Introduction
The global epidemic of obesity is a major public health problem, which is driven largely by its co-morbidities including insulin resistance, type 2 diabetes, CVD and cancer. Recent data from the UK show that approximately two-thirds of the population are classified as overweight or obese (defined as having a BMI ≥ 25·0 kg/m2)(1) and that over the last decade, the proportion of individuals classified as normal weight (BMI 18·5–24·9 kg/m2)(1) is slowly declining(Reference Craig and Mindell2). Consequently, being overweight has become the ‘norm’ in today's society(Reference Wardle and Boniface3) and it has been estimated, based on current rates, that by 2050, 60 % of males and 50 % of females in the UK will be obese (BMI ≥ 30·0 kg/m2)(Reference McPherson, Marsh and Brown4).
In 1993, Hotamisligil et al. (Reference Hotamisligil, Shargill and Spiegelman5) discovered that cells of the adipose tissue (adipocytes) in rodents secreted TNF-α, a pro-inflammatory cytokine and, although unknown to them, this discovery was to shape the future of obesity research worldwide(Reference Trayhurn6, Reference Hauner7). Following the discovery of cytokine-like leptin in 1994 by Zhang et al. (Reference Zhang, Proenca and Maffei8), it became clear that adipose tissue could no longer be regarded as an inert storage organ, but rather it is an active endocrine organ(Reference Zhang, Proenca and Maffei8, Reference Mohamed-Ali, Pinkney and Coppack9). Subsequent research has demonstrated that adipose tissue is involved in many metabolic and physiological pathways including inflammation, insulin sensitivity and vascular haemostasis(Reference Moreno-Aliaga, Campión and Milagro10, Reference Rokling-Andersen, Reseland and Veierod11). Since these initial discoveries, many more inflammatory peptides have been linked to adiposity, for example: the anti-inflammatory peptide hormone, adiponectin(Reference Scherer, Williams and Fogliano12); acute-phase proteins, such as C-reactive protein (CRP) and pro-inflammatory cytokines including IL-6(Reference Yudkin, Stehouwer and Emeis13) and to date, more than fifty adiposity-related inflammatory molecules have been identified(Reference Trayhurn and Wood14, Reference Greenberg and Obin15).
Consequently, obesity is now characterised as a state of chronic or low-grade systemic inflammation(Reference Yudkin, Stehouwer and Emeis13, Reference Das16–Reference Fantuzzi18). More recently, the term ‘metaflammation’ has been used to describe the metabolically triggered inflammation(Reference Hotamisligil19), due to the abnormal circulating levels of inflammatory molecules evident in the obese state (Fig. 1)(Reference Hauner7, Reference Ahima and Flier20–Reference Wellen and Hotamisligil23). Furthermore, several researchers have also demonstrated metabolic differences between the different adipose tissue depots, that is, subcutaneous adipose tissue (SAT) and visceral adipose tissue (VAT), with VAT (or central adiposity) in particular being associated with an increased risk of co-morbidities such as diabetes and CVD(Reference Hartz, Rupley and Rimm24–Reference von Eyben, Mouritsen and Holm29) which may partly be attributed to differences in the secretions of inflammatory molecules from each fat depot(Reference Snijder, van Dam and Visser30, Reference Fain31).
It is widely accepted that the abnormal inflammatory profile observed in obesity is due to adipocyte hypertrophy (increased size), caused by the storage of the excess lipids (Fig. 1)(Reference Greenberg and Obin15, Reference Fain31–Reference Powell33). In addition, some research indicates that an increase in the number of adipocytes (hyperplasia) may also contribute to the abnormal inflammatory profile; however, evidence for this view is less consistent in the literature(Reference de Ferranti and Mozaffarian34, Reference Spalding, Arner and Westermark35). Researchers have recently been criticised for taking an ‘over-simplistic’ view of adipose tissue(Reference Frayn36) in failing to take account of other cells residing in the tissue, such as macrophages, pre-adipocytes and mast cells, and their potential contribution to the inflammatory profile observed in obesity(Reference Weisberg, McCann and Desai37–Reference Fain, Madan and Hiler39). Indeed, by definition, an adipokine is a protein secreted by the adipocytes(Reference Trayhurn and Wood14); however, adipocytes are not the source of all inflammatory molecules in the obese state. For example, CRP is released from the liver(Reference Bassuk, Rifai and Ridker40) and therefore is not, by definition, an adipokine. However, it is beyond the scope of the present review to discuss the molecular mechanisms and the various cellular sources of each inflammatory molecule involved in the development of obesity-related inflammation. Therefore, all inflammatory molecules associated with obesity will be referred to hereafter as obesity-related inflammatory markers (ORIM).
Along with the discovery of the secretion of TNF-α from adipose tissue, Hotamisligil et al. (Reference Hotamisligil, Shargill and Spiegelman5) also demonstrated a link between adiposity, TNF-α and insulin resistance, and inflammation is now well understood as a link between obesity and its clustering of metabolic abnormalities and co-morbidities(Reference Hotamisligil, Shargill and Spiegelman5, Reference Lyon, Law and Hsueh41–Reference Ronti, Lupattelli and Mannarino43). Given the evidence that elevated levels of ORIM could be causal in the development of its associated co-morbidities, many researchers have hypothesised that the reduction in disease risk seen in response to weight loss could be as a result of an improved inflam-matory profile, that is, a decrease in the pro-inflammatory molecules, such as CRP, and an increase in the anti-inflammatory molecule, adiponectin (Fig. 1). To our knowledge, reviews in this area have solely focused on CRP as an independent risk factor for CVD(Reference Dietrich and Jialal44–Reference Selvin, Paynter and Erlinger46). Therefore, the aim of the present review is to examine the effects of weight loss on a number of ORIM in overweight and obese, but otherwise healthy, populations.
Weight loss and inflammation
Weight-loss interventions reviewed in the present paper (n 66) were broadly classified into four types according to the method of weight loss employed; diet, physical activity, diet and physical activity combined, and surgical interventions. In order to examine these effects in apparently healthy populations (with the exception of gastric surgery interventions), studies including insulin-resistant or diabetic subjects, those with any cardiovascular risk factor or patients suffering from any other chronic disease were excluded. All studies included at least one study group aiming for weight loss and measured at least one ORIM. In those studies where different methods of weight loss were compared, for example, diet v. diet and physical activity combined; each study group is discussed below according to the method used.
