èŠ‚ç‚¹æ–‡çŒ®

ä¸åŒå«ç£·åŒ–åˆç‰©ä¿®å¤é“…æ±¡æŸ“åœŸå£¤åŽçš„äººä½“å¥åº·é£Žé™©è¯„ä»·

Human health risk assessment for lead contaminated soil after remediation with several phosphate compounds

æŽ¨è CAJä¸‹è½½
PDFä¸‹è½½
ä¸æ”¯æŒè¿…é›·ç‰ä¸‹è½½å·¥å…·ï¼Œè¯·å–æ¶ˆåŠ é€Ÿå·¥å…·åŽä¸‹è½½ã€‚

ã€ä½œè€…ã€‘ æŽå²©ï¼› å°¹ä¹ƒæ¯…ï¼› éƒ½æ…§ä¸½ï¼› çŽ‹é¹é£žï¼› å™å›½æ–°ï¼› å´”å²©å±±ï¼›

ã€Authorã€‘ LI Yan;YIN Naiyi;DU Huili;WANG Pengfei;SUN Guoxin;CUI Yanshan;Sino-Danish College of University of Chinese Academy of Sciences;Research Center for Eco-Environmental Sciences, Chinese Academy of Sciences;College of Resources and Environment, University of Chinese Academy of Sciences;

ã€é€šè®¯ä½œè€…ã€‘ å´”å²©å±±;

ã€æœºæž„ã€‘ ä¸å›½ç§‘å¦é™¢å¤§å¦ä¸ä¸¹å¦é™¢ï¼› ä¸å›½ç§‘å¦é™¢ç”Ÿæ€çŽ¯å¢ƒç ”ç©¶ä¸å¿ƒï¼› ä¸å›½ç§‘å¦é™¢å¤§å¦èµ„æºä¸ŽçŽ¯å¢ƒå¦é™¢ï¼›

