Page 109 - 80_02
P. 109
Almudena
Gómez--Hernández
&
al.
126. Marchesi
C,
Ebrahimian
T,
Angulo
O,
Paradis
P,
Schiffrin
EL.
Endothelial
nitric
oxide
synthase
uncoupling
and
perivascular
adipose
oxidative
stress
and
inflammation
contribute
to
vascular
dysfunction
in
a
rodent
model
of
metabolic
syndrome.
Hypertension.
2009;
54(6):1384–92.
127. Sacks
HS,
Fain
JN.
Human
epicardial
fat:
what
is
new
and
what
is
missing?
Clin.
Exp.
Pharmacol.
Physiol.
2011;
38(12):879–887.
128. Mazurek
T,
Zhang
L,
Zalewski
A,
Mannion
JD,
Diehl
JT,
Arafat
H,
et
al.
Human
epicardial
adipose
tissue
is
a
source
of
inflammatory
mediators.
Circulation.
2003;
108(20):2460–6.
129. Redman
LM,
Ravussin
E.
Endocrine
alterations
in
response
to
calorie
restriction
in
humans.
Mol
Cell
Endocrinol.
2009;
299(1):129--36.
130. Howell
A,
Chapman
M,
Harvie
M.
Energy
restriction
for
breast
cancer
prevention.
Recent
Results
Cancer
Res.
2009;
181:97--111.
131. López--Lluch
G,
Hunt
N,
Jones
B,
Zhu
M,
Jamieson
H,
Hilmer
S,
et
al.
Calorie
restriction
induces
mitochondrial
biogenesis
and
bioenergetic
efficiency.
Proc
Natl
Acad
Sci
U
S
A.
2006;
103(6):1768--73.
132. Liu
D,
Pitta
M,
Mattson
MP.
Preventing
NAD(+)
depletion
protects
neurons
against
excitotoxicity:
bioenergetic
effects
of
mild
mitochondrial
uncoupling
and
caloric
restriction.
Ann
N
Y
Acad
Sci.
2008;
1147:275--82.
133. Kamel
EG,
McNeill
G,
Van
Wijk
MC.
Change
in
intra--abdominal
adipose
tissue
volume
during
weight
loss
in
obese
men
and
women:
correlation
between
magnetic
resonance
imaging
and
anthropometric
measurements.
Int
J
Obes
Relat
Metab
Disord.
2000;
24(5):607--13.
134. Seidell
JC.Environmental
influences
on
regional
fat
distribution.
Int
J
Obes.
1991;
15
Suppl
2:31--5.
135. Varady
KA,
Bhutani
S,
Klempel
MC,
Kroeger
CM.
Comparison
of
effects
of
diet
versus
exercise
weight
loss
regimens
on
LDL
and
HDL
particle
size
in
obese
adults.
Lipids
Health
Dis.
2011;
10:119.
136. Saris
WH.
Effects
of
energy
restriction
and
exercise
on
the
sympathetic
nervous
system.
Int
J
Obes
Relat
Metab
Disord.
1995;
19
Suppl
7:S17--S23.
137. Zorba
E,
Cengiz
T,
Karacabey
K.
Exercise
training
improves
body
composition,
blood
lipid
profile
and
serum
insulin
levels
in
obese
children.
J
Sports
Med
Phys
Fitness.
2011;
51(4):664--9.
138. Lamarche
B,
Després
JP,
Moorjani
S,
Nadeau
A,
Lupien
PJ,
Tremblay
A,
et
al.
Evidence
for
a
role
of
insulin
in
the
regulation
of
abdominal
adipose
tissue
lipoprotein
lipase
response
to
exercise
training
in
obese
women.
Int
J
Obes
Relat
Metab
Disord.
1993;
17(5):255--61.
139. Tremblay
A,
Nadeau
A,
Després
JP,
St--Jean
L,
Thériault
G,
Bouchard
C.
Long--term
exercise
training
with
constant
energy
intake.
2:
Effect
on
glucose
metabolism
and
resting
energy
expenditure.
Int
J
Obes.
1990;
14(1):75.
140. Langin
D.
Adipose
tissue
lipolysis
as
a
metabolic
pathway
to
define
pharmacological
strategies
against
obesity
and
the
metabolic
syndrome.
Pharmacol
Res.
2006;
53(6):482--91.
141. Enerbäck
S.
Human
brown
adipose
tissue.
Cell
Metab.
2010;
11(4):248--52.
142. Nedergaard
J,
Bengtsson
T,
Cannon
B.
New
powers
of
brown
fat:
fighting
the
metabolic
syndrome.
Cell
Metab.
2011;
13(3):238--40
143. Langin
D.
Recruitment
of
brown
fat
and
conversion
of
white
into
brown
adipocytes:
strategies
to
fight
the
metabolic
complications
of
obesity?
Biochim
Biophys
Acta.
2010;
1801(3):372--6.
144. Farmer
SR.
Brown
fat
and
skeletal
muscle:
unlikely
cousins?
Cell.
2008;134(5):726--7.
145. Schulz
TJ,
Huang
TL,
Tran
TT,
Zhang
H,
Townsend
KL,
Shadrach
JL,
et
al.
Identification
of
inducible
brown
adipocyte
progenitors
residing
in
skeletal
muscle
and
white
fat.
Proc
Natl
Acad
Sci
U
S
A.
2011;
108(1):143--8.
146. Townsend
KL,
Tseng
YH.
Brown
adipose
tissue.
Recent
insights
into
development,
metabolic
function
and
therapeutic
potential.
Adipocyte
2012;
1(1):13--24.
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