1 School of Physical and Health Education, and 2 Department of Medicine, Division of Endocrinology and Metabolism, Queen's University, Kingston, Ontario, Canada, K7L 3N6
![]() |
ABSTRACT |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
We examined the independent relationships
among various visceral and abdominal subcutaneous adipose tissue (AT)
depots, glucose tolerance, and insulin sensitivity in 89 obese men.
Measurements included an oral glucose tolerance test (OGTT), glucose
disposal by euglycemic clamp, and abdominal and nonabdominal (e.g.,
peripheral) AT by magnetic resonance imaging (MRI). OGTT glucose and
glucose disposal rates were related (P < 0.05) to
visceral AT (r = 0.50 and 0.41, respectively). These
observations remained significant (P < 0.05) after
control for nonabdominal and abdominal subcutaneous AT, and maximal
O2 consumption (
O2 max).
Abdominal subcutaneous AT was not a significant correlate
(P > 0.05) of any metabolic variable after control for
nonabdominal and visceral AT and
O2 max. Division of abdominal
subcutaneous AT into deep and superficial depots and visceral AT into
intra- and extraperitoneal AT depots did not alter the observed
relationships. Further analysis matched two groups of men for abdominal
subcutaneous AT but also for low and high visceral AT. Men with high
visceral AT had higher OGTT glucose values and lower glucose disposal
rates compared with those with low visceral AT values
(P < 0.05). A similar analysis performed on two groups
of men matched for visceral AT but also for high and low abdominal
subcutaneous AT revealed no statistically different values for any
metabolic variable (P > 0.10). In conclusion, visceral
AT alone is a strong correlate of insulin resistance independent of
nonabdominal and abdominal subcutaneous AT and cardiovascular fitness.
Subdivision of visceral and abdominal subcutaneous AT by MRI did not
provide additional insight into the relationship between abdominal
obesity and metabolic risk in obese men.
subcutaneous adipose tissue; insulin sensitivity; visceral adipose tissue
![]() |
INTRODUCTION |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
DEBATE CONTINUES regarding the independent contribution of abdominal subcutaneous and visceral adipose tissue (AT) toward the etiology of insulin resistance. Whereas some researchers report that visceral AT is the stronger correlate (11, 13, 15, 32), others find that abdominal subcutaneous AT is largely responsible for the established association between abdominal obesity and insulin resistance (1, 2, 19). It has recently been suggested that the discrepancies may be resolved by subdividing abdominal subcutaneous AT according to differences in metabolic characteristics (20, 26, 38, 40). Abdominal subcutaneous AT can be subdivided into superficial and deep compartments by use of the fascia superficialis. The rationale for this division presumes that adipocytes within the deep compartment are more metabolically active compared with superficial adipocytes (12, 25). On the assumption that the liberation of nonesterified fatty acids adversely effects insulin action (29, 37), it follows that the deep compartment would be the stronger predictor of insulin resistance. Indeed, Kelley et al. (20) have shown that deep, but not superficial, subcutaneous AT is strongly related to insulin resistance in a cohort of lean and obese men and women. Toth et al. (40) report similar observations in lean, premenopausal women. These findings confirm the earlier observation of Misra et al. (26), who report that posterior subcutaneous fat (analogous to deep subcutaneous fat in men) is associated with insulin resistance independently of visceral AT.
The subdivision of abdominal subcutaneous AT on the basis of metabolic characteristics is analogous to the partitioning of visceral AT into intraperitoneal and extraperitoneal depots on the basis of anatomical considerations. Subdivision of visceral AT is based on the premise that nonesterified fatty acids from intraperitoneal fat alone (omental and mesenteric adipocytes) are delivered directly to the liver and thus mediate hepatic insulin resistance: the so-called "portal theory" (9, 10). Thus isolation of intraperitoneal AT may improve upon the relationship between visceral AT per se and insulin resistance. To our knowledge, no study has simultaneously examined whether subdivision of abdominal subcutaneous and visceral AT improves the ability of either depot to predict insulin resistance.
