Total dietary lipid intake

Of the total selected studies, fifteen⁽ Reference Arvidsson, Viguerie and Andersson ^{7 –} Reference Wycherley, Brinkworth and Keogh ^{9 ,} Reference Blüher, Rudich and Kloting ^{16 ,} Reference Brons, Jensen and Storgaard ^{18 ,} Reference Varady, Bhutani and Klempel ^{19 ,} Reference Cardillo, Seshadri and Iqbal ^{31 –} Reference Rajaie, Azadbakht and Saneei ^{39 )} investigated the effects of a diet with a low-fat content (20–37 % of energy from lipids) on the circulating concentrations of adiponectin compared with a control diet with a high fat content (35–61 % of energy from lipids), as shown in Table 1. To test how differences in lipid quantity (expressed as the percentage of daily energy) may affect adiponectin concentrations, the diet with the lowest fat content was classified as an intervention diet in each study.

The median follow-up time was 14 weeks (5 d–144 weeks). These studies included seventeen to 322 participants (mean age 50 years). Most (71·4 %) of the studies included both sexes⁽ Reference Keogh, Brinkworth and Noakes ^{8 ,} Reference Blüher, Rudich and Kloting ^{16 ,} Reference Varady, Bhutani and Klempel ^{19 ,} Reference Cardillo, Seshadri and Iqbal ^{31 ,} Reference Keogh, Brinkworth and Clifton ^{33 –} Reference Yeung, Appel and Miller ^{36 ,} Reference Heggen, Klemsdal and Haugen ^{38 ,} Reference Rajaie, Azadbakht and Saneei ^{39 )}. The mean difference in total dietary lipid intake between the intervention and control groups was 12·0 % of the total energy intake. Of these studies, seven⁽ Reference Blüher, Rudich and Kloting ^{16 ,} Reference Cardillo, Seshadri and Iqbal ^{31 ,} Reference Ng, Watts and Barrett ^{32 ,} Reference Vetter, Wade and Womble ^{35 ,} Reference Summer, Brehm and Benoit ^{37 –} Reference Rajaie, Azadbakht and Saneei ^{39 )} did not describe the lipid type and four⁽ Reference Arvidsson, Viguerie and Andersson ^{7 ,} Reference Brons, Jensen and Storgaard ^{18 ,} Reference Yeung, Appel and Miller ^{36 ,} Reference Heggen, Klemsdal and Haugen ^{38 )} had no information about energy consumption. Differences in energy intake were not found to be significant in most of the studies, but were statistically significant only in one study⁽ Reference Ng, Watts and Barrett ^{32 )}. Among all the other studies that did not report a statistical difference in energy intake between the intervention and control groups, two studies were found to have an energy intake difference of 2173 and 1382 kJ (519 and 330 kcal). In the first study, there were no changes and differences in adiponectin concentrations between the groups throughout the study⁽ Reference Al-Sarraj, Saadi and Calle ^{34 )}, while in the other study, there was an increase in adiponectin concentrations within the groups, but not between the groups⁽ Reference Vetter, Wade and Womble ^{35 )}.

The risk of bias in the studies included in the quantitative analysis is summarised in online supplementary Table S1. The risk of selection bias was unclear in the majority of the studies, taking into account the lack of information about random sequence generation and allocation concealment. Performance bias was also unclear in all studies. Information about the blinding of outcome assessors was described in only one study⁽ Reference Rajaie, Azadbakht and Saneei ^{39 )}. Regarding attrition bias, the rates of dropouts and/or withdrawals were less than 20 % in nine studies⁽ Reference Arvidsson, Viguerie and Andersson ^{7 ,} Reference Wycherley, Brinkworth and Keogh ^{9 ,} Reference Blüher, Rudich and Kloting ^{16 ,} Reference Brons, Jensen and Storgaard ^{18 ,} Reference Ng, Watts and Barrett ^{32 –} Reference Al-Sarraj, Saadi and Calle ^{34 ,} Reference Summer, Brehm and Benoit ^{37 ,} Reference Heggen, Klemsdal and Haugen ^{38 )}. Reporting bias was low in all studies. Dietary compliance was assessed in most studies.