Dietary interventions
Studies using dietary modification alone (Table 1; n 23)(Reference Rokling-Andersen, Reseland and Veierod11, Reference You, Berman and Ryan47–Reference Pereira, Swain and Goldfine68) based interventions on energy-restricted diets (n 5), low-, or very-low-calorie diets (LCD or VLCD, respectively) (n 8), or low-fat diets (n 4). Some also compared the effects of diets with different macronutrient compositions (n 6), for example, low-fat v. low-carbohydrate, although in the majority, an energy deficit was the ultimate cause of weight loss. The duration of the interventions ranged from 2 d to 14 months and the number of participants ranged from seven to eighty-three. Based on mean baseline BMI values reported for each study group, 15 % were carried out in overweight subjects (25·0–29·9 kg/m2), 67 % in obese (30·0–39·9 kg/m2) and 9 % in morbidly obese subjects ( ≥ 40·0 kg/m2). Two studies did not report baseline BMI.
% M, percentage of male subjects; WC, waist circumference; % BF, percentage body fat; CRP, C-reactive protein; ERD, energy-restricted diet; F, female; ~, not measured or not reported; DXA, dual-energy X-ray absorptiometry; CT, computed tomography; M, male; ↓ , decrease; BIA, bioelectrical impedance analysis; LCD, low-calorie diet; % E, percent energy; LF, low-fat; HF, high-fat; ↑ , increase; NIR, near-IR spectrophotometry; ER, energy restriction; MF, medium-fat; HP, high-protein; GL, glycaemic load.
* Studies containing more than one study group.
† Highly sensitive method reported.
‡ Median values or values calculated from median values.
§ Percentage fat mass loss.
Overall, studies using LCD as the method of intervention resulted in the highest mean weight loss, compared with those using other methods, such as low-fat diets (10 v. 5 %, respectively). The greatest improvements in the serum or plasma concentrations of ORIM were observed in these studies where a weight loss of at least 10 % was reported(Reference Bougoulia, Triantos and Koliakos51, Reference Considine, Sinha and Heiman54–Reference Tchernof, Nolan and Sites56, Reference Raitakari, Ilvonen and Ahotupa59, Reference Pereira, Swain and Goldfine68). For example, Kasim-Karakas et al. failed to show any significant changes in serum CRP, IL-6 or adiponectin with an 8 % (6 kg) weight loss after a 12-month low-fat diet(Reference Kasim-Karakas, Tsodikov and Singh62), whereas in the two LCD studies which reported a weight loss of approximately 15 % (15 and 19 kg, respectively), a 32 % decrease in plasma CRP after 14 months(Reference Tchernof, Nolan and Sites56) and a 24 % decrease in plasma IL-6 after only 6 months(Reference Bruun, Verdich and Toubro55) was observed. No LCD study measured adiponectin concentration after weight loss; however, a shorter-term (6 weeks) VLCD reporting an 11 % (11 kg) weight loss was associated with a 19 % increase in serum adiponectin(Reference Raitakari, Ilvonen and Ahotupa59). Furthermore, the benefits of losing more than 10 % weight, rather than more modest weight loss, are evident when similar dietary methods of weight loss are employed. For example, You et al. demonstrated that a 5 % (5 kg) weight loss was unable to induce significant improvements in any ORIM measured(Reference You, Berman and Ryan47). On the other hand, Bougoulia et al. demonstrated a 22, 21, 86 and 32 % decrease in plasma CRP, TNF-α, IL-6 and leptin, respectively, and a 72 % increase in plasma adiponectin concentrations with a 19 % (20 kg) weight loss(Reference Bougoulia, Triantos and Koliakos51). It should be noted that these studies were carried out in females with differing menopausal status; however, the overall benefits of a weight loss greater than 10 % can clearly be seen.
Nine studies included in the present review compared the effect of two or more different weight-loss diets on inflammation(Reference Hannum, Carson and Evans53, Reference Clément, Viguerie and Poitou57, Reference Heald, Golding and Sharma60, Reference O'Brien, Brehm and Seeley63–Reference Pereira, Swain and Goldfine68), with the majority (n 8) lasting between 2 and 3 months. Hannum et al. failed to show a significant decrease in serum CRP with modest weight loss (4–7 % or 4–6 kg) in either a self-selected or portion-controlled LCD which were both low-fat (20 % of total energy)(Reference Hannum, Carson and Evans53). A further study by Heald et al. carried out in females of a similar age reported that when high-fat foods were replaced with reduced-fat alternatives, this resulted in a small, but significant, weight loss (2 % or 1 kg) and a significant decrease in serum CRP (24 %)(Reference Heald, Golding and Sharma60). Similar improvements in plasma and serum CRP concentrations were also reported in studies comparing diets of different macronutrient composition(Reference O'Brien, Brehm and Seeley63, Reference Wood, Volek and Davis64, Reference Noakes, Keogh and Foster67). However, no differences were reported between the diets, in terms of their effects on weight loss or inflammation. In an additional two studies that compared the effects of low-fat and moderate-fat diets, both designed for weight loss, significant reductions in plasma(Reference Viguerie, Vidal and Arner65) and serum(Reference Arvidsson, Viguerie and Andersson66) leptin concentrations were observed in all intervention groups, but with no significant difference between diets observed. In contrast in another study, a low-glycaemic-load diet was associated with a significantly greater improvement in serum CRP concentration compared with that of a low-fat diet group (48 v. 5 %) despite the same percentage weight loss in both groups(Reference Pereira, Swain and Goldfine68). Of note, the latter study was the only dietary comparison study to include both males and females.
Finally, Clément et al. (Reference Clément, Viguerie and Poitou57) examined the effects of a 2 d and 28 d VLCD on plasma leptin concentrations in eight and twenty-one obese females, respectively. The 2 d VLCD was only sufficient to induce an 11 % decrease in plasma leptin concentration, compared with a 53 % decrease observed in the 28 d VLCD group(Reference Clément, Viguerie and Poitou57). However, the decrease in leptin reported for the 2 d VLCD group was most probably attributed to the acute energy restriction rather than the degree of weight loss per se. Furthermore, those in the 2 d VLCD group had a considerably higher BMI, fat mass (FM) and plasma leptin concentration at baseline than those in the 28 d VLCD group, making it difficult to draw conclusions from the study.
