- ข้อความ
- ประวัติศาสตร์
Our study also found stronger effec
Our study also found stronger effects of BC on asthma hospitalization
than PM10, suggesting that BC is potentially a useful indicator
of air quality that can be used to estimate the health risks of
ambient particles. Our findings of BC are consistent with a previous
meta-analysis and systematic review of the health effects of BC (van
Schayck, 2013). In Shanghai, the major sources of BC are motorized
traffic, coal burning, shipping emissions, and industrial sources
(Denning et al., 2013); therefore, BC might serve as an indicator for
the larger category of primary combustion particles. PM10 is a
mixture of various chemical components. It is possible that we
observed a more robust association for BC than PM10 because BC
more closely resembles the harmful components in air pollution
mixtures than it resembles general PM (van Schayck, 2013).
The health effects implicated similar lag structures for NO2, SO2
and BC. The most significant associations were observed at lag0,
lag1 or lag 01, suggesting that increased asthma hospital admission
were associated with high NO2, SO2 and BC levels on the same day
or the previous day. In other words, this finding indicates that the
effects caused by these three pollutants on asthma exacerbation
might be acute and immediate. The absence of lag effects were also
reported by other studies (Hua et al., 2014; Katsouyanni et al., 1997;
Sunyer et al.,1997; To et al., 2013) while longer lag times have rarely
been described (Galan et al., 2003; Li et al., 2011).
Compared to the warm season, our study observed a stronger
association between air pollution and asthma hospitalization in the
cool season. This finding is consistent with several prior studies in
Hong Kong and Athens (Chen et al., 2010; Touloumi et al., 1996;
Wong et al., 2002). Season-specific observations likely result from
the variations in seasonal characteristics of air pollution and individual
exposure patterns (Baena-Cagnani, 2001). In Shanghai, air
pollution levels were higher and more variable in the cool season
than PM10, suggesting that BC is potentially a useful indicator
of air quality that can be used to estimate the health risks of
ambient particles. Our findings of BC are consistent with a previous
meta-analysis and systematic review of the health effects of BC (van
Schayck, 2013). In Shanghai, the major sources of BC are motorized
traffic, coal burning, shipping emissions, and industrial sources
(Denning et al., 2013); therefore, BC might serve as an indicator for
the larger category of primary combustion particles. PM10 is a
mixture of various chemical components. It is possible that we
observed a more robust association for BC than PM10 because BC
more closely resembles the harmful components in air pollution
mixtures than it resembles general PM (van Schayck, 2013).
The health effects implicated similar lag structures for NO2, SO2
and BC. The most significant associations were observed at lag0,
lag1 or lag 01, suggesting that increased asthma hospital admission
were associated with high NO2, SO2 and BC levels on the same day
or the previous day. In other words, this finding indicates that the
effects caused by these three pollutants on asthma exacerbation
might be acute and immediate. The absence of lag effects were also
reported by other studies (Hua et al., 2014; Katsouyanni et al., 1997;
Sunyer et al.,1997; To et al., 2013) while longer lag times have rarely
been described (Galan et al., 2003; Li et al., 2011).
Compared to the warm season, our study observed a stronger
association between air pollution and asthma hospitalization in the
cool season. This finding is consistent with several prior studies in
Hong Kong and Athens (Chen et al., 2010; Touloumi et al., 1996;
Wong et al., 2002). Season-specific observations likely result from
the variations in seasonal characteristics of air pollution and individual
exposure patterns (Baena-Cagnani, 2001). In Shanghai, air
pollution levels were higher and more variable in the cool season
0/5000
Our study also found stronger effects of BC on asthma hospitalization
than PM10, suggesting that BC is potentially a useful indicator
of air quality that can be used to estimate the health risks of
ambient particles. Our findings of BC are consistent with a previous
meta-analysis and systematic review of the health effects of BC (van
Schayck, 2013). In Shanghai, the major sources of BC are motorized
traffic, coal burning, shipping emissions, and industrial sources
(Denning et al., 2013); therefore, BC might serve as an indicator for
the larger category of primary combustion particles. PM10 is a
mixture of various chemical components. It is possible that we
observed a more robust association for BC than PM10 because BC
more closely resembles the harmful components in air pollution
mixtures than it resembles general PM (van Schayck, 2013).
The health effects implicated similar lag structures for NO2, SO2
and BC. The most significant associations were observed at lag0,
lag1 or lag 01, suggesting that increased asthma hospital admission
were associated with high NO2, SO2 and BC levels on the same day
or the previous day. In other words, this finding indicates that the
effects caused by these three pollutants on asthma exacerbation
might be acute and immediate. The absence of lag effects were also
reported by other studies (Hua et al., 2014; Katsouyanni et al., 1997;
Sunyer et al.,1997; To et al., 2013) while longer lag times have rarely
been described (Galan et al., 2003; Li et al., 2011).
