Jump to main content
US EPA
United States Environmental Protection Agency
Search
Search
Main menu
Environmental Topics
Laws & Regulations
About EPA
Health & Environmental Research Online (HERO)
Contact Us
Print
Feedback
Export to File
Search:
This record has one attached file:
Add More Files
Attach File(s):
Display Name for File*:
Save
Citation
Tags
HERO ID
2882734
Reference Type
Journal Article
Title
Potential cause of aerobic granular sludge breakdown at high organic loading rates
Author(s)
Adav, SS; Lee, DuuJ; Lai, JYih
Year
2010
Is Peer Reviewed?
Yes
Journal
Applied Microbiology and Biotechnology
ISSN:
0175-7598
EISSN:
1432-0614
Volume
85
Issue
5
Page Numbers
1601-1610
Language
English
PMID
19888574
DOI
10.1007/s00253-009-2317-9
Web of Science Id
WOS:000273743000035
Abstract
Aerobic sludge granules are compact, strong microbial aggregates that have excellent settling ability and capability to efficiently treat high-strength and toxic wastewaters. Aerobic granules disintegrate under high organic loading rates (OLR). This study cultivated aerobic granules using acetate as the sole carbon and energy source in three identical sequencing batch reactors operated under OLR of 9-21.3 kg chemical oxygen demand (COD) m(-3) day(-1). The cultivated granules removed 94-96% of fed COD at OLR up to 9-19.5 kg COD m(-3) day(-1), and disintegrated at OLR of 21.3 kg COD m(-3) day(-1). Most tested isolates did not grow in the medium at >3,000 mg COD l(-1); additionally, these strains lost capability for auto-aggregation and protein or polysaccharide productivity. This critical COD regime correlates strongly with the OLR range in which granules started disintegrating. Reduced protein quantity secreted by isolates was associated with the noted poor granule integrity under high OLR. This work identified a potential cause of biological nature for aerobic granules breakdown.
Keywords
Aerobic granule; Breakdown; OLR; Proteins; Isolates
Home
Learn about HERO
Using HERO
Search HERO
Projects in HERO
Risk Assessment
Transparency & Integrity