In two of the above studies, the authors noted that significant improvements in ORIM (CRP and IL-6 in this case) were observed when results for the two study groups were pooled for analysis, implying an insufficient sample size to detect changes in these ORIM following weight loss in each study group(Reference Hannum, Carson and Evans53, Reference Arvidsson, Viguerie and Andersson66). This limitation was also noted by Pereira et al., albeit their results were significant(Reference Pereira, Swain and Goldfine68), and it was also evident in the study by Keogh et al. (Reference Keogh, Brinkworth and Clifton48). Their study initially aimed to investigate the effect of weight loss on two ORIM (CRP and adiponectin) in a low-carbohydrate (n 13) and high-carbohydrate (n 12) group. However, after a substantial drop-out, the small sample size led to results for the two intervention groups to be combined. Overall, a modest weight loss (6 % or 5 kg) resulted in a 17 % increase in circulating adiponectin concentration, with CRP remaining unchanged from baseline. However, this may have been due to the small sample size that remained (n 13), even after combining the two groups(Reference Keogh, Brinkworth and Clifton48).
Physical activity interventions
The duration of physical activity interventions included in the present review ranged from 2 months to 1 year and the number of participants ranged from eight to 199 (Table 2)(Reference Rokling-Andersen, Reseland and Veierod11, Reference Olson, Dengel and Leon69–Reference Okita, Nishijima and Murakami72). The types of physical activity intervention used were generally classified as exercise training, resistance training or aerobic exercise training. Based on mean BMI values, it would appear that the majority of studies (n 4) were carried out in overweight subjects. However, only one of these studies solely included overweight subjects(Reference Olson, Dengel and Leon69), with the other studies including both overweight and obese individuals(Reference Rokling-Andersen, Reseland and Veierod11, Reference Tsukui, Kanda and Nara70–Reference Okita, Nishijima and Murakami72).
% M, percentage of male subjects; WC, waist circumference; % BF, percentage body fat; CRP, C-reactive protein; F, female; RT, resistance training; ~, not measured or not reported; DXA, dual-energy X-ray absorptiometry; M, male; ET, exercise training; NIR, near-IR spectrophotometry; ↑ , increase; BIA, bioelectrical impedance analysis; AE, aerobic exercise; UT, ultrasound tomography.
* All studies included more than one study group.
† Highly sensitive method reported.
Overall, few studies (n 5) used physical activity to induce weight loss, which did not exceed 5 % (3 kg) in any study. This is to be expected, as to achieve a weight loss of approximately 2 lb (1 kg) per week, a deficit of 4·2 MJ (1000 kcal) would require walking or running 65–70 miles (105–113 km) per week with energy intake remaining constant. Therefore, due to the smaller amount of weight loss observed, resulting changes in ORIM are also somewhat inconsistent. For example, TNF-α was shown to significantly decrease by 16 % (after 12 weeks) in one study(Reference Strączkowski, Kowalska and Dzienis-Straczkowska71), decrease by 83 % (after 5 months) in another study(Reference Tsukui, Kanda and Nara70) and significantly increase by 12 % (after 1 year) in a third intervention(Reference Rokling-Andersen, Reseland and Veierod11). Differences in baseline anthropometry, FM or percentage weight loss do not seem to explain the different effects of physical activity on TNF-α evident in these studies. However, differing intensities and/or frequencies of exercise training in each study, or simply the duration of intervention, may partly explain the observed findings.
Another important consideration when using physical activity interventions as a method of weight loss is the role of fat-free mass (FFM). It is well documented that physical activity increases, or at least maintains, levels of FFM(Reference Ballor and Poehlman73), which is a likely explanation for the relatively smaller levels of total weight loss noted in these studies in comparison with the dietary interventions. Indeed, in those studies reporting FFM pre- and post-intervention (n 3), it was seen to significantly increase by 5 % after resistance training(Reference Olson, Dengel and Leon69) or remain unchanged (i.e. was conserved) after general exercise training(Reference Tsukui, Kanda and Nara70, Reference Strączkowski, Kowalska and Dzienis-Straczkowska71) in females. This finding agrees with a recent study by Hunter et al. who showed that females involved in resistance training maintained levels of FFM more than those involved in aerobic exercise or no exercise training at all(Reference Hunter, Byrne and Sirikul74).
Diet and physical activity interventions
Interventions combining both diet and physical activity modifications (n 18) ranged in duration from 6 weeks to 2 years and the number of participants ranged from nineteen to 190 (Table 3)(Reference Rokling-Andersen, Reseland and Veierod11, Reference You, Berman and Ryan47, Reference Brekke, Lenner and Taskinen61, Reference Itoh, Imai and Masuda75–Reference Obisesan, Leeuwenburgh and Phillips89). The majority of these interventions were carried out in obese subjects (50 %), with 22 % of studies in overweight and 11 % in morbidly obese subjects. The mean baseline BMI value was not reported in three studies.
% M, percentage of male subjects; WC, waist circumference; % BF, percentage body fat; CRP, C-reactive protein; ERD, energy-restricted diet; F, female; ↓ , decrease; ~, not measured or not reported; BIA, bioelectrical impedance analysis; ↑ , increase; DXA, dual-energy X-ray absorptiometry; CT, computed tomography; AE, aerobic exercise; M, male; E %, percent energy; LCD, low-calorie diet; MD, multidisciplinary; LF, low-fat; ET, exercise training.
* Studies including more than one study group.
† Highly sensitive method reported.
‡ Values calculated from median values.
§ In addition to the diet and PA intervention, liposuction was performed in fifteen(Reference Ziccardi, Nappo and Giugliano85) and twenty(Reference Nicoletti, Giugliano and Pontillo86) subjects, respectively, at least 3 months before plasma assays.
