 20 30 40 50 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 Hour No. of pollen/ m 3 ai r 1993 1994

Fig. 2. Diurnal variations of total airborne pollen in Taipei City, 1993 and 1994.

Dominant airborne pollen and spores

The diurnal variations of airborne pollen and spores of Broussonetia, Cyathea, Fraxinus and Gramineae in 1993 were significantly correlated with those in 1994 (Table 2 and Fig. 3). The diurnal variations of airborne pollen of Bischofia, Juniperus, Mallotus, Morus, Trema and Urticaceae were negatively correlated between the two years (Table 2 and Fig. 4).

Table 2. Data on the taxa with the largest concentrations was recorded over two years and regression analysis of diurnal trends over 1993 and 1994 was conducted.

Time of maximum concentration (o’clock) Taxon 1993 1994 Correlation coefficient Broussonetia 3 9 **r= 0.92 Cyathea 13 12 *r= 0.39 Fraxinus 7 7 **r= 0.72 Gramineae 18 17 **r= 0.67 Bischofia 4 22 r= -0.1 Juniperus 8 24 r= 0.01 Mallotus 10 1 and 5 r= 0.27 Morus 11 19 r= 0.16 Trema 1 11 r= -0.05 Urticaceae 6 2 r= 0.27 * : result significant at p< 0.1 ** : result significant at p< 0.01

In 1993, concentrations of Bischofia, Broussonetia, Fraxinus, Juniperus, Mallotus, Trema and Urticaceae pollen were high from midnight to next morning, peaking at 4, 3, 7, 8, 10, 1 and 6 o’clock, respectively. Concentrations of Cyathea spores and Morus pollen were high from morning to midday, peaking at 13 and 11 o’clock, respectively. The concentration of Gramineae pollen was high from afternoon to night, peaking at 18 o’clock.

In 1994, the concentrations of Broussonetia, Fraxinus, Mallotus and Urticaceae pollen were high from midnight to next morning, peaking at 9, 7, 5 and 2 o’clock, respectively. High concentrations of Cyathea spores and Trema pollen were recorded from morning to midday, peaking at 12 and 11 o’clock, respectively. High concentrations of Bischofia, Gramineae,

Juniperus and Morus pollen were recorded from afternoon to midnight, peaking at 22, 17, 24,

and 19 o’clock, respectively. Source areas of pollen and spores

The sources of pollen of Bischofia, Broussonetia, Fraxinus, Juniperus, Morus and Trema were probably in the city; however the pollen and spores of Cyathea, Gramineae, Mallotus and Urticaceae were probably from vegetation in the surrounding mountainous areas.

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Fig. 3. Regular diurnal variations of Broussonetia, Fraxinus, Cyathea and Gramineae. Mean values per hour were for three selected days (listed in Table 1) with high pollen counts.

Bischofia javanica is a native tree common on the streets and gardens of Taipei City, and is the possible source of Bischofia pollen in air. Broussonetia papyrifera, Morus australis and

Trema orientalis, common native pioneer trees, are common in the city and the possible

source of Broussonetia, Morus and Trema pollen in air, respectively. Fraxinus griffithii, a major source of Fraxinus pollen is a common native tree, too, but it is uncommon in Taipei City. Juniperus pollen probably originated from individual ornamental trees in the gardens and parks in the city, such as Juniperus chinensis var. kaizuka and J. chinensis var.

pyramidalis.

Cyathea lepifera, C. podophylla and C. spinulosa, the major sources of Cyathea spores, are common native ferns in the lower mountainous areas throughout Taiwan. Miscanthus

floridulus is common native species from low to medium altitudes throughout Taiwan. In

Taipei City, large populations of Miscanthus floridulus in mountainous areas may be the major sources of Gramineae pollen. Mallotus paniculatus is a common native tree in the lower mountainous areas throughout Taiwan and the source of the Mallotus pollen. The sources of Urticaceae pollen include many species, such as Boehmeria densiflora,

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Fig. 4. Irregular diurnal variations of pollen of Bischofia, Juniperus, Mallotus, Morus, Trema and Urticaceae. The mean values per hour were for three selected days (listed in Table 1.) with high pollen counts.