Compared to the warm season, our study observed a stronger
association between air pollution and asthma hospitalization in the
cool season. This finding is consistent with several prior studies in
Hong Kong and Athens (Chen et al., 2010; Touloumi et al., 1996;
Wong et al., 2002). Season-specific observations likely result from
the variations in seasonal characteristics of air pollution and individual
exposure patterns (Baena-Cagnani, 2001). In Shanghai, air
pollution levels were higher and more variable in the cool season
than PM10, suggesting that BC is potentially a useful indicator
of air quality that can be used to estimate the health risks of
ambient particles. Our findings of BC are consistent with a previous
meta-analysis and systematic review of the health effects of BC (van
Schayck, 2013). In Shanghai, the major sources of BC are motorized
traffic, coal burning, shipping emissions, and industrial sources
(Denning et al., 2013); therefore, BC might serve as an indicator for
the larger category of primary combustion particles. PM10 is a
mixture of various chemical components. It is possible that we
observed a more robust association for BC than PM10 because BC
more closely resembles the harmful components in air pollution
mixtures than it resembles general PM (van Schayck, 2013).
The health effects implicated similar lag structures for NO2, SO2
and BC. The most significant associations were observed at lag0,
lag1 or lag 01, suggesting that increased asthma hospital admission
were associated with high NO2, SO2 and BC levels on the same day
or the previous day. In other words, this finding indicates that the
effects caused by these three pollutants on asthma exacerbation
might be acute and immediate. The absence of lag effects were also
reported by other studies (Hua et al., 2014; Katsouyanni et al., 1997;
Sunyer et al.,1997; To et al., 2013) while longer lag times have rarely
been described (Galan et al., 2003; Li et al., 2011).
Compared to the warm season, our study observed a stronger
association between air pollution and asthma hospitalization in the
cool season. This finding is consistent with several prior studies in
Hong Kong and Athens (Chen et al., 2010; Touloumi et al., 1996;
Wong et al., 2002). Season-specific observations likely result from
the variations in seasonal characteristics of air pollution and individual
exposure patterns (Baena-Cagnani, 2001). In Shanghai, air
pollution levels were higher and more variable in the cool season
การแปล กรุณารอสักครู่..
Our study also found stronger effects of BC on asthma hospitalization
than PM10, suggesting that BC is potentially a useful indicator
of air quality that can be used to estimate the health risks of
ambient particles. Our findings of BC are consistent with a previous
meta-analysis and systematic review of the health effects of BC (van
Schayck, 2013). In Shanghai, the major sources of BC are motorized
traffic, coal burning, shipping emissions, and industrial sources
(Denning et al., 2013); therefore, BC might serve as an indicator for
the larger category of primary combustion particles. PM10 is a
mixture of various chemical components. It is possible that we
observed a more robust association for BC than PM10 because BC
more closely resembles the harmful components in air pollution
mixtures than it resembles general PM (van Schayck, 2013).
The health effects implicated similar lag structures for NO2, SO2
and BC. The most significant associations were observed at lag0,
lag1 or lag 01, suggesting that increased asthma hospital admission
were associated with high NO2, SO2 and BC levels on the same day
or the previous day. In other words, this finding indicates that the
effects caused by these three pollutants on asthma exacerbation
might be acute and immediate. The absence of lag effects were also
reported by other studies (Hua et al., 2014; Katsouyanni et al., 1997;
Sunyer et al.,1997; To et al., 2013) while longer lag times have rarely
been described (Galan et al., 2003; Li et al., 2011).
Compared to the warm season, our study observed a stronger
association between air pollution and asthma hospitalization in the
cool season. This finding is consistent with several prior studies in
Hong Kong and Athens (Chen et al., 2010; Touloumi et al., 1996;
Wong et al., 2002). Season-specific observations likely result from
the variations in seasonal characteristics of air pollution and individual
exposure patterns (Baena-Cagnani, 2001). In Shanghai, air
pollution levels were higher and more variable in the cool season
than PM10, suggesting that BC is potentially a useful indicator
of air quality that can be used to estimate the health risks of
ambient particles. Our findings of BC are consistent with a previous
meta-analysis and systematic review of the health effects of BC (van
Schayck, 2013). In Shanghai, the major sources of BC are motorized
traffic, coal burning, shipping emissions, and industrial sources
(Denning et al., 2013); therefore, BC might serve as an indicator for
the larger category of primary combustion particles. PM10 is a
mixture of various chemical components. It is possible that we
observed a more robust association for BC than PM10 because BC
more closely resembles the harmful components in air pollution
mixtures than it resembles general PM (van Schayck, 2013).