All but one of these studies (n 17) reported significant weight loss post-intervention(Reference Rokling-Andersen, Reseland and Veierod11, Reference You, Berman and Ryan47, Reference Brekke, Lenner and Taskinen61, Reference Sheu, Chang and Lee76–Reference Obisesan, Leeuwenburgh and Phillips89) and although not reported as absolute weight loss (kg), the remaining study did report significant decreases in BMI and FM post-intervention(Reference Itoh, Imai and Masuda75). Similar to those interventions using dietary modification alone, a weight loss of at least 10 % resulted in the greatest improvements in ORIM concentrations(Reference Church, Willis and Priest80–Reference St-Onge, Desmond and Hunter83, Reference Ziccardi, Nappo and Giugliano85–Reference Dandona, Weinstock and Thusu88). Studies reporting less than 10 % weight loss show inconsistent effects on the concentrations of ORIM(Reference Rokling-Andersen, Reseland and Veierod11, Reference You, Berman and Ryan47, Reference Brekke, Lenner and Taskinen61, Reference Sheu, Chang and Lee76–Reference Salas-Salvadó, Bullo and Garcia-Lorda79, Reference Zahorska-Markiewicz, Janowska and Olszanecka-Glinianowicz84, Reference Obisesan, Leeuwenburgh and Phillips89). For example, after 6 months, Ryan & Nicklas observed significant improvements in plasma CRP and IL-6 concentrations (7 and 16 % decrease, respectively), with no significant change in plasma TNF-α in thirty-seven postmenopausal females(Reference Ryan and Nicklas77), whereas You et al. (Reference You, Berman and Ryan47) found that plasma CRP, IL-6 and TNF-α concentrations decreased by 34, 27 and 6 %, respectively, in seventeen postmenopausal females with a similar degree of weight loss (7–9 % or 6–7 kg)(Reference You, Berman and Ryan47). Subjects in the latter study(Reference You, Berman and Ryan47) lost slightly more FM compared with those in the study of Ryan & Nicklas(Reference Ryan and Nicklas77), which may partly explain the discrepant ORIM results.
Only four out of the eighteen diet and physical activity studies investigated the effects of weight loss on circulating leptin concentrations(Reference Rokling-Andersen, Reseland and Veierod11, Reference Brekke, Lenner and Taskinen61, Reference Itoh, Imai and Masuda75, Reference Sheu, Chang and Lee76). Unfortunately, weight loss (kg) was not quantified in all studies, so meaningful comparisons cannot be drawn. However, an improvement in circulating leptin concentration was associated with a significant decrease in body fat, expressed as percentage change or absolute change(Reference Rokling-Andersen, Reseland and Veierod11, Reference Itoh, Imai and Masuda75, Reference Sheu, Chang and Lee76) and where the intervention failed to decrease FM despite a significant weight loss, circulating leptin concentration remained unchanged from that at baseline(Reference Brekke, Lenner and Taskinen61).
Three of the diet and physical activity intervention studies that resulted in the greatest weight loss were also the longest in duration (1–2 years) and observed significant improvements in all ORIM measured(Reference Esposito, Pontillo and Di Palo82, Reference Marfella, Esposito and Siniscalchi87, Reference Dandona, Weinstock and Thusu88). The decrease in serum TNF-α concentrations ranged from 24 %(Reference Dandona, Weinstock and Thusu88) to 31 %(Reference Marfella, Esposito and Siniscalchi87), and the decrease in serum CRP and IL-6 concentrations ranged from 34–44 % and 33–62 %, respectively(Reference Esposito, Pontillo and Di Palo82, Reference Marfella, Esposito and Siniscalchi87). Moreover, serum adiponectin concentration was also shown to increase by 48 %(Reference Esposito, Pontillo and Di Palo82). These three studies were carried out in females; however, similar improvements in serum CRP and IL-6 (42 and 31 %, respectively) were also observed in men in a separate intervention(Reference Esposito, Giugliano and Di Palo81). Unfortunately in these four studies, only the simple anthropometric measures, BMI and/or waist:hip ratio were used; therefore, associations between inflammation, weight loss and adiposity cannot truly be identified as FM was not measured directly. One advantage, however, is that these four studies clearly demonstrate the benefit of long-term diet and lifestyle interventions in terms of the assessment of changes in inflammation following weight loss.
Surgical interventions
Subjects who underwent surgery for weight loss (Table 4)(Reference Giugliano, Nicoletti and Grella90–Reference Botella-Carretero, Alvarez-Blasco and Martinez-Garcia114) were either obese (20 %) or morbidly obese (80 %). The duration of follow-up was longer than in other weight-loss interventions, ranging from 3 months to 3 years, and the number of participants in each study (n 25) ranged from seven to 106. Methods of surgical intervention were broadly classified into three types; fat removal surgery, gastric restrictive surgery or gastric bypass surgery, with some studies using either restrictive or bypass. In the majority of studies including morbidly obese patients (n 16), post-operative mean BMI was significantly reduced to below 40 kg/m2 and in the two studies with the greatest overall weight loss(Reference Hulver, Zheng and Tanner108, Reference Calvani, Scarfone and Granato109), post-operative BMI dramatically fell to below 30 kg/m2.
% M, percentage of male subjects; WC, waist circumference; CRP, C-reactive protein; FRS, fat removal surgery; F, female; LVL, large-volume liposuction; ~, not measured or not reported; LVTL, large-volume tumescent liposuction; DXA, dual-energy X-ray absorptiometry; UAM, ultrasound-assisted megalipoplasty; ↓ , decrease; GRS, gastric restrictive surgery; VBG, vertical banded gastroplasty; M, male; AGB, adjustable gastric binding; GPS, gastric partition surgery; SAGB, Swedish adjustable gastric banding; BIA, bioelectrical impedance analysis; VRG, vertical ring gastroplasty; GBS, gastric bypass surgery; RYGBP, roux-en-Y gastric bypass; BPD, bilious-pancreatic diversion; ID, isotope dilution; LMGBP, laparoscopic minigastric bypass; GBP, gastric bypass; TBW, total body water.
* Studies including more than one study group.
† Highly sensitive method reported.
‡ Values calculated from median values.