Among the fifteen selected studies, twelve⁽ Reference Arvidsson, Viguerie and Andersson ^{7 –} Reference Wycherley, Brinkworth and Keogh ^{9 ,} Reference Blüher, Rudich and Kloting ^{16 ,} Reference Brons, Jensen and Storgaard ^{18 ,} Reference Cardillo, Seshadri and Iqbal ^{31 ,} Reference Ng, Watts and Barrett ^{32 ,} Reference Al-Sarraj, Saadi and Calle ^{34 ,} Reference Vetter, Wade and Womble ^{35 ,} Reference Summer, Brehm and Benoit ^{37 –} Reference Rajaie, Azadbakht and Saneei ^{39 )} reported sufficient data and were thus included in the meta-analysis. The remaining three studies⁽ Reference Varady, Bhutani and Klempel ^{19 ,} Reference Keogh, Brinkworth and Clifton ^{33 ,} Reference Yeung, Appel and Miller ^{36 )} were excluded due to the lack of sufficient data for quantitative analysis.

Among these three studies that were excluded from the quantitative analysis, one⁽ Reference Yeung, Appel and Miller ^{36 )} showed a greater increase in adiponectin concentrations in the control group than in the intervention group, another⁽ Reference Varady, Bhutani and Klempel ^{19 )} showed an increase in the concentrations of adiponectin in the control group than in the intervention group, and in the last one it was not possible to describe the differences between intervention and control groups because the results were not described separately by groups⁽ Reference Keogh, Brinkworth and Clifton ^{33 )}.

Overall, the intervention diet (28–37 % of the total energy intake from fat) did not increase adiponectin concentrations compared with the control diet (39–61 % of the total energy intake from fat) (WMD − 0·04 (95 % CI − 0·82, 0·74) μg/ml; I ² 83·7 %, P for heterogeneity < 0·001; Fig. 2(a)) . Given the significant heterogeneity between the included studies, we performed a meta-regression analysis by including one variable per model: age (adjusted R ² − 9·6 %, P= 0·63); sex (adjusted R ² − 16·5, P= 0·90); study location (adjusted R ² − 9·8 %, P= 0·61); follow-up time (adjusted R ² − 12·7 %, P= 0·87); BMI (adjusted R ² − 10·3 %, P= 0·91); weight-loss difference between the intervention and control groups (adjusted R ² − 11·1 %, P= 0·66); energy intake differences between the intervention and control groups (adjusted R ² − 5·7 %, P= 0·41); percentage point difference in total dietary lipid intake between the intervention and control groups (adjusted R ² − 15·1 %, P= 0·65); carbohydrate content in the control group (adjusted R ² − 16·4 %, P= 0·88). In three studies⁽ Reference Ng, Watts and Barrett ^{32 ,} Reference Al-Sarraj, Saadi and Calle ^{34 ,} Reference Summer, Brehm and Benoit ^{37 )}, a significant change in body weight between the intervention and control groups was observed at the end of each trial. We also performed a sensitivity analysis with body weight used as a variable, which showed no significant change in the results. Publication bias was not observed in the present meta-analysis (Begg's test, P= 0·89; Egger's test, P= 0·21), and asymmetry was also not detected, as shown in the funnel plot (Fig. 3(a)).

Fig. 2 Forest plots (meta-analyses, random-effects models) of the effect of fatty acid interventions on circulating adiponectin concentrations (μg/ml): (a) diet with a low fat content; (b) n-3 PUFA supplementation; (c) conjugated linoleic acid (CLA) supplementation. % EI, percentage of energy intake. For the Troseid et al. ⁽ Reference Troseid, Arnesen and Hjerkinn ^{24 )} study, data for the main effect of fish oil intake on adiponectin concentrations were obtained directly from the authors and used in the pooled meta-analysis. (A colour version of this figure can be found online at http://www.journals.cambridge.org/bjn)