Discrepancies regarding the singular importance of abdominal subcutaneous and visceral AT may also be explained by differences in the cohorts studied (11). In some of the reports indicating that abdominal subcutaneous AT independently predicts insulin resistance, the cohort examined combines men and women with wide variation in body composition and insulin sensitivity (19, 20). In other studies, wherein the investigators studied homogeneous groups of lean men (2) or lean women (40), the accumulation of visceral AT is below the threshold thought to be associated with distinct elevations in metabolic risk factors (14). By comparison, studies that found visceral AT the stronger predictor of insulin resistance are characterized by homogeneous populations of men or women with marked elevation in visceral AT (11, 13, 15, 32). However, in most of the these studies, abdominal subcutaneous AT was not subdivided into deep and superficial depots (13, 15, 32).
The primary purpose of this study, therefore, was to determine whether subdivision of abdominal subcutaneous and visceral AT strengthens the association between insulin resistance and either subcutaneous or visceral AT alone. To test this objective we studied a cohort of abdominally obese men at increased metabolic risk. We hypothesized that, in this homogenous group of men characterized by marked elevation in visceral obesity, visceral AT would be a strong correlate of insulin resistance independent of abdominal (anterior and posterior) and nonabdominal subcutaneous AT.
![]() |
METHODS |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
Subjects. The subjects consisted of 89 males who were initially recruited to participate in two weight loss studies (32, 35). The baseline data from these studies have not been reported previously. Inclusion criteria required that the subjects had a body mass index [BMI (weight in kg/height in m2)] >27, a waist-to-hip ratio >0.95, a stable weight (±2 kg) for 6 mo before the beginning of the study, consumption on average of less than two alcoholic beverages per day, and being nonsmokers and sedentary. All subjects were nondiabetic, as confirmed by plasma glucose levels in a fasting state and 2 h after a 75-g oral glucose tolerance test (OGTT) (4). All subjects gave their fully informed and written consent to participate in the study, which was conducted in accordance with the ethical guidelines set by Queen's University.
Anthropometric variables. Body mass was measured on a balance scale to the nearest 0.1 kg with the subjects dressed in light clothing. Standing height was measured to the nearest 0.1 cm with a wall-mounted stadiometer. Circumference measurements were taken, with the subjects in a standing position, at the level of the last rib and hip by means of standard procedures (21).
Tissue measurement by magnetic resonance imaging.
Whole body (41 images) magnetic resonance imaging (MRI) data were
obtained with a GE 1.5-Tesla scanner (GE, Milwaukee, WI) with the use
of an established protocol (35). The MRI data were transferred to a stand-alone work station (Silicon Graphics, Mountain View, CA) for analysis using special software (TomoVision, Montreal, QC, Canada) as described elsewhere (27, 35). Total AT
(subcutaneous + visceral + intrapelvic + intrathoracic + intermuscular) and skeletal muscle were determined
using all 41 images. Total (e.g., volume or mass) visceral and
abdominal subcutaneous AT were calculated using the five images
extending from 5 cm below to 15 cm above L4-L5. Nonabdominal AT
includes all AT other than abdominal subcutaneous and visceral AT (92%
of nonabdominal AT is peripheral subcutaneous AT; data not shown).
Abdominal subcutaneous AT was divided into anterior and posterior
compartments by drawing a perpendicular line along the anterior edge of
the vertebral bodies for all five abdominal MRI images (Fig.
1). Visceral AT was subdivided into intraperitoneal and extraperitoneal compartments by use of a method previously described (33, 36) and as illustrated in Fig.
1. AT volume units (l) were converted to mass units (kg) by multiplying the volumes by the assumed constant densities of 0.92 for adipose tissue and 1.04 for skeletal muscle (39).
|
Glucose tolerance. A 2-h, 75-g OGTT was administered the morning after an overnight fast. Blood samples were collected from the antecubital vein at 0, 60, and 120 min. Glucose was measured using an automated glucose analyzer (YSI 2300 Glucose Analyzer, Yellow Springs Instrument, Yellow Springs, OH). Plasma insulin was measured using a radioimmunoassay kit (Intermedico, Toronto, ON, Canada). Areas under the glucose and insulin curves were determined using a trapezoid model (3).
Insulin sensitivity.
