I E Woodrow
Overview
Explore the profile of I E Woodrow including associated specialties, affiliations and a list of published articles.
Author names and details appear as published. Due to indexing inconsistencies, multiple individuals may share a name, and a single author may have variations. MedLuna displays this data as publicly available, without modification or verification
Snapshot
Snapshot
Articles
29
Citations
322
Followers
0
Related Specialties
Related Specialties
Top 10 Co-Authors
Top 10 Co-Authors
Published In
Published In
Affiliations
Affiliations
Soon will be listed here.
Recent Articles
1.
Lawler I, Foley W, Woodrow I, Cork S
Oecologia
. 2017 Mar;
109(1):59-68.
PMID: 28307613
Seedlings of Eucalyptus tereticornis (Smith) were grown under two levels of availability each of CO (352 and 793 µmol mol), soil nutrients (1/24 and 1/4 Hoagland's solution) and light (full...
2.
Woodrow I
Photosynth Res
. 2013 Dec;
39(3):401-12.
PMID: 24311132
A range of studies of C3 plants have shown that there is a change in both the carbon flux and the pattern of nitrogen allocation when plants are grown under...
3.
Woodrow I, Raymond Ellis J, Jellings A, Foyer C
Planta
. 2013 Nov;
161(6):525-30.
PMID: 24253921
An analysis of the compartmentation and fluxes of inorganic phosphate in isolated cladophyll cells from Asparagus officinalis was made in parallel with an ultrastructural study. The elution pattern of labelled...
4.
Kreimer G, Surek B, Woodrow I, Latzko E
Planta
. 2013 Nov;
171(2):259-65.
PMID: 24227335
Calcium binding to spinach (Spinacia oleracea L.) stromal proteins was examined by dual-wavelength spectrophotometry using the metallochromic indicator tetramethylmurexide. The data are consistent with the existence of at least two,...
5.
Lovelock C, Clough B, Woodrow I
Planta
. 2013 Nov;
188(2):143-54.
PMID: 24178250
Ultraviolet (UV)-absorbing phenolic compounds that have been shown to be protective against the damaging: effects of UV-B radiation (Tevini et al., 1991, Photochem. Photobiol. 53, 329-333) were found in the...
6.
Heskes A, Lincoln C, Goodger J, Woodrow I, Smith T
J Microsc
. 2012 Mar;
247(1):33-42.
PMID: 22394321
Multiphoton fluorescence lifetime imaging provides an excellent tool for imaging deep within plant tissues while providing a means to distinguish between fluorophores with high spatial and temporal resolution. Ideal candidates...
7.
Fernando D, Mizuno T, Woodrow I, Baker A, Collins R
New Phytol
. 2010 Sep;
188(4):1014-27.
PMID: 20819177
Plant hyperaccumulation of the essential nutrient manganese (Mn) is a rare phenomenon most evident in the Western Pacific region, and differs from hyperaccumulation of other elements. Mn hyperaccumulators employ a...
8.
Fernando D, Woodrow I, Jaffre T, Dumontet V, Marshall A, Baker A
New Phytol
. 2007 Nov;
177(1):178-185.
PMID: 17986181
Hyperaccumulation by plants is a rare phenomenon that has potential practical benefits. The majority of manganese (Mn) hyperaccumulators discovered to date occur in New Caledonia, and little is known about...
9.
Simon J, Miller R, Woodrow I
Plant Biol (Stuttg)
. 2006 Oct;
9(1):152-7.
PMID: 17048139
The relationships between various leaf functional traits that are important in plant growth (e.g., specific leaf area) have been investigated in recent studies; however, research in this context on plants...
10.
Fernando D, Bakkaus E, Perrier N, Baker A, Woodrow I, Batianoff G, et al.
New Phytol
. 2006 Aug;
171(4):751-7.
PMID: 16918546
Little is known about the spatial distribution of excess manganese (Mn) in the leaves of tolerant plants. Recently, the first such study of a Mn hyperaccumulator showed that the highest...