Ulcerative colitis (UC) is a chronic condition characterised by inflammation and ulcerations along the colonic mucosa. The disease predominantly affects the large bowel and develops from the rectum to other parts of the colon in a progressive fashion. Symptoms occur intermittently, cycling between active disease and periods of remission. These range from gastrointestinal issues, such as loose stools, urgency, frequency and bleeding, to systemic issues such as fatigue, joint pain, malnutrition and the development of colon cancer. As such, those living with this condition often report a significant impact on quality of life, although overall lifespan is not reduced(Reference Winther, Jess and Langholz1). Along with other inflammatory bowel diseases (IBD), the prevalence of UC is increasing globally(Reference Bernstein2). The reason for this trend is not well understood; however, a combination of environmental(Reference Abegunde, Muhammad and Bhatti3), lifestyle(Reference Chapman-Kiddell, Davies and Gillen4) and genetic risk factors(Reference Abegunde, Muhammad and Bhatti3,Reference Aleksandrova, Romero-Mosquera and Hernandez5) has been proposed.
Diet has been a key lifestyle focus for both clinicians and patients. Its role in modifying disease risk factors, disease severity and symptoms has previously been reported in prospective studies and small trials(Reference Aleksandrova, Romero-Mosquera and Hernandez5,Reference Haskey and Gibson6) . In contrast to medical therapy, dietary approaches are often viewed as an attractive option due to the side effects of conventional treatment such as immunosuppressive therapy and monoclonal antibodies(Reference Carter, Lobo and Travis7). As such, patients often report a range of self-prescribed dietary behaviours and restrictions with potentially negative implications for health outcomes and quality of life(Reference Casanova, Chaparro and Molina8). Unfortunately, the efficacy of such practices remains unclear due to the lack of robust evidence(Reference Alastair, Emma and Emma9).
Amongst the various dietary strategies proposed, the Mediterranean diet is one approach that has gained interest in recent years. Early findings suggest that dietary patterns which emulate the Mediterranean diet were associated with reduced faecal calprotectin(Reference Godny, Reshef and Pfeffer-Gik10,Reference Strisciuglio, Cenni and Serra11) , reduced inflammatory markers and improvements to anthropometric measures and quality of life measures(Reference Chicco, Magrì and Cingolani12). Definitions of the diet tend to vary and may extend to include social aspects of food consumption and lifestyle; thus, it can be challenging to identify how specific elements of the diet impact health outcomes.
Amongst the various elements of the diet, extra virgin olive oil consumption is one aspect of the diet which is often credited with positive health outcomes(Reference Santangelo, Varì and Scazzocchio13). Epidemiological studies have shown associations between higher olive oil consumption with lower UC prevalence(Reference Triantafillidis, Emmanouilidis and Manousos14–Reference De Silva, Luben and Mc Taggart16). However, it is unknown whether such observational associations indicate any causal relationships between olive oil and disease risk(Reference Shivananda, Lennard-Jones and Logan15,Reference De Silva, Luben and Mc Taggart16) . By contrast, one uncontrolled trial in eight adults with UC using 1 g olive oil capsules demonstrated no effects on UC disease activity scores after a 12-month period(Reference Greenfield, Green and Teare17). However, higher doses have yet to be investigated; no randomised controlled trials or systematic review of human or animal trials has been published to our knowledge.
Aim
We aimed to systematically review and, if appropriate, perform a meta-analysis of interventions using extra virgin olive oil from table olives (Olea europaea) or their constituents on disease outcomes of individuals living with UC and murine models of UC at any stage of the disease.
Methods
Searches for eligible articles for the systematic literature review commenced on 9 July 2018 and concluded on 16 August 2018. Inclusion of hand-searched literature and new trials identified through alerts and the Cochrane central registry of clinical trials concluded on 22 June 2020. This systematic literature review adhered to PRISMA guidelines(Reference Moher, Liberati and Tetzlaff18) and was prospectively registered with the international prospective register of systematic reviews (PROSPERO) under CRD42018103754 on 9 August 2018.