Insulin sensitivity data were measured for 55 subjects with the use of
a hyperinsulinemic euglycemic clamp. All subjects consumed a weight
maintenance diet consisting of 200 g of carbohydrate for a minimum of
4 days before measurements of insulin sensitivity and were asked to
avoid strenuous physical activity for 3 days preceding the studies.
Subjects stayed in the hospital the night before the measurement of
insulin sensitivity. All measurements were performed at 8:00 AM after a
12- to 14-h overnight fast. An antecubital vein was catheterized for
infusion of insulin plus 20% glucose. An intravenous catheter
was inserted in a retrograde fashion in a hand vein, and the hand was
placed in a heating pad for sampling of arterialized blood. Insulin was
infused at the rate of 40 mU · m
2 · min
1 for 3 h. Plasma glucose was measured using an automated glucose analyzer (YSI
2300 Glucose Analyzer) every 5 min in arterialized blood. Glucose
disposal rate was calculated using the average exogenous glucose
infusion rate during the final 30 min of euglycemia.
Statistical analyses. Data are presented as group means ± SD. Relationships between fat depots and metabolic variables were determined using Pearson product-moment correlation coefficients. Independent correlations were determined using multiple regression stepwise analysis. Paired t-tests were used to determine differences between the sizes of the various AT depots at different levels of the abdomen. Unpaired t-tests were used to determine differences between groups matched for visceral and abdominal subcutaneous AT. Statistical procedures were performed using SYSTAT (SYSTAT, Evanston, IL).
![]() |
RESULTS |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
Subject characteristics.
Subjects characteristics are given in Table
1. Despite being obese, as indicated by
BMI (31.9 ± 2.8 kg/m2), the cohort was characterized
by wide variations in age and total and abdominal adiposity. Table
2 contains the intra- and extraperitoneal
AT values and the anterior and posterior abdominal subcutaneous AT
values of the five images obtained at different levels of the
abdomen. Intraperitoneal AT area (cm2) was greater
than extraperitoneal AT area at all levels of the abdomen
(P < 0.01, Table 2). Anterior subcutaneous AT area was greater (P < 0.01) than posterior subcutaneous AT area
at the top of the abdomen but less (P < 0.01) than
posterior subcutaneous AT at the bottom of the abdomen (Table 2). Total
visceral AT area was greater (P < 0.05) than total
abdominal subcutaneous AT area at the top of the abdomen but less
(P < 0.01) than total abdominal subcutaneous AT area
at the bottom of the abdomen (Table 2).
|
|
Relationship between abdominal fat depots and metabolic variables.
Total abdominal AT (visceral + subcutaneous) was significantly
(P < 0.05) correlated with all metabolic variables
with the exception of glucose disposal (Table
3). Separation of total abdominal AT into
visceral and subcutaneous AT revealed that visceral AT was
significantly (P < 0.05) correlated with fasting
glucose, OGTT glucose, and glucose disposal by euglycemic clamp,
whereas abdominal subcutaneous AT was significantly (P < 0.05) correlated with fasting and OGTT insulin values (Table 3).
Subdivision of visceral AT into intra- and extraperitoneal depots and
abdominal subcutaneous AT into anterior and posterior depots did not
alter the magnitude of the correlations with all metabolic variables (Table 3).
|
|
|
Relationship between abdominal fat area, fat mass, and metabolic
variables.
Visceral and subcutaneous AT area (cm2) was measured at
five levels through the abdomen. As expected, the visceral and
subcutaneous AT areas for each of the five images were significantly
(P < 0.01) correlated with the respective AT mass (kg)
(data not shown). Moreover, visceral and subcutaneous AT area measures
were related to the metabolic variables by a similar order of magnitude
for each of the five abdominal images (Table
6). Accordingly, the relationship between
visceral and abdominal subcutaneous AT mass (kg), derived using all
five abdominal images, and the respective metabolic variables was
similar to the relationships observed using AT area (cm2)
values (Table 6).
|
![]() |
DISCUSSION |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
In this study, we investigated the independent relationships among various abdominal AT depots with selected measures of insulin and glucose metabolism. The results demonstrate that visceral AT alone was a significant correlate of glucose tolerance and insulin resistance after statistical control for abdominal subcutaneous AT, nonabdominal AT, and cardiovascular fitness. Subdivision of abdominal subcutaneous AT into anterior and posterior compartments and visceral AT into intraperitoneal and extraperitoneal compartments by MRI did not provide additional insight.
