Yutaka Nakai
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Explore the profile of Yutaka Nakai including associated specialties, affiliations and a list of published articles.
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82
Citations
702
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Recent Articles
1.
Takizawa S, Asano R, Abe K, Fukuda Y, Baba Y, Sakurai R, et al.
Microbes Environ
. 2024 Jun;
39(2).
PMID: 38839366
No abstract available.
2.
Takizawa S, Asano R, Abe K, Fukuda Y, Baba Y, Sakurai R, et al.
Microbes Environ
. 2023 Sep;
38(3).
PMID: 37766554
Rumen fibrolytic microorganisms have been used to increase the rate of lignocellulosic biomass biodegradation; however, the microbial and isozymatic characteristics of biodegradation remain unclear. Therefore, the present study investigated the...
3.
Takizawa S, Asano R, Fukuda Y, Baba Y, Tada C, Nakai Y
Microb Biotechnol
. 2021 Dec;
15(6):1729-1743.
PMID: 34964273
Treatment with rumen fluid improves methane production from non-degradable lignocellulosic biomass during subsequent methane fermentation; however, the kinetics of xylanases during treatment with rumen fluid remain unclear. This study aimed...
4.
Takizawa S, Asano R, Fukuda Y, Baba Y, Tada C, Nakai Y
Anim Sci J
. 2021 Oct;
92(1):e13653.
PMID: 34714591
Rumen microorganisms produce various fibrolytic enzymes and degrade lignocellulosic materials into nutrient sources for ruminants; therefore, the characterization of fibrolytic enzymes contributing to the polysaccharide degradation in the rumen microbiota...
5.
Takizawa S, Asano R, Fukuda Y, Feng M, Baba Y, Abe K, et al.
Front Microbiol
. 2021 Jan;
11:603818.
PMID: 33391225
Treatment with rumen microorganisms improves the methane fermentation of undegradable lignocellulosic biomass; however, the role of endoglucanase in lignocellulose digestion remains unclear. This study was conducted to investigate endoglucanases contributing...
6.
Mori Y, Tada C, Fukuda Y, Nakai Y
Microbes Environ
. 2020 Jul;
35(3).
PMID: 32713897
Sulfur-oxidizing bacterial diversity at the surface of cattle manure was characterized throughout the composting process using a sulfur oxidation gene (soxB) clone library approach. In the mesophilic phase, clones related...
7.
Pretreatment with rumen fluid improves methane production in the anaerobic digestion of paper sludge
Takizawa S, Baba Y, Tada C, Fukuda Y, Nakai Y
Waste Manag
. 2020 Jun;
78:379-384.
PMID: 32559924
Because paper sludge discharged from the waste paper recycling process contains high levels of lignin and ash, it is not hydrolyzed effectively during anaerobic digestion. In this study, we investigated...
8.
Lee C, Baba Y, Asano R, Fukuda Y, Tada C, Nakai Y
J Biosci Bioeng
. 2020 Apr;
130(2):137-141.
PMID: 32331776
We had developed a new pretreatment system using cow rumen fluid to improve the methane production from lignocellulosic substrates. However, the pretreatment conditions differ from the in-situ rumen environment, therefore...
9.
Baba Y, Matsuki Y, Takizawa S, Suyama Y, Tada C, Fukuda Y, et al.
Microbes Environ
. 2019 Nov;
34(4):421-428.
PMID: 31748428
The pretreatment of lignocellulosic substrates with cattle rumen fluid was successfully developed to increase methane production. In the present study, a 16S rRNA gene-targeted amplicon sequencing approach using the MiSeq...
10.
Takizawa S, Baba Y, Tada C, Fukuda Y, Nakai Y
Waste Manag
. 2019 May;
87:672-678.
PMID: 31109569
It is necessary to preserve rumen fluid for transport from slaughterhouses to the pretreatment facilities for use in treating lignocellulosic biomass. In this study, we investigated how the preservation of...