The health effects implicated similar lag structures for NO2, SO2
and BC. The most significant associations were observed at lag0,
lag1 or lag 01, suggesting that increased asthma hospital admission
were associated with high NO2, SO2 and BC levels on the same day
or the previous day. In other words, this finding indicates that the
effects caused by these three pollutants on asthma exacerbation
might be acute and immediate. The absence of lag effects were also
reported by other studies (Hua et al., 2014; Katsouyanni et al., 1997;
Sunyer et al.,1997; To et al., 2013) while longer lag times have rarely
been described (Galan et al., 2003; Li et al., 2011).
Compared to the warm season, our study observed a stronger
association between air pollution and asthma hospitalization in the
cool season. This finding is consistent with several prior studies in
Hong Kong and Athens (Chen et al., 2010; Touloumi et al., 1996;
Wong et al., 2002). Season-specific observations likely result from
the variations in seasonal characteristics of air pollution and individual
exposure patterns (Baena-Cagnani, 2001). In Shanghai, air
pollution levels were higher and more variable in the cool season
การแปล กรุณารอสักครู่..
Our study also found stronger effects of BC on asthma hospitalization
than PM10, suggesting that BC is potentially a useful indicator
of air quality that can be used to estimate the health risks of
ambient particles. Our findings of BC are consistent with a previous
meta-analysis and systematic review of the health effects of BC (van
Schayck, 2013). In Shanghai,แหล่งที่มาหลักของ BC ยนต์
จราจร การเผาไหม้ถ่านหิน มลพิษ จัดส่งสินค้า และแหล่งอุตสาหกรรม
( เดนนิ่ง et al . , 2013 ) ; ดังนั้น บีซี อาจใช้เป็นตัวบ่งชี้สำหรับ
ขนาดใหญ่ประเภทของอนุภาคเชื้อเพลิงหลัก PM10 เป็น
ส่วนผสมของส่วนประกอบทางเคมีต่างๆ มันเป็นไปได้ว่าเรา
สังเกตแข็งแกร่งมากขึ้นกว่า PM10 เพราะสมาคม BC BC
more closely resembles the harmful components in air pollution
mixtures than it resembles general PM (van Schayck, 2013).
The health effects implicated similar lag structures for NO2, SO2
and BC. The most significant associations were observed at lag0,
lag1 or lag 01, suggesting that increased asthma hospital admission
were associated with high NO2, SO2 and BC levels on the same day
หรือก่อนหน้าวัน ในคำอื่น ๆ การค้นพบนี้บ่งชี้ว่า ผลที่เกิดจากสารมลพิษเหล่านี้สามโรคหืดกำเริบ
อาจจะแหลม และทันที การขาดของร่างกายผลยัง
รายงานการศึกษาอื่น ๆ ( หัว et al . , 2014 ; katsouyanni et al . , 1997 ;
sunyer et al . , 1997 ; et al . , 2013 ) ในขณะที่เวลาความล่าช้านานไม่ค่อย
บรรยาย ( Galan et al . , 2003 ; Li et al . ,
2011 )Compared to the warm season, our study observed a stronger
association between air pollution and asthma hospitalization in the
cool season. This finding is consistent with several prior studies in
Hong Kong and Athens (Chen et al., 2010; Touloumi et al., 1996;
Wong et al., 2002). Season-specific observations likely result from
การเปลี่ยนแปลงในลักษณะตามฤดูกาลของมลพิษทางอากาศและบุคคล
เปิดรับรูปแบบ ( baena cagnani , 2001 ) ในเซี่ยงไฮ้ , ระดับมลพิษทางอากาศ
มีมากขึ้นและตัวแปรในฤดูหนาว
than PM10, suggesting that BC is potentially a useful indicator
of air quality that can be used to estimate the health risks of
ambient particles. Our findings of BC are consistent with a previous
meta-analysis and systematic review of the health effects of BC (van
Schayck, 2013). In Shanghai,แหล่งที่มาหลักของ BC ยนต์
จราจร การเผาไหม้ถ่านหิน มลพิษ จัดส่งสินค้า และแหล่งอุตสาหกรรม
( เดนนิ่ง et al . , 2013 ) ; ดังนั้น บีซี อาจใช้เป็นตัวบ่งชี้สำหรับ
ขนาดใหญ่ประเภทของอนุภาคเชื้อเพลิงหลัก PM10 เป็น
ส่วนผสมของส่วนประกอบทางเคมีต่างๆ มันเป็นไปได้ว่าเรา
สังเกตแข็งแกร่งมากขึ้นกว่า PM10 เพราะสมาคม BC BC
more closely resembles the harmful components in air pollution
mixtures than it resembles general PM (van Schayck, 2013).