The findings of this study suggest that visceral AT is a strong marker of insulin resistance independent of abdominal subcutaneous AT and cardiovascular fitness. That we employed a multislice MRI protocol to determine abdominal and nonabdominal (e.g., peripheral subcutaneous AT) AT depots, measured insulin resistance using the euglycemic clamp method, and performed our measurements in a homogeneous cohort reinforces the importance of visceral AT as a modulator of insulin resistance in abdominally obese men. These observations confirm and strengthen previous observations from others, who reported similar findings in Caucasian men (28, 32) and women (13, 15, 17, 22, 24), Asian men (5, 18), and African-American men and women (6). However, the findings here contrast with those of others who report that abdominal subcutaneous AT is the stronger correlate of insulin resistance (1, 2, 26, 20, 38, 40). The discrepant findings may be partially explained by differences in the cohorts studied. Several studies implicating abdominal subcutaneous AT as the stronger predictor of insulin resistance are characterized by cohorts that were gender mixed and varied widely in subcutaneous adiposity (19, 20). Because correlation coefficients are a function of the standard deviation of the dependent and independent variables, the greater the variability among observations (e.g., abdominal subcutaneous AT), the greater the correlation coefficient. Another, equally tenable, explanation for the discrepant findings is that, in some of the studies demonstrating that abdominal subcutaneous AT is a strong predictor of insulin resistance (19, 20, 38), the average values for visceral AT are substantially below the value (~130 cm2 at L4-L5) thought to be associated with a marked increase in metabolic risk (14). By contrast, in this study and others (11, 17, 32), wherein a strong, independent relationship between visceral AT and insulin resistance is reported, average values for visceral AT far exceed the 130 cm2 value.
It has also been suggested that discrepancies in the literature regarding the independent relationship between visceral AT, abdominal subcutaneous AT, and insulin resistance may be resolved by subdividing abdominal subcutaneous AT on the basis of metabolic characteristics (18, 36, 38). Abdominal subcutaneous AT can be subdivided into superficial and deep compartments by using the fascia superficialis (23). The rationale for this division derives from animal studies indicating that adipocytes within the deep compartment are more metabolically active than superficial adipocytes (12, 25). With the assumption that the liberation of nonesterified fatty acids adversely affects insulin action (29, 37), it follows that the deep compartment would be the stronger predictor of insulin resistance. Interestingly, recent in vivo evidence suggests that the lipolytic rate of superficial abdominal subcutaneous AT in the anterior abdomen in normal-weight men is higher than that of the deep subcutaneous AT located in the posterior abdominal wall (16). Thus preliminary evidence in human volunteers does not appear to support the hypothesis derived from animal models suggesting that deep abdominal subcutaneous AT is more lipolytically active compared with superficial depots. Despite this observation, several reports observe that deep abdominal subcutaneous AT is a strong correlate of insulin action (20, 38, 40). Findings that confirm the earlier report by Misra et al. (26), that posterior abdominal subcutaneous AT measured by MRI (analogous to deep subcutaneous AT in men) compared with anterior compartment mass, displayed a stronger relationship with glucose disposal. Because we employed an MRI protocol similar to that used by Misra et al., it is unlikely that the equivocal findings are explained by methodological differences. However, although the majority of deep subcutaneous AT is located in the posterior half of the abdomen in men (20, 38), the two compartments (posterior subcutaneous vs. deep subcutaneous AT) are not precisely the same; thus differences between our findings and those that employed computed tomography may be explained by differences in the technique used to subdivide abdominal subcutaneous AT.