Fig. 3 Funnel plots of changes in circulating adiponectin concentrations in randomised trials with (a) a diet with a low fat content, (b) n-3 PUFA supplementation and (c) conjugated linoleic acid (CLA) supplementation. (A colour version of this figure can be found online at http://www.journals.cambridge.org/bjn)

n-3 PUFA intake

Of the total selected studies, nineteen analysed the effect of n-3 PUFA intake on adiponectin concentrations: sixteen⁽ Reference Sofi, Giangrandi and Cesari ^{21 ,} Reference Vargas, Almario and Buchan ^{22 ,} Reference Troseid, Arnesen and Hjerkinn ^{24 ,} Reference Krebs, Browning and McLean ^{40 –} Reference Damsgaard, Frokiaer and Andersen ^{42 ,} Reference Sneddon, Tsofliou and Fyfe ^{45 –} Reference Simão, Lozovoy and Bahls ^{52 ,} Reference Guebre-Egziabher, Debard and Drai ^{54 ,} Reference Spencer, Finlin and Unal ^{55 )} with n-3 PUFA supplementation and three⁽ Reference Kratz, Swarbrick and Callahan ^{43 ,} Reference Ramel, Martinez and Kiely ^{44 ,} Reference Zhang, Wang and Li ^{53 )} with diets composed of n-3 PUFA-rich foods. The details of these studies are summarised in Table 2. The median follow-up time was 10 weeks (3–24 weeks). These studies included twenty-six to 324 participants, and most studies (54 %) included both sexes.

Dietary composition was described in ten studies⁽ Reference Sofi, Giangrandi and Cesari ^{21 ,} Reference Vargas, Almario and Buchan ^{22 ,} Reference Krebs, Browning and McLean ^{40 ,} Reference Kabir, Skurnik and Naour ^{41 ,} Reference Kratz, Swarbrick and Callahan ^{43 ,} Reference Ramel, Martinez and Kiely ^{44 ,} Reference Mohammadi, Rafraf and Farzadi ^{50 ,} Reference Munro and Garg ^{51 ,} Reference Zhang, Wang and Li ^{53 ,} Reference Guebre-Egziabher, Debard and Drai ^{54 )}. Comparisons between intervention (diet or supplementation) and fatty acid intake from different sources (placebo) were made in twelve studies⁽ Reference Sofi, Giangrandi and Cesari ^{21 ,} Reference Vargas, Almario and Buchan ^{22 ,} Reference Troseid, Arnesen and Hjerkinn ^{24 ,} Reference Krebs, Browning and McLean ^{40 ,} Reference Damsgaard, Frokiaer and Andersen ^{42 ,} Reference Sneddon, Tsofliou and Fyfe ^{45 –} Reference Gammelmark, Madsen and Varming ^{48 ,} Reference Munro and Garg ^{51 ,} Reference Simão, Lozovoy and Bahls ^{52 ,} Reference Spencer, Finlin and Unal ^{55 )}. Among the dietary intervention studies, one⁽ Reference Kratz, Swarbrick and Callahan ^{43 )} used different amounts of n-3 PUFA from plant and marine sources, while two⁽ Reference Ramel, Martinez and Kiely ^{44 ,} Reference Zhang, Wang and Li ^{53 )} used different types of fish.

The risk of selection bias was unclear in the majority of the studies, taking into account the lack of information about random sequence generation and allocation concealment. In general, performance bias was low in most studies. Information about the blinding of outcome assessors was described in only three studies⁽ Reference Troseid, Arnesen and Hjerkinn ^{24 ,} Reference Damsgaard, Frokiaer and Andersen ^{42 ,} Reference Munro and Garg ^{51 )}. Attrition bias was low in ten studies⁽ Reference Sofi, Giangrandi and Cesari ^{21 ,} Reference Troseid, Arnesen and Hjerkinn ^{24 ,} Reference Kabir, Skurnik and Naour ^{41 ,} Reference Damsgaard, Frokiaer and Andersen ^{42 ,} Reference Micallef and Garg ^{46 –} Reference Mohammadi, Rafraf and Farzadi ^{50 ,} Reference Spencer, Finlin and Unal ^{55 )}. Reporting bias was low in all studies. Dietary compliance was analysed in the majority of the studies (online supplementary Table S1).