A greater range in weight loss (3–50 % or 3–84 kg) was observed in the surgical interventions, with the gastric bypass surgery leading to a greater mean weight loss (33 %) than the fat removal, or restrictive surgery (7 and 27 %, respectively). Results for most ORIM are more consistent compared with those observed in the dietary interventions, with or without physical activity. Significant reductions in circulating CRP concentrations were reported in fifteen out of nineteen studies and ranged from 17 to 79 %. The decrease in leptin (n 15) ranged from 15 to 76 % and the increase in adiponectin (n 10) ranged from 13 to 209 %. Overall, improvements in circulating IL-6 and TNF-α concentrations are somewhat less consistent than those observed for the other ORIM. IL-6 concentration was not significantly decreased in five out of twelve studies reporting its concentration post-operatively and in those that do report significant decreases, the effects are smaller (9 to 59 %) compared with those seen for other ORIM. Serum TNF-α was only significantly decreased in one out of seven studies, despite this being the study reporting the smallest degree of weight loss(Reference Giugliano, Nicoletti and Grella90).
A study by Busetto et al. (Reference Busetto, Bassetto and Zocchi92) observed no significant effects on CRP or IL-6, a small but significant decrease in leptin (23 %) and a significant decrease in adiponectin concentration (11 %) at 6 months, effects associated with a modest weight loss of 9 % (9 kg) post-surgery. This was the only study reviewed which used large-volume ultrasound-assisted megalipoplasty as the method of surgery (which mainly removes subcutaneous fat) and the only one to assess the immediate post-operative effects, following subjects at 1, 3, 28 and 180 d post-surgery. Subjects also had a lower BMI at baseline (37·5 kg/m2) relative to those in the other studies. Although body weight was significantly reduced at each time-point, FM only decreased after 3 d and remained at this level up to day 180. An immediate inflammatory response was observed 1 d post-surgery, characterised by a dramatic increase in leptin, CRP and IL-6, and a decrease in adiponectin concentrations. However, the authors concluded that as patients recovered from surgery, levels of the ORIM returned to baseline values within 6 months, with only the concentration of leptin and adiponectin remaining significantly reduced post-surgery(Reference Busetto, Bassetto and Zocchi92). The importance of adequate duration of follow-up of surgical interventions to allow for recovery and stabilisation of inflammation will be explored in more detail later in the present review.
As mentioned above, surgical interventions that included insulin-resistant or diabetic subjects, or those with cardiovascular risk factors, were not excluded from the present review. The majority of patients presenting for gastric surgery are morbidly obese and, consequently, it is common that additional risk factors or co-morbidities of obesity are present. In all of the surgical intervention studies reviewed, measures of disease risk were studied in parallel with ORIM. Overall, weight loss was coupled with improvements in metabolic risk factors(Reference Krzyzanowska, Mittermayer and Kopp93, Reference Hanusch-Enserer, Cauza and Spak98, Reference van Dielen, Buurman and Hadfoune110), insulin resistance and/or insulin sensitivity(Reference Giugliano, Nicoletti and Grella90, Reference Busetto, Bassetto and Zocchi92, Reference Yang, Lee and Funahashi95, Reference Laimer, Kaser and Kranebitter96, Reference Hanusch-Enserer, Cauza and Spak98, Reference Kopp, Krzyzanowska and Mohlig99, Reference Cancello, Henegar and Viguerie103, Reference Vendrell, Broch and Vilarrasa105–Reference Calvani, Scarfone and Granato109, Reference Poitou, Coussieu and Rouault111, Reference Vázquez, Pazos and Berrazueta112, Reference Botella-Carretero, Alvarez-Blasco and Martinez-Garcia114) and a decrease in cardiovascular risk(Reference Giugliano, Nicoletti and Grella90, Reference Yang, Lee and Funahashi95–Reference Laimer, Ebenbichler and Kaser97, Reference Kopp, Krzyzanowska and Mohlig99–Reference Kopp, Kopp and Steiner102, Reference Manco, Fernandez-Real and Equitani104, Reference Faraj, Havel and Phelis106, Reference Liou, Lin and Lee107, Reference Calvani, Scarfone and Granato109, Reference Vázquez, Pazos and Berrazueta112–Reference Botella-Carretero, Alvarez-Blasco and Martinez-Garcia114). Moreover, improvements in glucose tolerance were reported as a reversal of type 2 diabetes, with subjects reverting back to impaired glucose tolerance or, in some cases, achieving a normal glucose tolerance level again(Reference Krzyzanowska, Mittermayer and Kopp93, Reference Kopp, Hopp and Festa101, Reference Kopp, Kopp and Steiner102, Reference Calvani, Scarfone and Granato109). However, three studies found no significant improvements in metabolic risk factors(Reference Klein, Fontana and Young91) or insulin resistance(Reference Klein, Fontana and Young91, Reference Haider, Schindler and Schaller94, Reference Gannagé-Yared, Yaghi and Habre113). Correlating changes in ORIM with these improvements allowed possible mechanisms to be proposed that may explain the reduction in disease risk associated with weight loss. For example, Faraj et al. found a negative correlation between changes in adiponectin concentration and post-operative homeostasis model assessment for insulin resistance; therefore, the greatest improvements in adiponectin were seen in those with the lowest insulin resistance, that is, the most insulin-sensitive subjects post-operatively(Reference Faraj, Havel and Phelis106).