It is hypothesized that the complications associated with visceral AT may be related to the portally drained fat originating within the peritoneal cavity (intraperitoneal fat) (9, 10). Although access to portal circulation in humans is not practical, data from animal models confirm that intra-abdominal AT is positively related to hepatic insulin resistance (5, 7). Because extraperitoneal AT drains systemically, it has been suggested that removal of extraperitoneal AT would strengthen the relationship between visceral AT and metabolic risk (2). In support of this hypothesis, Abate and colleagues (2, 3) twice reported that intraperitoneal fat is a stronger correlate of insulin resistance compared with extraperitoneal fat. However, in those studies, the authors did not confirm whether intraperitoneal AT was a better predictor of insulin resistance than visceral AT per se (intraperitoneal and extraperitoneal). The observations here are consistent with previous findings from our group indicating that subdivision of visceral AT does not improve on the relationship observed between visceral AT per se and plasma lipid profile (31) and insulin action (30, 33). These observations might be expected, given that intraperitoneal AT comprises ~75% of the total visceral depot (30, 31, 33). Coupled with the fact that intraperitoneal AT is highly correlated with total visceral AT (r = 0.98; data not shown), it is not surprising that isolation of intraperitoneal AT does not enhance the relationship between visceral AT per se and insulin metabolism.
In this study, the use of a multislice MRI model revealed that the correlations obtained between subcutaneous AT or visceral AT area (cm2) and insulin resistance were essentially unchanged regardless of which abdominal image was used to quantify AT area. This finding confirms a previous observation from our group (31), wherein the association between visceral AT and plasma lipid profile remained significant independently of the abdominal image used to estimate visceral AT. Together, these observations suggest that the commonly used L4-L5 level for MRI or computed tomography measurement is an accurate measure of abdominal AT distribution and of the relationships between subcutaneous or visceral AT distribution and insulin resistance. This finding is consistent with the observation that the visceral AT area at the level of L4-L5 is highly correlated with both the visceral AT area of adjacent abdominal images (34, 38) and the visceral AT mass derived from multiple images (34).
In summary, the findings of this study reinforce the notion that visceral AT is a robust marker of insulin resistance in abdominally obese men independent of nonabdominal and abdominal subcutaneous AT and cardiovascular fitness. This observation remains true independent of the level of the abdomen at which visceral or abdominal subcutaneous AT was measured. It would also appear that further subdivision of visceral and abdominal subcutaneous AT with the use of the MRI method described here provides no additional insight into the relationship between abdominal obesity and metabolic risk in obese men.
![]() |
ACKNOWLEDGEMENTS |
---|
This work was supported by Canadian Institutes of Health Research Grant MT 13448 and Natural Sciences and Engineering Council of Canada Grant OGPIN 030 (to R. Ross). I. Janssen was supported by a Heart and Stroke Foundation of Canada Research Trainee Award.
![]() |
FOOTNOTES |
---|
Address for reprint requests and other correspondence: R. Ross, School of Physical and Health Education, Queen's Univ., Kingston, Ontario, Canada, K7L 3N6 (E-mail: rossr{at}post.queensu.ca).
The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
10.1152/ajpendo.00469.2001
Received 17 October 2001; accepted in final form 8 November 2001.
![]() |
REFERENCES |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
1.
Abate, N,
Garg A,
Peshock R,
Stray-Gundersen J,
Adama-Huet B,
and
Grundy S.
Relationship of generalized and regional adiposity to insulin sensitivity in men with NIDDM.
Diabetes
45:
1684-1693,
1996[Abstract].
2.
Abate, N,
Garg A,
Peshok R,
Stray-Gundersen J,
and
Grundy S.
Relationship of generalized and regional adiposity to insulin sensitivity in men.
J Clin Invest
96:
88-98,
1995[ISI][Medline].
3.
Allison, DB,
Paultre F,
Maggio C,
Mezzitis N,
and
Pi-Sunyer FX.
The use of area under the curve in diabetes research.
Diabetes Care
18:
245-250,
1992[Abstract].
4.
American Diabetes Association.
Screening for type 2 diabetes.
Diabetes Care
12:
S20-S22,
1998.
5.
Banjeri, MA,
Faridi N,
Atluri R,
Chaiken RL,
and
Lebovitz HE.
Body composition, visceral fat, leptin, and insulin resistance in Asian Indian men.
J Clin Endocrinol Metab
84:
137-144,
1999
6.
Banerji, MA,
Lebowitz J,
Chaiken RL,
Gordon D,
Kral JG,
and
Lebovitz HE.
Relationship of visceral adipose tissue and glucose disposal is independent of sex in black NIDDM subjects.