Of these nineteen studies, thirteen⁽ Reference Sofi, Giangrandi and Cesari ^{21 ,} Reference Vargas, Almario and Buchan ^{22 ,} Reference Troseid, Arnesen and Hjerkinn ^{24 ,} Reference Krebs, Browning and McLean ^{40 –} Reference Damsgaard, Frokiaer and Andersen ^{42 ,} Reference Micallef and Garg ^{46 –} Reference Munro and Garg ^{51 ,} Reference Spencer, Finlin and Unal ^{55 )} presented the data that could be pooled and used in a meta-analysis. Different oils were used as a placebo: four studies⁽ Reference Sofi, Giangrandi and Cesari ^{21 ,} Reference Damsgaard, Frokiaer and Andersen ^{42 ,} Reference Rizza, Tesauro and Cardillo ^{47 ,} Reference Gammelmark, Madsen and Varming ^{48 )} used olive oil; three⁽ Reference Troseid, Arnesen and Hjerkinn ^{24 ,} Reference Micallef and Garg ^{46 ,} Reference Munro and Garg ^{51 )} used sunola oil; one⁽ Reference Vargas, Almario and Buchan ^{22 )} used soyabean oil; one⁽ Reference Spencer, Finlin and Unal ^{55 )} used maize oil; two⁽ Reference Kabir, Skurnik and Naour ^{41 ,} Reference Mohammadi, Rafraf and Farzadi ^{50 )} used paraffin oil; one study⁽ Reference Krebs, Browning and McLean ^{40 )} used a mixture of linoleic and oleic oil; one study⁽ Reference Koh, Quon and Shin ^{49 )} did not describe the oil type. Of these thirteen studies, only five⁽ Reference Sofi, Giangrandi and Cesari ^{21 ,} Reference Krebs, Browning and McLean ^{40 ,} Reference Kabir, Skurnik and Naour ^{41 ,} Reference Mohammadi, Rafraf and Farzadi ^{50 ,} Reference Munro and Garg ^{51 )} reported the dietary composition in both intervention and control groups. None of these studies showed any differences in total energy or in the proportion of macronutrient intake between the two groups. Furthermore, no studies described the consumption of n-3 and n-6 PUFA.

Studies that had analysed the effects of n-3 PUFA-rich foods on adiponectin concentrations⁽ Reference Kratz, Swarbrick and Callahan ^{43 ,} Reference Ramel, Martinez and Kiely ^{44 ,} Reference Zhang, Wang and Li ^{53 )} were not included in the quantitative analysis. In addition, one study⁽ Reference Sneddon, Tsofliou and Fyfe ^{45 )} that combined n-3 PUFA intake with CLA supplementation in the intervention group, as well as two studies⁽ Reference Simão, Lozovoy and Bahls ^{52 ,} Reference Guebre-Egziabher, Debard and Drai ^{54 )} in which data extraction was not available were excluded from the analysis. Among these six excluded studies⁽ Reference Kratz, Swarbrick and Callahan ^{43 –} Reference Sneddon, Tsofliou and Fyfe ^{45 ,} Reference Simão, Lozovoy and Bahls ^{52 –} Reference Guebre-Egziabher, Debard and Drai ^{54 )}, four did not show any significant change in adiponectin concentrations at the end of the intervention⁽ Reference Kratz, Swarbrick and Callahan ^{43 –} Reference Sneddon, Tsofliou and Fyfe ^{45 ,} Reference Guebre-Egziabher, Debard and Drai ^{54 )}. However, in two studies⁽ Reference Simão, Lozovoy and Bahls ^{52 ,} Reference Zhang, Wang and Li ^{53 )}, an increase in adiponectin concentrations was observed at the end of the trial.

The pooled data from thirteen studies did show a modest and significant effect of n-3 PUFA supplementation on adiponectin concentrations (WMD 0·27 (95 % CI 0·07, 0·47) μg/ml; I ² 79·6 %, P for heterogeneity < 0·001; Fig. 2(b)). Given the high heterogeneity between the included studies, we performed a meta-regression analysis by including one variable per model. The independent variables were as follows: age (adjusted R ² − 24·2, P= 0·16); sex (adjusted R ² − 11·2, P= 0·11); study location (adjusted R ² − 28·8 %, P= 0·59); follow-up time (adjusted R ² − 47·0 %, P= 0·58); BMI (adjusted R ² − 39·5 %, P= 0·42); blinding of participants/personnel (adjusted R ² − 103·0 %, P= 0·71); amount of n-3 PUFA (g/d; adjusted R ² − 64·8 %, P= 0·85); EPA (adjusted R ² − 65·9 %, P= 0·83); docosapentaenoic acid (adjusted R ² − 87·0 %, P= 0·60); fat type used as a placebo (vegetable oil v. paraffin oil; adjusted R ² 100 %, P= 0·04); change in body weight over the study period between the intervention and control groups (adjusted R ² − 21·9 %, P= 0·60).