The health effects implicated similar lag structures for NO2, SO2
and BC. The most significant associations were observed at lag0,
lag1 or lag 01, suggesting that increased asthma hospital admission
were associated with high NO2, SO2 and BC levels on the same day
หรือก่อนหน้าวัน ในคำอื่น ๆ การค้นพบนี้บ่งชี้ว่า ผลที่เกิดจากสารมลพิษเหล่านี้สามโรคหืดกำเริบ
อาจจะแหลม และทันที การขาดของร่างกายผลยัง
รายงานการศึกษาอื่น ๆ ( หัว et al . , 2014 ; katsouyanni et al . , 1997 ;
sunyer et al . , 1997 ; et al . , 2013 ) ในขณะที่เวลาความล่าช้านานไม่ค่อย
บรรยาย ( Galan et al . , 2003 ; Li et al . ,
2011 )Compared to the warm season, our study observed a stronger
association between air pollution and asthma hospitalization in the
cool season. This finding is consistent with several prior studies in
Hong Kong and Athens (Chen et al., 2010; Touloumi et al., 1996;
Wong et al., 2002). Season-specific observations likely result from
การเปลี่ยนแปลงในลักษณะตามฤดูกาลของมลพิษทางอากาศและบุคคล
เปิดรับรูปแบบ ( baena cagnani , 2001 ) ในเซี่ยงไฮ้ , ระดับมลพิษทางอากาศ
มีมากขึ้นและตัวแปรในฤดูหนาว
การแปล กรุณารอสักครู่..
ภาษาอื่น ๆ
การสนับสนุนเครื่องมือแปลภาษา: กรีก, กันนาดา, กาลิเชียน, คลิงออน, คอร์สิกา, คาซัค, คาตาลัน, คินยารวันดา, คีร์กิซ, คุชราต, จอร์เจีย, จีน, จีนดั้งเดิม, ชวา, ชิเชวา, ซามัว, ซีบัวโน, ซุนดา, ซูลู, ญี่ปุ่น, ดัตช์, ตรวจหาภาษา, ตุรกี, ทมิฬ, ทาจิก, ทาทาร์, นอร์เวย์, บอสเนีย, บัลแกเรีย, บาสก์, ปัญจาป, ฝรั่งเศส, พาชตู, ฟริเชียน, ฟินแลนด์, ฟิลิปปินส์, ภาษาอินโดนีเซี, มองโกเลีย, มัลทีส, มาซีโดเนีย, มาราฐี, มาลากาซี, มาลายาลัม, มาเลย์, ม้ง, ยิดดิช, ยูเครน, รัสเซีย, ละติน, ลักเซมเบิร์ก, ลัตเวีย, ลาว, ลิทัวเนีย, สวาฮิลี, สวีเดน, สิงหล, สินธี, สเปน, สโลวัก, สโลวีเนีย, อังกฤษ, อัมฮาริก, อาร์เซอร์ไบจัน, อาร์เมเนีย, อาหรับ, อิกโบ, อิตาลี, อุยกูร์, อุสเบกิสถาน, อูรดู, ฮังการี, ฮัวซา, ฮาวาย, ฮินดี, ฮีบรู, เกลิกสกอต, เกาหลี, เขมร, เคิร์ด, เช็ก, เซอร์เบียน, เซโซโท, เดนมาร์ก, เตลูกู, เติร์กเมน, เนปาล, เบงกอล, เบลารุส, เปอร์เซีย, เมารี, เมียนมา (พม่า), เยอรมัน, เวลส์, เวียดนาม, เอสเปอแรนโต, เอสโทเนีย, เฮติครีโอล, แอฟริกา, แอลเบเนีย, โคซา, โครเอเชีย, โชนา, โซมาลี, โปรตุเกส, โปแลนด์, โยรูบา, โรมาเนีย, โอเดีย (โอริยา), ไทย, ไอซ์แลนด์, ไอร์แลนด์, การแปลภาษา.
- ใช่ คุณน่ารัก สุภาพมากสำหรับฉัน
- i- if it's that cold...then you can slee
- acid-insoluble ash Not more than 2.0 per
- เอ็นไก่ผสมงาขาวปรุงรสคลุกแป้งนำไปทอดทานก
- อยากไปที่นั้นเร็วๆ
- 장소
- SomeTimes
- ฉันกำลังจะนอนแล้ว
- การดำเนินการ
- I prefer
- Samsung hero strong durable Like a Super
- ขันชุลี
- ฉันรอคุณออนxat
- She it call me. Sorry alone in worry
- ฉันไม่รู้ว่ามันต้องออกเสียงอย่างไร
- กรอกคำสำคัญชื่อหนังสือ
- ข้อแนะนำในการดื่ม
- ข้าว
- termini
- ฉันรักวันหยุด ฉันรักปีใหม่ ฉันคิดว่าทุกๆ
- นั้นสิคะ คุณมีความสุขใช่ไหม??^_^
- very beautiful. want to go there soon
- คุณต้องรู้อะไรอีก
- She it call me.know or rye is a worry