Am J Physiol Endocrinol Metab
273:
E425-E432,
1997
7.
Barzilai, N,
Banerjee S,
Hawkins M,
Chen W,
and
Rossetti L.
Caloric restriction reverses hepatic insulin resistance in aging rats by decreasing visceral fat.
J Clin Invest
101:
1353-1358,
1998
8.
Barzilai, N,
She L,
Liu BQ,
Vaguin P,
Cohen P,
Wang J,
and
Rosetti L.
Surgical removal of viseral fat reverses hepatic insulin resistance.
Diabetes
8:
94-98,
1999.
9.
Björntorp, P.
"Portal" adipose tissue as a generator of risk factors for cardiovascular disease and diabetes.
Arteriosclerosis
10:
493-496,
1990[Medline].
10.
Björntorp, P.
Metabolic implications of body fat distribution.
Diabetes Care
14:
1132-1143,
1991[Abstract].
11.
Brochu, M,
Starling RD,
Tchernof A,
Matthews D,
Garcia-Rubi E,
and
Poehlman ET.
Visceral adipose tissue is an independent correlate of glucose disposal in older obese postmenopausal women.
J Clin Endocrinol Metab
85:
2378-2384,
2000
12.
Carey, G.
The swine as a model for studying exercise induced changes in lipid metabolism.
Med Sci Sports Exerc
29:
1437-1444,
1997[ISI][Medline].
13.
DeNino, WF,
Tchernof A,
Dionne IJ,
Toth MJ,
Ades PA,
Sites CK,
and
Poehlman ET.
Contribution of abdominal adiposity to age-related differences in insulin sensitivity and plasma lipids in healthy nonobese women.
Diabetes Care
24:
925-932,
2001
14.
Després, J-P,
and
Lamarche B.
Effects of diet and physical activity on adiposity and body fat distribution: implications for the prevention of cardiovascular disease.
Nutr Res Rev
6:
137-159,
1993.
15.
Després J-P, Nadeau A, Tremblay A, Ferland M, Moorjani S, Lupein
P, Theriault G, Pinault S, and Bouchard C. Role of deep abdominal
fat in the association between regional adipose tissue distribution and
glucose tolerance in obese women. Diabetes :304-309,
1989.
16.
Enevoldsen, LH,
Simonsen L,
Stallknecht B,
Galbo H,
and
Bülow J.
In vivo human lipolytic activity in preperitoneal and subdivisions of subcutaneous abdominal adipose tissue.
Am J Physiol Endocrinol Metab
281:
E1110-E1114,
2001
17.
Fujioka, S,
Matsuzawa Y,
Tokunaga K,
and
Tarui S.
Contribution of intra-abdominal fat accumulation to the impairment of glucose and lipid metabolism.
Metabolism
36:
54-59,
1987[ISI][Medline].
18.
Fujiomoto, WY,
Abbate SL,
Kahn SE,
Hokason JE,
and
Brunzell JD.
The visceral adiposity syndrome in Japanese-American men.
Obes Res
2:
364-371,
1994.
19.
Goodpaster, BH,
Thaete FL,
Simoneau JA,
and
Kelley DE.
Subcutaneous abdominal fat and thigh muscle composition predict insulin sensitivity independently of visceral fat.
Diabetes
46:
1579-1585,
1997[Abstract].
20.
Kelley, DE,
Thaete EL,
Troost F,
Huwe T,
and
Goodpaster BH.
Subdivisions of subcutaneous abdominal adipose tissue and insulin resistance.
Am J Physiol Endocrinol Metab
278:
E941-E948,
2000
21.
Lohman, TG,
Roche AF,
and
Martello R
(Editors).
Anthropometric Standardization Reference Manual. Champaign, IL: Human Kinetics, 1988.
22.
Lovejoy, JC,
Smith SR,
and
Rood JC.
Comparison of regional fat distribution and health risk factors in middle-aged White and African American women: the healthy transitions study.
Obes Res
9:
10-16,
2001
23.
Markman, B,
and
Barton F.
Anatomy of the subcutaneous tissue of the trunk and lower extremity.
Plastic Reconstr Surg
80:
248-254,
1987[ISI][Medline].
24.