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Size of pollen and spores

Table 3 shows that Cyathea spores (41.81±3.18 x 42.53±2.75 µm) are the largest among those of the ten taxa, followed by those of Gramineae pollen. Broussonetia pollen (11.75± 1.10 x 11.43±0.91 µm) are the smallest.

Table 3. Mean size of airborne pollen and spores. The pollen and spores, embedded in glycerine- gelatine were measured in LM. P: polar axis; E: equatorial axis.

Taxon Mean size of pollen and spores ( P x E )

Bischofia 22.60±1.45 x 19.40±0.66 µm Broussonetia 11.75±1.10 x 11.43±0.91 µm Cyathea 41.81±3.18 x 42.53±2.75 µm Fraxinus 16.54±0.80 x 15.54±0.88 µm Garmineae 32.40±1.00 x 31.57±0.99 µm Juniperus 32.03±2.33 x 31.58±1.87 µm Mallotus 18.74±0.78 x 19.99±0.78 µm Morus 15.20±0.59 x 15.29±0.86 µm Trema 19.91±1.23 x 20.37±1.25 µm Urticaceae 13.40±1.75 x 13.50±1.60 µm DISCUSSION

Total concentration of airborne pollen and spores

The dynamics of the meteorological factors in a day could affect the diurnal variations of airborne pollen (Lee et al., 1996; Berggren et al., 1995; Galán et al., 1991; Norris-Hill and Emberlin, 1991). That is, increasing temperature and decreasing relative humidity were closely correlated with increasing amounts of airborne pollen and spores. Therefore, most airborne pollen and spores were collected from 3 to 10 o’clock (Fig. 2) not only in Taipei City, but also in Tansui (Pen and Chen, 1997) and Pingtung (Huang, 1998) on Taiwan Island. Dominant airborne pollen and spores

Data obtained on rainless days were used, since rain can delay or suppress the release of pollen (Atluri and Appanna, 1988) and even wash away airborne pollen (Berggren et al., 1995).

All airborne pollen and spores taxa considered in this study, except for Cyathea, Fraxinus,

Juniperus and Urticaceae are dominant in whole Taiwan Island, according to the mass of

airborne pollen they produce (Peng and Chen, 1997; Tsou et al., 1997; Huang, 1998; Huang

et al., 1998; Yang and Chen, 1998; Kuoh et al., 1999).

Although the source of Urticaceae pollen and Cyathea spore distribute throughout Taiwan, Urticaceae pollen were dominant in air only in Taipei City (Yang and Chen, 1998), Tansui (Peng and Chen, 1997), Tainan (Huang et al., 1998) and Hualien (Huang et al., 1998), while

Cyathea spore were dominant in air only in Taipei City (Yang and Chen, 1998) and Tansui

(Peng and Chen, 1997). There are mountainous areas, the source plants of Urticaceae pollen and Cyathea spore grow, around the locality of the pollen trap, such as Taipei City (Yang and Chen, 1998), Tansui (Peng and Chen, 1997), Tainan (Huang et al., 1998) and Hualien (Huang

et al., 1998), which could collect those airborne pollen and spores.

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was dominant only in Taipei City (Yang and Chen, 1998). A great number of Fraxinus pollen was collected in the trap in Taipei City was probably related to the planted F. griffithii on the campus of Hondau Junior High School where the recording trap was located. Pollen of

Juniperus was dominant only in Taipei City (Yang and Chen, 1998). There are more gardens

and parks in Taipei City than those in other cities where planted many ornamental trees, such as Juniperus chinensis var. kaizuka and J. chinensis var. pyramidalis, the source of Juniperus pollen. The abundance of the pollen and spores may be affected by vegetation around the locality of the pollen trap.

The tendency of diurnal variation of Broussonetia pollen in 1993 was similar to that in 1994, with high concentration from midnight to following morning. In Southwest of Spain the airborne pollen of B. papyrifera was recorded to exhibit a similar diurnal pattern to that in Taipei City, with a high concentration from 10 to 12 o,clock in 1982 and 1983 (Galán et al., 1991), whereas those results are different with Tansui (Peng, 1994) and Pingtung(Huang, 1998). Most airborne Broussonetia pollen was collected from 13 to 15 o,clock and 23 to 24 o,clock in 1993 in Tansui and throughout the day in Pingtung.

