@ARTICLE{TreeBASE2Ref28703,
author = {Tyler Maxwell and Richard Blair and Yuemin Wang and Andrew Hugh Kettring and Sean Moore and Matthew Rex and James Harper},
title = {A solvent-free approach for converting cellulose waste into hydrocarbon fuels with endophytic fungi},
year = {2018},
keywords = {Endophytic fungi; Mechanocatalysis; cellulose degradation; volatile organic compounds; myco-diesel; Hypoxylon},
doi = {},
url = {http://},
pmid = {},
journal = {Journal of Fungi},
volume = {},
number = {},
pages = {},
abstract = {Simple sugars produced from a solvent-free mechanocatalytic degradation of cellulose were evaluated for suitability as a growth medium carbon source for fungi that produce volatile organic compounds. An endophytic Hypoxylon sp. (CI-4) known to produce volatiles having potential value as fuels was initially evaluated. Rapid growth was obtained on a medium containing the degraded cellulose as the sole carbon source and the volatile compounds produced were largely the same as those produced from a conventional dextrose/starch diet. A second Hypoxylon sp. (BS15) was also characterized and shown to be phylogenetically divergent from any other named species. The degraded cellulose medium supports growth of BS15 and approximately the same quantity of volatile compounds were produced as from conventional diets. Although the major products from BS15 grown on degraded cellulose were identical to those from dextrose, minor products differed. Extraction of volatiles from growth media was achieved using solid-phase extraction in order to reduce solvent waste and more efficiently retain compounds having low vapor pressures. A comparison to more conventional liquid-liquid extraction demonstrates that, for CI-4, both methods gave similar results. Solid-phase extraction of BS15 retained a significantly larger variety of volatile compounds than liquid-liquid extraction. These advances positon the coupling of solvent-free cellulose conversion and endophyte metabolism as a viable strategy for the production of important hydrocarbons.}
}
Citation for Study 23089
Citation title:
"A solvent-free approach for converting cellulose waste into hydrocarbon fuels with endophytic fungi".
Study name:
"A solvent-free approach for converting cellulose waste into hydrocarbon fuels with endophytic fungi".
This study is part of submission 23089
(Status: Published).
Citation
Maxwell T., Blair R., Wang Y., Kettring A.H., Moore S., Rex M., & Harper J. 2018. A solvent-free approach for converting cellulose waste into hydrocarbon fuels with endophytic fungi. Journal of Fungi, .
Authors
-
Maxwell T.
-
Blair R.
-
Wang Y.
-
Kettring A.H.
-
Moore S.
-
Rex M.
-
Harper J.
Abstract
Simple sugars produced from a solvent-free mechanocatalytic degradation of cellulose were evaluated for suitability as a growth medium carbon source for fungi that produce volatile organic compounds. An endophytic Hypoxylon sp. (CI-4) known to produce volatiles having potential value as fuels was initially evaluated. Rapid growth was obtained on a medium containing the degraded cellulose as the sole carbon source and the volatile compounds produced were largely the same as those produced from a conventional dextrose/starch diet. A second Hypoxylon sp. (BS15) was also characterized and shown to be phylogenetically divergent from any other named species. The degraded cellulose medium supports growth of BS15 and approximately the same quantity of volatile compounds were produced as from conventional diets. Although the major products from BS15 grown on degraded cellulose were identical to those from dextrose, minor products differed. Extraction of volatiles from growth media was achieved using solid-phase extraction in order to reduce solvent waste and more efficiently retain compounds having low vapor pressures. A comparison to more conventional liquid-liquid extraction demonstrates that, for CI-4, both methods gave similar results. Solid-phase extraction of BS15 retained a significantly larger variety of volatile compounds than liquid-liquid extraction. These advances positon the coupling of solvent-free cellulose conversion and endophyte metabolism as a viable strategy for the production of important hydrocarbons.