Matsuzawa, Y,
Shimomura I,
Nakamura T,
Keno Y,
Kotani K,
and
Katsuto T.
Pathophysiology and pathogenesis of visceral fat obesity.
Obes Res
3:
187S-194S,
1995[Abstract].
25.
Mersmann, HJ,
and
Leymaster K.
Differential deposition and utilization of backfat layers in swine.
Growth
48:
321-330,
1984[ISI][Medline].
26.
Misra, A,
Garg A,
Abate N,
Peshock R,
Stray-Gundersen J,
and
Grundy S.
Relationship of anterior and posterior subcutaneous abdominal fat to insulin sensitivity in nondiabetic men.
Obes Res
5:
93-99,
1997[Abstract].
27.
Mitsiopoulos, N,
Baumgartner RN,
Heymsfield SB,
Lyons W,
Gallager D,
and
Ross R.
Cadaver validation of magnetic resonance imaging and computerized tomography measurements of human skeletal muscle.
J Appl Physiol
85:
115-122,
1998
28.
Park, KS,
Rhee BD,
Lee KU,
Kim SY,
Lee HK,
Koh CS,
and
Min HK.
Intra-abdominal fat is associated with decreased insulin sensitivity in healthy young men.
Metabolism
40:
600-603,
1991[ISI][Medline].
29.
Randle, P,
Hales C,
Garland P,
and
Newsholme E.
The glucose fatty acid cycle.
Lancet
1:
785-789,
1963[ISI].
30.
Rice, B,
Janssen I,
Hudson R,
and
Ross R.
Effects of aerobic or resistance exercise and or diet on glucose tolerance and plasma insulin levels in men.
Diabetes Care
22:
684-691,
1999[Abstract].
31.
Rissanen, J,
Hudson R,
and
Ross R.
Visceral adiposity, androgens, and plasma lipids in obese men.
Metabolism
43:
1318-1323,
1994[ISI][Medline].
32.
Ross, R,
Dagnone D,
Jones P,
Smith H,
Paddags A,
Hudson R,
and
Janssen I.
Reduction in obesity and related comormid conditions after diet-induced weight loss or exerciseinduced weight loss in men.
Ann Intern Med
122:
92-103,
2000.
33.
Ross, R,
Fortier L,
and
Hudson R.
Separate associations between visceral and subcutaneous adipose tissue distribution, insulin and glucose levels in obese women.
Diabetes Care
19:
1404-1411,
1996[Abstract].
34.
Ross, R,
Léger L,
Morris DV,
de Guise J,
and
Guardo R.
Quantification of adipose tissue by MRI: relationship with anthropometric variables.
J Appl Physiol
72:
787-795,
1992
35.
Ross, R,
Rissanen J,
Pedwell H,
Clifford J,
and
Shragge P.
Influence of diet and exercise on skeletal muscle and visceral adipose tissue in men.
J Appl Physiol
1:
2445-2455,
1996.
36.
Ross, R,
Shaw K,
Rissanen J,
Martel Y,
de Guise J,
and
Avruch L.
Sex differences in lean and adipose tissue distribution by magnetic resonance imaging: anthropometric relationships.
Am J Clin Nutr
60:
1277-1284,
1994.
37.
Shulman, GI.
Cellular mechanisms of insulin resistance.
J Clin Invest
106:
171-176,
2000
38.
Smith, SR,
Lovejoy JC,
Greenway F,
Ryan D,
deJonge L,
de la Bretonne J,
Volafova J,
and
Bray GA.
Contributions of total body fat, abdominal subcutaneous adipose tissue compartments, and visceral adipose tissue to the metabolic complications of obesity.
Metabolism
50:
425-435,
2001[ISI][Medline].
39.
Snyder, WS,
Cooke MJ,
Mnassett ES,
Larhansen LT,
Howells GP,
and
Tipton IH.
Report of the Task Group on Reference Man. Oxford, UK: Pergammon, 1975.
40.
Toth, MJ,
Sites CK,
Cefalu WT,
Matthews DE,
and
Poehlman ET.
Determinants of insulin-stimulated glucose disposal in middle-aged, premenopausal women.
Am J Physiol Endocrinol Metab
281:
E113-E121,
2001