Weight maintenance
When weight loss is achieved through diet and physical activity modifications, the body experiences an unusual physiological state of negative energy balance. This can in turn disrupt a number of processes within the body, including inflammation. Consequently, the majority of weight-loss interventions discussed are limited in their design since very few (n 8) included a weight-maintenance phase before post-intervention sampling to allow for stabilisation of the body's inflammatory profile. However, half of these studies did not distinguish between the active weight-loss and maintenance phases of their interventions, only reporting results for the total study duration(Reference You, Berman and Ryan47, Reference Bruun, Verdich and Toubro55, Reference Tchernof, Nolan and Sites56, Reference St-Onge, Desmond and Hunter83). Therefore, it is unclear if differences in inflammatory profiles are evident between these phases. In the remaining studies, concentrations of ORIM immediately post-intervention and after weight maintenance were considered as different time-points(Reference Keogh, Brinkworth and Clifton48, Reference Considine, Sinha and Heiman54, Reference Kasim-Karakas, Tsodikov and Singh62, Reference Salas-Salvadó, Bullo and Garcia-Lorda79). Considine et al. showed an improvement in serum leptin concentrations (53 % decrease) following a 10 % weight loss by LCD, although leptin concentrations showed a slight increase during the 4-week maintenance phase, albeit that it still remained significantly lower compared with that at baseline(Reference Considine, Sinha and Heiman54). In contrast, Keogh et al. found that a 12-week energy-restricted diet was unable to improve CRP concentration and slightly increased adiponectin, although not significantly so. At 1-year follow-up, a small 6 % (5 kg) weight loss was maintained and did give rise to significantly greater adiponectin concentrations; however, the limitations of this study in terms of small sample size have been discussed previously(Reference Keogh, Brinkworth and Clifton48). The effects of dietary manipulation on inflammation are clearly highlighted by Kasim-Karakas et al. (Reference Kasim-Karakas, Tsodikov and Singh62). During the initial phase of their intervention, subjects were placed on an energy-balanced diet that reduced fat content from 35 % to 15 % of energy over 4 months. Weight did not change during this phase, although energy intake was much greater than that at baseline (9·4 v. 6·6 MJ/d). This induced an acute inflammatory response with a significant increase in serum CRP and a significant decrease in serum adiponectin concentration. For the remaining 8 months, the second phase, subjects remained on a 15 % fat ad libitum diet. Compared with that of the energy-balanced diet (9·4 MJ/d), energy intake was reduced to 5·2 MJ/d and a significant weight loss (8 % or 6 kg) was also achieved. Although the serum concentrations of CRP, IL-6 and adiponectin were significantly improved following the acute response, they did not significantly differ from that at baseline(Reference Kasim-Karakas, Tsodikov and Singh62). Finally, Salas-Salvado et al. (Reference Salas-Salvadó, Bullo and Garcia-Lorda79) reported that a 9 % (11 kg) weight loss achieved by a 6-week LCD was associated with a significant improvement in plasma IL-6 and CRP concentrations. However, following a 2-week weight-maintenance period, plasma IL-6 increased slightly but remained significantly lower compared with baseline. Plasma CRP, on the other hand, rose sharply to a higher concentration than that at baseline. In this case, the authors were forced to conclude that the improvements in inflammatory markers were mainly attributable to the energy restriction during the 6-week LCD as these improvements were not sustained during weight maintenance(Reference Salas-Salvadó, Bullo and Garcia-Lorda79). More recently it has been quantified that in order to maintain improvements in ORIM (CRP and adiponectin in this case), following a short-term (8 weeks) VLCD, a minimum weight loss of 10 % must be maintained in the long term (3 years)(Reference Madsen, Rissanen and Bruun115).
The duration of follow-up needed in gastric surgery interventions is likely to be longer in comparison with diet and/or physical activity interventions, to allow for stabilisation of physiological processes and overall recovery post-surgery. Despite this, few studies (n 5) have included different time-points to determine changes in inflammatory profiles post-surgery. Faraj et al. (Reference Faraj, Havel and Phelis106) classified subjects into two groups; weight-stable at 18 months and weight-reducing at 12 months (twenty-five subjects per group), with the latter group achieving more weight loss (37 % or 52 kg v. 36 % or 49 kg) and at a greater rate per month (3 v. 1 %) than those in the former group. Unfortunately, improvements in ORIM were only quantified for the study group as a whole; therefore, differences between the groups in terms of their inflammatory profiles cannot be elucidated(Reference Faraj, Havel and Phelis106). A recent intervention by Busetto et al. is the only study included in the present review that demonstrates the acute pro-inflammatory response immediately post-surgery(Reference Busetto, Bassetto and Zocchi92). At later time-points, responses observed for each ORIM are inconsistent. For example, at 6 months, CRP has been shown to remain unchanged from baseline(Reference Busetto, Bassetto and Zocchi92, Reference Hanusch-Enserer, Cauza and Spak100, Reference van Dielen, Buurman and Hadfoune110) or slightly higher, although not significantly so(Reference Liou, Lin and Lee107). Furthermore, at 12 months, plasma CRP concentration has been reported as slightly increased(Reference Liou, Lin and Lee107), unchanged(Reference Hanusch-Enserer, Cauza and Spak98), or remaining lower at 24 months(Reference van Dielen, Buurman and Hadfoune110). Overall, if generalised to all ORIM, the evidence suggests that at least 2 years is required post-surgery for stabilisation of the inflammatory profile. In all of these surgical interventions, significant weight loss was achieved at each time-point up to 1 year(Reference Busetto, Bassetto and Zocchi92, Reference Hanusch-Enserer, Cauza and Spak98, Reference Liou, Lin and Lee107, Reference van Dielen, Buurman and Hadfoune110) and although van Dielen et al. did not report absolute weight loss in kg, BMI and percentage total excess weight loss were significantly lower at each time-point up to 2 years(Reference van Dielen, Buurman and Hadfoune110). However, more recently, weight regain has been reported up to 5 years post-surgery, suggesting that follow-ups of a longer duration are required, especially when investigating the effects on inflammation(Reference Magro, Geloneze and Delfini116).
Hidden dangers
When investigating associations between adiposity, inflammation and the effects of weight loss, measures of body composition – whether indirect (using BMI) or direct (measuring FM or percentage body fat) – are crucial. However, as mentioned previously, metabolic differences have been observed between SAT and VAT, with VAT in particular associated with a greater metabolic risk(Reference Hartz, Rupley and Rimm24–Reference von Eyben, Mouritsen and Holm29). Although waist circumference and waist:hip ratio have proved effective as surrogate measures of body fat distribution(Reference Snijder, van Dam and Visser30, Reference Lean, Han and Morrison117–119), advances in techniques, such as MRI or computed tomography scans, have allowed researchers to accurately distinguish the different fat depots.