The significantly large amount of Miscanthus floridulus pollen, the major source of Gramineae pollen in Taipei City, dominated the diurnal variation of the grass airborne pollen, which appeared to be regular. The irregularity in diurnal variations of grass airborne pollen in other areas was probably due to involvement of multiple species (Käpylä, 1981; Mullins et al., 1986; Pen and Chen, 1997).

The diurnal variations of Bischofia, Mallotus, Morus and Trema pollen showed irregularity in 1993 to those in 1994. As several authors have suggested, the dehiscence of pollen of Morus exhibits no regular pattern, and the release of Morus pollen continues throughout the day (Käpylä, 1984; Galán et al., 1991). Although the diurnal variation of

Trema pollen showed irregular pattern, most airborne Trema pollen was collected from

morning to midday. The result is similar to that in Pingtung, high concentration of Trema pollen from 9 to 13 o’clock (Huang, 1998) and Indian, high concentration in early and late morning (Banik and Chanda, 1992). In Tansui, the tendency of diurnal variation of Trema pollen showed regular pattern with high concentration from 4 to 8 o’clock (Peng and Chen, 1997).

The diurnal variations of Juniperus and Urticaceae pollen in this study showed an irregularity that was probably related to the fact that at least two species were involved; similar result was obtained in Tansui (Peng, 1994; Peng and Chen, 1997).

Although the anthesis of the different species occurred different, most of them were in the morning to midday. For example, a study of 31 species in India revealed pollen release from 3 to 13 o’clock (Atluri and Appanna, 1988). Bhattacharya and Datta (1992) studied 35 species, including 25 anemophilous species, and found that release patterns of pollen varied but occurred within the period from 2 to 12 o’clock. Variations in diurnal rhythms of airborne pollen may reflect the release of pollen from different species (Käpylä, 1981; Käpylä, 1984). Many studies have found only slightly different diurnal patterns of airborne pollen at different times (Alcázar et al., 1999; Diaz, et al., 1993; Galán et al., 1991), but some other studies have indicated significant differences with time (Alcázar et al., 1999; Galán et al., 1991). This study revealed that high concentration of airborne pollen varied with species and that the diurnal variations of Broussonetia, Cyathea, Fraxinus and Gramineae in 1993 were similar to those in 1994 (Fig. 3). However, the diurnal variations of Bischofia, Juniperus, Mallotus,

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Source areas of pollen and spores

The amount of airborne pollen does not necessarily reflect only the release of pollen, but also pollen dispersal and transport (Norris-Hill, 1999; Käpylä, 1984). The position of the trap in relation to the source of pollen influences the diurnal patterns of the pollen in air (Muñoz et

al., 2000; Norris-Hill and Emberlin, 1991). Käpylä (1981) revealed that when the airborne

pollen collection site is far from the source plants, the movement of air is more important than the pollen liberation rhythm in determining the diurnal fluctuation of the airborne pollen. In this study, the diurnal patterns of airborne pollen of Broussonetia and Fraxinus were regular because their source plants, B. papyrifera and F. griffithii, grow in the campus where the data were recorded and their pollen grains were captured by the trap almost immediately after they were released. The source plants of Bischofia, Juniperus, Mallotus, Morus, Trema and Urticaceae are scattered over the city or in the suburban mountains far from trap, so the diurnal patterns of their airborne pollen were irregular, while those of Cyathea and Gramineae were regular.