Subsequently, we performed a sensitivity analysis with fat type as placebo (unsaturated oil or paraffin oil), which revealed that n-3 PUFA supplementation was still associated with an increase in adiponectin concentrations. Studies that had used unsaturated oil as placebo showed an effect of n-3 PUFA supplementation on adiponectin concentrations (WMD 0·23 (95 % CI 0·04, 0·42) μg/ml; I ² 40·2 %, P for heterogeneity = 0·09) as well as those that had used paraffin oil as placebo (WMD 1·19 (95 % CI 0·24, 2·13) μg/ml; I ² 39·5 %, P for heterogeneity = 0·20). Studies that had used paraffin oil as placebo showed a greater increase (0·96 μg/ml) in adiponectin concentrations than those that had used vegetable oils as placebo.

Significant evidence of publication bias was found by Egger's test (P= 0·01) but not by Begg's test (P= 0·95). Visual inspection of the funnel plot confirmed the existence of asymmetry (Fig. 3(b)). In fact, a theoretical pooled estimate of 0·08 (95 % CI − 0·13, 0·30) μg/ml (P= 0·46) was obtained by using the trim-and-fill correction method after the addition of six theoretically unreported studies.

Conjugated linoleic acid supplementation

Of the total selected studies, seven⁽ Reference Shademan, Rastmanesh and Hedayati ^{17 ,} Reference Risérus, Vessby and Arner ^{56 –} Reference Joseph, Jacques and Plourde ^{61 )} assessed the effect of CLA (mixture containing cis-9, trans-11 and trans-10, cis-12) supplementation on adiponectin concentrations. The median follow-up time was 13·0 weeks (8–24 weeks). These studies included twenty-eight to eighty participants, aged 18 to 80 years. The details of these studies are summarised in Table 3.

In most studies, CLA supplementation (intervention) was compared with unsaturated fatty acid supplementation (placebo) such as olive oil⁽ Reference Risérus, Vessby and Arner ^{56 ,} Reference Syvertsen, Halse and Hoivik ^{57 ,} Reference MacRedmond, Singhera and Attridge ^{60 )}, safflower oil⁽ Reference Norris, Collene and Asp ^{58 ,} Reference Joseph, Jacques and Plourde ^{61 )}or soyabean oil⁽ Reference Shademan, Rastmanesh and Hedayati ^{17 )}. Only one study⁽ Reference Zhao, Zhai and Wang ^{59 )} compared CLA supplementation with saturated fatty acid intake (placebo, mixture of fatty acids in capsules). The median CLA supplementation was 4·1 (range 3·0–8·0) g/d, with an equal mix of the two predominant isomers. Only two studies⁽ Reference Norris, Collene and Asp ^{58 ,} Reference Zhao, Zhai and Wang ^{59 )} described the dietary composition.

The risk of selection bias was unclear in the majority of the studies, taking into account the lack of information about random sequence generation and allocation concealment. Performance bias was low in most studies. Information about the blinding of outcome assessors was described in only two studies⁽ Reference Norris, Collene and Asp ^{58 ,} Reference Joseph, Jacques and Plourde ^{61 )}. Attrition bias was low in five⁽ Reference Shademan, Rastmanesh and Hedayati ^{17 ,} Reference Risérus, Vessby and Arner ^{56 ,} Reference Syvertsen, Halse and Hoivik ^{57 ,} Reference Zhao, Zhai and Wang ^{59 ,} Reference MacRedmond, Singhera and Attridge ^{60 )} out of seven studies⁽ Reference Shademan, Rastmanesh and Hedayati ^{17 ,} Reference Risérus, Vessby and Arner ^{56 –} Reference Joseph, Jacques and Plourde ^{61 )}. Reporting bias was low in all studies. Dietary compliance was analysed in the majority of the studies (online supplementary Table S1).