Seven out of eight studies included in the present review(Reference You, Berman and Ryan47, Reference Tchernof, Nolan and Sites56, Reference Itoh, Imai and Masuda75, Reference Ryan and Nicklas77, Reference Dvořáková-Lorenzová, Suchanek and Havel78, Reference St-Onge, Desmond and Hunter83, Reference Klein, Fontana and Young91) directly measured the VAT and/or SAT areas using MRI or computed tomography scans before and after weight loss (the other study used ultrasound tomography to quantify fat in the abdominal wall(Reference Okita, Nishijima and Murakami72)). Circulating levels of CRP(Reference Tchernof, Nolan and Sites56, Reference Okita, Nishijima and Murakami72, Reference Dvořáková-Lorenzová, Suchanek and Havel78) and leptin(Reference Itoh, Imai and Masuda75) were shown to be positively correlated with intra-abdominal VAT in women, similar to findings (CRP only) previously reported in men(Reference Lemieux, Pascot and Prud'homme120). In most cases, significant reductions in total body weight (range 5–16 %) resulted in significant percentage losses of VAT in females(Reference You, Berman and Ryan47, Reference Tchernof, Nolan and Sites56, Reference Itoh, Imai and Masuda75, Reference Ryan and Nicklas77, Reference Dvořáková-Lorenzová, Suchanek and Havel78, Reference St-Onge, Desmond and Hunter83) which were greater than that of SAT, when reported. In the majority of studies, this was also associated with significant improvements in ORIM (Tables 1–4). In addition, changes in VAT and plasma IL-6 following significant weight loss were shown to be independent predictors of changes in insulin sensitivity(Reference Ryan and Nicklas77). Unfortunately, no studies reviewed in the present paper quantified VAT and SAT areas in males. Salas-Salvadó et al. (Reference Salas-Salvadó, Bullo and Garcia-Lorda79) failed to show a positive association between SAT ORIM production (determined from biopsies) and systemic inflammation after weight loss. The authors speculated that the VAT depot may have, in part, attributed to the improved inflammatory profile observed although not accounted for in this study(Reference Salas-Salvadó, Bullo and Garcia-Lorda79). In support of this, Klein et al. showed that abdominal liposuction, which mainly removed SAT, was unable to produce improvements in the ORIM measured(Reference Klein, Fontana and Young91). A recent systematic review of sixty-one studies, including more than 2000 measured changes in VAT and SAT, found a favourable reduction in VAT (rather than SAT) with modest weight loss. Furthermore, this effect was lessened as weight loss increased and it was concluded that this finding may shed some light on the mechanisms underlying the beneficial effects associated with modest weight loss(Reference Chaston and Dixon121). Although VAT initially contributes to an improved inflammatory profile following modest weight loss, the general pattern highlighted throughout this review may suggest that SAT (and total adipose tissue loss) also has a role in modulating changes in inflammation with further weight loss.
Discussion
In the present review we have described the effects of weight loss on a number of ORIM in overweight and obese, but otherwise healthy, populations. A total of sixty-six intervention studies were included, grouped by the strategy used to induce weight loss, with each study measuring one or more ORIM.
Effects of weight loss
The overall conclusion from the present and previous reviews(Reference Dietrich and Jialal44–Reference Selvin, Paynter and Erlinger46) is that weight loss does improve inflammation in terms of a number of ORIM, specifically characterised by a decrease in the inflammatory markers (CRP, TNF-α, IL-6 and leptin) and an increase in the anti-inflammatory marker, adiponectin. Moreover, the greatest and more consistent improvements are noted in those studies achieving at least a 10 % weight loss. A systematic review by Selvin et al. quantified that a 1 kg weight loss will produce a − 0·13 mg/l change in CRP through diet and lifestyle modifications, which is increased to a − 0·16 mg/l change per 1 kg loss of body weight induced by gastric surgery(Reference Selvin, Paynter and Erlinger46). It remains to be elucidated whether similar changes per 1 kg weight loss would be observed for the other ORIM.
Overall, LCD (with or without lifestyle modifications) and gastric bypass surgery appeared to result in the greatest average weight loss and, therefore, the greatest improvements in ORIM compared with the other dietary or surgical methods, respectively. Where two or more diets of different macronutrient composition were compared, no differences between diets were apparent with the exception of a low-glycaemic-load diet v. a low-fat diet, where the former resulted in a marked decrease in serum CRP concentration compared with the latter. However, it has previously been concluded that more dietary interventions focusing on specific macronutrients and their effects on inflammation are needed to determine any mechanistic differences(Reference Devaraj, Kasim-Karakas and Jialal45, Reference Clifton122).
Physical activity interventions, although fewer in number, did not produce consistent improvements in ORIM; however, this is most probably due to the small, or lack of significant degrees of weight loss observed in these studies. Indeed, in three studies where diet and/or physical activity intervention groups were compared, it was concluded that diet plus physical activity led to the greatest improvements in some(Reference Rokling-Andersen, Reseland and Veierod11, Reference Brekke, Lenner and Taskinen61) if not all(Reference You, Berman and Ryan47) ORIM measured compared with the diet and/or physical activity groups individually.
Methodological issues
A number of limitations concerning study design referred to throughout the present review may mask associations between weight loss and inflammation.
Sex
The majority of studies (n 42) have been carried out only in female subjects. In the studies that have included males (usually in a much smaller proportion compared with females), effects of weight loss on inflammation have not been analysed for each sex individually and therefore do not allow for any sex-specific differences to be determined. This finding suggests that women are generally a more obvious target group for weight-loss interventions and given the fact that differences in ORIM do exist between males and females (for example, CRP reportedly higher in females(Reference Albert, Glynn and Ridker123, Reference Thorand, Baumert and Döring124), and that adiposity is associated with inflammation to a greater extent in females(Reference Thorand, Baumert and Döring124)), it seems possible that this target group is potentially more appealing for researchers.
Age
In general, subjects ranged in age between 32 and 61 years (where reported), with some studies including quite a large age range, for example, 20–65 years(Reference Noakes, Keogh and Foster67). It is well known that both adiposity and inflammation increase with age, so combining both young and middle-aged adults represents another potential limitation within the literature. Furthermore, the hormonal status of women should be indicated in studies as it has been shown that postmenopausal women have increased inflammation(Reference Ridker, Hennekens and Rifai125, Reference Pradhan, Manson and Rossouw126). Only one study included in the present review (a physical activity intervention) split their group of females by menopausal status; however, no differences in the amount of weight loss, or effects on ORIM, were observed between the groups(Reference Okita, Nishijima and Murakami72).