ã€æ‘˜è¦ã€‘ ç£·é…¸ç›é’åŒ–é“…æ˜¯é“…æ±¡æŸ“åœŸå£¤çš„é‡è¦ä¿®å¤æŠ€æœ¯ä¹‹ä¸€.ä½†ç£·é…¸ç›ä¿®å¤åœŸå£¤é“…æ±¡æŸ“åŽ,åœŸå£¤é“…å¯¹äººä½“çš„å¥åº·é£Žé™©ä»ç¼ºä¹ç³»ç»Ÿç ”ç©¶.æœ¬ç ”ç©¶é€šè¿‡å‘é“…æ±¡æŸ“åœŸå£¤æ·»åŠ äº”ç§ä¸åŒçš„å«ç£·åŒ–åˆç‰©ï¼ˆKH₂PO₄ã€NH₄H₂PO₄ã€CaHPO₄,æ¤é…¸å’Œåµç£·è„‚ï¼‰,åˆ†æžäº†å…¶å¯¹é“…æ±¡æŸ“åœŸå£¤çš„é’åŒ–æ•ˆæžœ,è¿ç”¨in vitroå’ŒSHIMEæ¨¡åž‹è¯„ä¼°ä¿®å¤åŽåœŸå£¤é“…å¯¹äººä½“çš„å¥åº·é£Žé™©.ç»“æžœè¡¨æ˜Ž,æ·»åŠ å«ç£·åŒ–åˆç‰©30 dåŽ,äº”ç§å¤„ç†å‡æœ‰æ•ˆé™ä½Žäº†é“…çš„DTPAå’ŒCaCl₂å¯æå–æ€,åˆ†åˆ«é™ä½Žäº†62.5%â€”66.5%å’Œ27.8%â€”49.5%,å…¶ä¸æ¤é…¸å’ŒCaHPO₄å¤„ç†æ•ˆæžœè¾ƒå¥½,åµç£·è„‚å¤„ç†æ•ˆæžœè¾ƒå·®.5ç§å¤„ç†ä¸,é“…çš„ç”Ÿç‰©å¯ç»™æ€§åœ¨èƒƒã€å°è‚ å’Œç»“è‚ é˜¶æ®µæœ‰æ˜¾è‘—å·®å¼‚,åˆ†åˆ«ä¸º8.67%â€”9.31%ã€0.88%â€”1.55%ã€2.06%â€”2.76%,ç”±äºŽå—pHçš„å½±å“,é“…åœ¨èƒƒé˜¶æ®µç”Ÿç‰©å¯ç»™æ€§æœ€é«˜ä¸”å„å¤„ç†ä¹‹é—´å·®å¼‚ä¸æ˜Žæ˜¾,åœ¨å°è‚ é˜¶æ®µKH₂PO₄å¤„ç†åœŸå£¤é“…çš„ç”Ÿç‰©å¯ç»™æ€§æœ€ä½Ž,åµç£·è„‚å¤„ç†é“…çš„ç”Ÿç‰©å¯ç»™æ€§æœ€é«˜,ç»“è‚ é˜¶æ®µNH₄H₂PO₄å¤„ç†åœŸå£¤é“…çš„ç”Ÿç‰©å¯ç»™æ€§æœ€ä½Ž,åµç£·è„‚å¤„ç†é“…çš„ç”Ÿç‰©å¯ç»™æ€§æœ€é«˜.ç»“è‚ é˜¶æ®µé“…çš„ç”Ÿç‰©å¯ç»™æ€§å‡é«˜äºŽå°è‚ é˜¶æ®µçš„,å¯è§è‚ é“å¾®ç”Ÿç‰©ä¿ƒè¿›äº†åœŸå£¤ä¸Pbçš„æº¶å‡º,æé«˜äº†é“…çš„ç”Ÿç‰©å¯ç»™æ€§,å¢žåŠ äº†äººä½“çš„å¥åº·é£Žé™©.åœ¨æ·»åŠ åŒç‰å«é‡çš„å«ç£·åŒ–åˆç‰©ä¿®å¤é“…æ±¡æŸ“åœŸå£¤åŽ,KH₂PO₄å¤„ç†å¯¹äººä½“å¥åº·é£Žé™©æœ€å°,åµç£·è„‚æœ€å¤§.æ›´å¤š è¿˜åŽŸ

ã€Abstractã€‘ The use of phosphate as a stabilizing agent that is widely accepted and capable of lead-contaminated soil remediation. However, there are few studies on the assessment the risk of human health after remediation. In the study, five different phosphorus materialsï¼ˆKH₂PO₄,NH₄ H₂PO₄,CaHPO₄,Phytic acid and Lecithinï¼‰ were added to lead-contaminated oil, and theirs inactivation of lead was analyzed. In vitro and SHIME models were adopted to evaluate the risk of human health of soil lead after soil remediation. The results showed that, after adding P material for 30 days, the five materials obviously decreases by 62.5%â€”66.5% DTPA extractable Pb and by 27.8%â€”49.5% CaCl₂ extractable Pb. The Pb inactivation of CaHPO₄ and phytic acid was better than the others. Among the five treatments, the Pb bioaccessibility in different phase was quite different, about 8.67%â€”9.31% in gastric phase, 0.88%â€”1.55% in small intestinal phase and 2.06%â€”2.76% in colon phase. The Pb bioaccessibility was highest and no significant difference was observed within the five treatments according to the low pH in gastric phase. In small intestinal, the bioaccessibility of soil lead was lowest after adding KH₂PO₄, highest after adding lecithin. In colon phase, the bioaccessibility of soil lead was lowest after adding NH₄H₂PO₄, highest after adding lecithin. In addition, the bioaccessibility of lead in colon stage was higher than that in small intestine stage, suggested that the human gut microbiota could induced Pb release from soil and increased bioaccessibility, which may resulted in a high risk to human health. After remediation of lead-contaminated soil with the same amount of the five phosphorous materials, the human health risk was the lowest by KH₂PO₄ and the highest by lecithin.æ›´å¤š è¿˜åŽŸ