All these seven studies⁽ Reference Shademan, Rastmanesh and Hedayati ^{17 ,} Reference Risérus, Vessby and Arner ^{56 –} Reference Joseph, Jacques and Plourde ^{61 )} were pooled in the meta-analysis. The pooled data did not show any significant effect of CLA supplementation on circulating adiponectin concentrations (WMD − 0·18 (95 % CI − 0·84, 0·48) μg/ml; I ² 97·7 %, P for heterogeneity < 0·001; Fig. 2(c)). A high level of heterogeneity was detected. The visual inspection of the funnel plot revealed the existence of asymmetry (Fig. 3(c)), suggesting a publication bias, although neither Begg's test (P= 0·76) nor Egger's test (P= 0·48) showed any evidence of the same. In fact, a theoretical pooled estimate of − 0·64 (95 % CI − 1·83 to 0·55) μg/ml (P= 0·29) was obtained by using the trim-and-fill correction method after the addition of one theoretically unreported study.

Given the significant heterogeneity between the included studies, we performed a meta-regression analysis by including one variable per model: age (adjusted R ² − 21·1, P= 0·75); sex (adjusted R ² − 5·6, P= 0·44); study location (adjusted R ² 41·9 %, P= 0·07); follow-up time (R ² 29·5 %, P= 0·13); BMI (adjusted R ² 11·6 %, P= 0·23); change in body weight over the study period between the intervention and control groups (adjusted R ² − 9·0 %, P= 0·53); amount of CLA supplementation ( < 4·8 v.>4·8 g/d; adjusted R ² 11·6 %, P= 0·23); fat type used as a placebo (unsaturated v. saturated fat; adjusted R ² 56·0 %, P= 0·02).

Subsequently, a sensitivity analysis was performed with fat type used as a placebo (unsaturated or saturated fat). The analysis revealed a reduction in adiponectin concentrations with CLA supplementation after the removal of one study that had used saturated fat as placebo (WMD − 0·74 (95 % CI − 1·38, − 0·10) μg/ml; I ² 97·3 %, P for heterogeneity < 0·001). However, the analysis showed a high level of heterogeneity among the studies that used unsaturated fat as placebo.

Other dietary lipid interventions

Among the total selected studies, three analysed the effect of fatty acid intake on adiponectin concentrations (saturated fat⁽ Reference Lithander, Keogh and Wang ^{63 )}, α-lipoic acid⁽ Reference Manning, Sutherland and Williams ^{69 )} and n-6 PUFA⁽ Reference Bjermo, Iggman and Kullberg ^{68 )}) and nine analysed the effect of the food source of lipids on adiponectin concentrations (eggs⁽ Reference Ratliff, Mutungi and Puglisi ^{64 )}, partially-hydrogenated oil⁽ Reference Bendsen, Stender and Szecsi ^{20 ,} Reference Vega-Lopez, Matthan and Ausman ^{65 )}, nuts⁽ Reference Kalgaonkar, Almario and Gurusinghe ^{66 ,} Reference Aronis, Vamvini and Chamberland ^{67 ,} Reference Somerset, Graham and Markwell ^{71 )} and flaxseed⁽ Reference Taylor, Noto and Stringer ^{23 ,} Reference Nelson, Stevens and Hickey ^{62 ,} Reference Kontogianni, Vlassopoulos and Gatzieva ^{70 )}). The details of these studies are summarised in online supplementary Table S2. The median follow-up time was 9 weeks (4 d–48 weeks). These studies included fifteen to 160 participants, aged 20 to 80 years. However, these studies were not included in the meta-analysis due to the variability in dietary intervention.

A high consumption of saturated fat⁽ Reference Lithander, Keogh and Wang ^{63 )}, n-6 PUFA⁽ Reference Bjermo, Iggman and Kullberg ^{68 )} and α-lipoic acid⁽ Reference Manning, Sutherland and Williams ^{69 )}did not show a significant effect on adiponectin concentrations. In contrast, intake of eggs increased the circulating concentrations of adiponectin⁽ Reference Ratliff, Mutungi and Puglisi ^{64 )}. Flaxseed intake reduced adiponectin concentrations in one study⁽ Reference Nelson, Stevens and Hickey ^{62 )}, but did not change its concentrations in other two studies⁽ Reference Taylor, Noto and Stringer ^{23 ,} Reference Kontogianni, Vlassopoulos and Gatzieva ^{70 )}. Intake of nuts increased adiponectin concentrations in two studies⁽ Reference Kalgaonkar, Almario and Gurusinghe ^{66 ,} Reference Aronis, Vamvini and Chamberland ^{67 )}, with no effect being found in one study⁽ Reference Somerset, Graham and Markwell ^{71 )}.