Size of pollen and spores

Weather conditions, especially wind conditions, affect the diurnal fluctuations of pollen concentrations in the air (Berggren, 1995; Käpylä, 1981). Mullins et al. (1986) pointed out that rising air currents lead to irregular diurnal patterns of airborne pollen. Strong agitation is required to transport large particles in the air, so the concentration of large pollen depend more strongly on the wind speed than does that of smaller pollen (Käpylä, 1984). Therefore, the diurnal pattern of larger airborne pollen is much more regular than that of smaller pollen. A previous paper, noted that smaller airborne pollen correspond to higher pollen concentration at greater heights, affected by thermal convection (Alcázar et al., 1998). Such a phenomena may explain why regular diurnal patterns are always associated with taxa with large pollen and spores, such as Gramineae and Cyathea. Also, if the source plants of

Broussonetia and Fraxinus with small pollen are not in campus, the diurnal variation may be

varied, like that of Broussonetia pollen in Pingtung (Huang, 1998) and Tansui (Pen and Chen, 1997)

The pollen and spore concentrations in the air and their diurnal patterns affected by many factors, such as meteorological variables, topography and distribution of source plant in relation to the pollen sampler (Alba, et al., 2000; Berggren, 1995). A more detailed study is required, especially the field studies because it may reveal the diurnal rhythm of airborne pollen and spores and it is helpful for the diagnosis and prevention of allergies through analysis.

ACKNOWLEDGEMENTS

This research was supported by the National Science Council of Taiwan (NSC 82-0211-B-002-368-B08, 83- 0409- B 002-005-B08 and NSC 84-2311-B-002-017- B08). The authors would like to thank Houndau Junior High School for kindly providing a space in which to set up the trap.

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台北市空中孢粉每日的逐時變化

楊月鈴(1)、黃增泉(2)、陳淑華(1, 3, 4)

(收稿日期:2003 年 7 月 17 日;接受日期:2003 年 8 月 28 日)

摘 要

本研究以設在台北市市區的孢粉收集器(Burkard seven-day volumetric pollen trap) 收集 1993 和 1994 兩年的空中孢粉,發現這兩年累計所有空中孢粉於一天出現的逐時變 化(diurnal variation)趨勢相似,空中孢粉多數出現在清晨 3 時至 10 時,只有少數會出 現 在 下 午 。 今 以 出 現 最 優 勢 的 前 10 種 空 中 孢 粉 的 逐 時 變 化 分 析 , 其 中 構 樹 屬 (Broussonetia)、梣屬(Fraxinus)、莎欏屬(Cyathea)和禾本科(Gramineae)孢粉兩 年的逐時變化趨勢相似,構樹屬和梣屬花粉多數出現在深夜至次日上午;莎欏屬孢子多 數出現在上午至中午;禾本科花粉則多數出現在下午。重陽木屬(Bischofia)、柏屬 (Juniperus)、野桐屬(Mallotus)、桑屬(Morus)、山黃麻屬(Trema)及蕁麻科(Urticaceae) 的花粉兩年的逐時變化趨勢不規則。體積較大的孢粉逐時變化趨勢較規則,例如莎欏屬 孢子和禾本科花粉;體積較小的花粉,逐時變化趨勢較不規則,例如重陽木屬、柏屬、 野桐屬、桑屬、山黃麻屬及蕁麻科。構樹屬和梣屬花粉雖然體積小,但因花粉的來源很 靠近孢粉收集器,而出現規則的逐時變化趨勢。空中孢粉逐時變化的規則性可能受到孢 粉來源、孢粉大小及氣流所影響,即體積較小的孢粉較易受影響而使其逐時變化趨勢較 不規則。 關鍵詞:空中孢粉、逐時變化、台北。 ___________________________________________________________________________ 1.國立台灣大學生命科學系,台北市 106,台灣。 2.國立台灣大學植物科學所,台北市 106,台灣。 3.國立台灣大學生態學與演化生物所,台北市 106,台灣。 4.通信作者。Email: suchen@ccms.ntu.edu.tw

數據

Fig. 1. Location of Taipei City(★) and the other sampling locations in Taiwan, Tansui(☆), Taitung, Tainan,  Pingtung(△), Hualien and Taitung
Table 1. Three selected days of ten dominant pollen and spore taxa.
Table 2. Data on the taxa with the largest concentrations was recorded over two years and regression analysis of  diurnal trends over 1993 and 1994 was conducted
Fig. 3. Regular diurnal variations of Broussonetia,  Fraxinus,  Cyathea and Gramineae
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