Keywords
Endophytic fungi; Mechanocatalysis; cellulose degradation; volatile organic compounds; myco-diesel; Hypoxylon
External links
About this resource
- Canonical resource URI:
http://purl.org/phylo/treebase/phylows/study/TB2:S23089
- Other versions:
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NeXML
- Show BibTeX reference
@ARTICLE{TreeBASE2Ref28703,
author = {Tyler Maxwell and Richard Blair and Yuemin Wang and Andrew Hugh Kettring and Sean Moore and Matthew Rex and James Harper},
title = {A solvent-free approach for converting cellulose waste into hydrocarbon fuels with endophytic fungi},
year = {2018},
keywords = {Endophytic fungi; Mechanocatalysis; cellulose degradation; volatile organic compounds; myco-diesel; Hypoxylon},
doi = {},
url = {http://},
pmid = {},
journal = {Journal of Fungi},
volume = {},
number = {},
pages = {},
abstract = {Simple sugars produced from a solvent-free mechanocatalytic degradation of cellulose were evaluated for suitability as a growth medium carbon source for fungi that produce volatile organic compounds. An endophytic Hypoxylon sp. (CI-4) known to produce volatiles having potential value as fuels was initially evaluated. Rapid growth was obtained on a medium containing the degraded cellulose as the sole carbon source and the volatile compounds produced were largely the same as those produced from a conventional dextrose/starch diet. A second Hypoxylon sp. (BS15) was also characterized and shown to be phylogenetically divergent from any other named species. The degraded cellulose medium supports growth of BS15 and approximately the same quantity of volatile compounds were produced as from conventional diets. Although the major products from BS15 grown on degraded cellulose were identical to those from dextrose, minor products differed. Extraction of volatiles from growth media was achieved using solid-phase extraction in order to reduce solvent waste and more efficiently retain compounds having low vapor pressures. A comparison to more conventional liquid-liquid extraction demonstrates that, for CI-4, both methods gave similar results. Solid-phase extraction of BS15 retained a significantly larger variety of volatile compounds than liquid-liquid extraction. These advances positon the coupling of solvent-free cellulose conversion and endophyte metabolism as a viable strategy for the production of important hydrocarbons.}
}
- Show RIS reference
TY - JOUR
ID - 28703
AU - Maxwell,Tyler
AU - Blair,Richard
AU - Wang,Yuemin
AU - Kettring,Andrew Hugh
AU - Moore,Sean
AU - Rex,Matthew
AU - Harper,James
T1 - A solvent-free approach for converting cellulose waste into hydrocarbon fuels with endophytic fungi
PY - 2018
KW - Endophytic fungi; Mechanocatalysis; cellulose degradation; volatile organic compounds; myco-diesel; Hypoxylon
UR - http://dx.doi.org/
N2 - Simple sugars produced from a solvent-free mechanocatalytic degradation of cellulose were evaluated for suitability as a growth medium carbon source for fungi that produce volatile organic compounds. An endophytic Hypoxylon sp. (CI-4) known to produce volatiles having potential value as fuels was initially evaluated. Rapid growth was obtained on a medium containing the degraded cellulose as the sole carbon source and the volatile compounds produced were largely the same as those produced from a conventional dextrose/starch diet. A second Hypoxylon sp. (BS15) was also characterized and shown to be phylogenetically divergent from any other named species. The degraded cellulose medium supports growth of BS15 and approximately the same quantity of volatile compounds were produced as from conventional diets. Although the major products from BS15 grown on degraded cellulose were identical to those from dextrose, minor products differed. Extraction of volatiles from growth media was achieved using solid-phase extraction in order to reduce solvent waste and more efficiently retain compounds having low vapor pressures. A comparison to more conventional liquid-liquid extraction demonstrates that, for CI-4, both methods gave similar results. Solid-phase extraction of BS15 retained a significantly larger variety of volatile compounds than liquid-liquid extraction. These advances positon the coupling of solvent-free cellulose conversion and endophyte metabolism as a viable strategy for the production of important hydrocarbons.
L3 -
JF - Journal of Fungi
VL -
IS -
ER -
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