Sample size
The number of participants in the majority of studies ranged from seven to seventy-one, and those that included more than one study group contained relatively fewer subjects per group in most cases. Only three studies contained more than 100 subjects(Reference Okita, Nishijima and Murakami72, Reference St-Onge, Desmond and Hunter83, Reference Gannagé-Yared, Yaghi and Habre113). The limitation of small sample size has been noted in a number of studies, some only finding significant improvements in ORIM when results for different intervention groups are pooled for analysis(Reference Keogh, Brinkworth and Clifton48, Reference Hannum, Carson and Evans53, Reference Arvidsson, Viguerie and Andersson66).
Duration
Some of the null or inconsistent findings reported in the present review may, in part, be attributed to the short duration of these studies. The effects of short-term weight loss, i.e. 4–6 weeks (or less), on inflammation are conflicting and prompt the question: are the positive effects observed due to weight loss, or solely because of the energy restriction (Fig. 1)? Few studies (n 8) in the present review include a period of weight maintenance after intervention and, where included, normalisation of ORIM is evident, in some cases levels reverting back to that at baseline or higher, despite a lower weight being maintained. Furthermore, where physical activity was used as a method of weight loss, with or without dietary modification, only ten out of twenty-three studies took into account the stabilisation of the acute inflammatory effects of exercise.
Analysis of obesity-related inflammatory markers
The most common technique used for the analysis of ORIM by studies included in the present review is the ELISA. However, a number of other commercially available assays have also been reported, including chemiluminescent assays(Reference McLaughlin, Abbasi and Lamendola50), nephelometric latex immunoassays(Reference Bougoulia, Triantos and Koliakos51, Reference O'Brien, Brehm and Seeley63, Reference Okita, Nishijima and Murakami72) and RIA(Reference Considine, Sinha and Heiman54, Reference Clément, Viguerie and Poitou57, Reference Arvidsson, Viguerie and Andersson66, Reference Itoh, Imai and Masuda75, Reference Sheu, Chang and Lee76). While techniques for ORIM assessment continue to improve in sensitivity and specificity there is no accepted ‘gold standard’ method for assessment. Furthermore, interpretation of data is hampered by the paucity of data on what is considered a normal concentration of such molecules. In addition, several ORIM, including TNF-α, are likely to act in an autocrine or paracrine manner, mediating their inflammatory effect at a local cellular level and therefore, systemic concentrations of such molecules may not provide an accurate reflection of their inflammatory potential.
Assessment of body composition
The way in which studies report weight changes after intervention lacks consistency. For example, some report weight changes in absolute (kg) terms and others only report the relative losses ( %). Therefore, future studies should report weight loss, both in absolute (kg) and relative ( %) terms, in order to determine if it is the weight loss relative to an individual's starting point ( %) or the extent of the energy deficit (kg) that is important in terms of improving inflammatory status. BMI (i.e. body weight adjusted for height to classify overweight and obesity)(1) and waist circumference (to take account of central obesity and provide an estimate of body fat distribution)(Reference Snijder, van Dam and Visser30, Reference Lean, Han and Morrison117–119) are widely used anthropometric tools in research. However, obesity itself is defined as excess body fat, levels of which cannot be determined using these surrogate measures, as they do not distinguish between FM and FFM. Approximately half of the studies included in the present review used only BMI, waist circumference and/or waist:hip ratio, which impedes clarification of the relationship between adiposity, weight loss and inflammation. Given the fact that obesity-related inflammation is due to increasing adiposity, as excess fat is stored in adipocytes, failure to directly measure FM means that these studies cannot truly identify the associations between inflammation and adiposity, both before, and after, weight loss. In studies where FM was measured, bioelectrical impedance analysis and dual-energy X-ray absorptiometry were the two most common methods used. However, a recent study has demonstrated that these methods may not be reliable in detecting changes in body composition following weight loss(Reference Minderico, Silva and Keller127). These studies also fail to take account of the proportions of FM and FFM in excess weight (i.e. 75 and 25 %, respectively)(Reference Webster, Hesp and Garrow128) and, therefore, the relationship between the FM:FFM ratio and ORIM has also not been investigated. Furthermore, expressing FM as a percentage of total body weight (i.e. percentage body fat) has more recently been criticised within the literature, being described as a ‘fallacy’(Reference Cole, Fewtrell and Prentice129). In order to take account of the individual variations in FM and FFM, alternative indices, first described over 15 years ago(Reference VanItallie, Yang and Heymsfield130), have been proposed where FM (kg) and FFM (kg) are individually adjusted for height (i.e. divided by height in meters squared) to give FM index and FFM index respectively(Reference Schutz, Kyle and Pichard131–Reference Kyle, Genton and Gremion133). The fact that these indices are not considered by any intervention study included in the present review suggests how little they have been applied in research over the last decade. We have recently highlighted the importance of using these indices when examining the association between adiposity and inflammation by demonstrating that FM index is more strongly associated with serum CRP levels in females ( ≤ 30 years) compared with FM in absolute terms, with percentage body fat showing no significant association(Reference Forsythe, Livingstone and Barnes134).
Conclusion
Overall, the present review indicates that during a period of weight loss, the unfavourable inflammatory profile associated with increased adiposity can be improved, thus providing further evidence for the beneficial effects of weight loss in overweight and obesity in terms of reducing the risk of co-morbidities. However, it is likely that the improvements observed are mainly due to a negative energy balance in the short term, rather than decreasing adiposity. More randomised, controlled intervention studies are required to accurately determine the time needed, in which a reduced weight is maintained, in order to benefit from improved inflammatory status long-term. Furthermore, it is recommended that these studies include younger adults, with equal numbers of both men and women, and contain measures of body composition appropriately adjusted for body size.
Acknowledgements
The present review was supported by funding from the Department of Education and Learning (DEL). We would also like to give special thanks to Tracy McCaffrey and Carol Wilson for their comments on the drafts of the manuscript, and to Kilian McDaid for graphic design.
There are no conflicts of interest.