Search strategy
A systematic literature search was conducted using the following databases: MEDLINE (1946 to August 2018), AMED (1985 to August 2018), CINAHL (1981 to August 2018), Embase (1947 to August 2018), Web of Science (1900 to August 2018), Google Scholar (first 100 results from 2008 to August 2018) and Cochrane central registry of clinical trials (1955 to 22 June 2020). Alerts were established for MEDLINE, AMED, CINAHL, Embase, Web of Science and Google Scholar, and additional references found were included up until 22 June 2020. Search strategy included a combination of ‘Population’ (UC) AND ‘Intervention’(olives/constituents) terms. ‘Comparison intervention’ or ‘Outcome’ terms were not used, to optimise sensitivity. Searches using the following terms: (‘ulcerative colitis’ or ‘colitis’ or ‘colitis, ischemic’ or ‘colitis, microscopic’ or ‘colitis, ulcerative’ or ‘proctocolitis’ or ‘inflammatory bowel diseases’ or ‘inflammatory bowel disease’ or ‘IBD’ or ‘Crohn disease’ or ‘proctitis’ or ‘enterocolitis’) AND (‘dietary fats’ or ‘dietary fat’ or ‘olive oil’ or ‘olive’ or ‘virgin olive oil’ or ‘fatty acid’ or ‘monounsaturated’ or ‘diet’ or ‘monounsaturated fat’ or ‘phenols’ or ‘polyphenols’ or ‘flavonoids’ or ‘phenyl ethyl alcohol’ or ‘antioxidant’ or ‘olea’ or ‘Tyrosol’ or ‘Hydroxytyrosol’ or ‘Oleocanthal’ or ‘plant oils’ or ‘plant extracts’ or ‘fatty acids’ or ‘fatty acids, unsaturated’ or ‘fatty acids, monounsaturated’ or ‘dietary fats, unsaturated’). Due to the range of phenols present in olives, we explicitly searched for phenols specific to olives which have been examined in previous clinical trials(Reference Cicerale, Lucas and Keast19) in addition to broad search terms such as ‘phenols’ and ‘plant extracts’ (see online, Supplementary Material). Reference list of articles meeting the inclusion criteria was also examined to identify studies which may be eligible. No limitations were set for publication year, language or study location. Both human and animal studies were included. Potentially eligible abstracts not in English were translated to determine eligibility.
Selection of eligible studies
Inclusion criteria for both human and animal studies were as follows:
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1) randomised experimental trials including a control arm,
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2) peer-reviewed publication, either full-length articles or chapters,
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3) clinical validation of UC in humans at any stage of disease or comparative pathology in animals,
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4) ability to assess UC as an independent study arm,
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5) in vivo intervention,
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6) interventions using the olive fruit (O. europaea) and its products including olive oil, paste, freeze-dried powdered products and capsules, or phenolic compounds (Hydroxytyrosol, Tyrosol, Oleuropein and Oleocanthal). Studies using olives or its constituents as part of a broader dietary intervention were also included,
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7) administration of the intervention either orally or rectally,
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8) ability to isolate the effects of the olive fruit or its components as an intervention,
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9) disease activity outcomes via disease activity score, weight loss, mortality, histology or inflammatory markers.
No limitations were set on disease severity or duration. Other conditions not meeting the definition of UC(Reference Geboes, Dewit, Moreels, Jouret-Mourin, Faa and Geboes20) such as Crohn’s disease, Inflammatory Bowel Disease Unclassified and indeterminate colitis were excluded. Animal studies fulfilling the selection criteria were further screened for (1) mammalian models of the disease and (2) equivalent condition matching UC pathologies comprising both experimental and sporadic disease(Reference Jiminez, Uwiera and Douglas Inglis21–Reference Randhawa, Singh and Singh23). Mammalian models were selected due to the relative similarity of intestinal function and morphology to humans(Reference Jiminez, Uwiera and Douglas Inglis21). Other transient forms of colitis such as acute or episodic colitis, allergic colitis and stress colitis were excluded from this review. Studies which include olive-based interventions as part of a broader dietary intervention were considered.
The reference management software Endnote X9.3.3 was used for this review. The primary author (K.D.) was responsible for database searches, collation of studies and removal of duplicates and screening of eligible studies. Full text of remaining articles was assessed by K. D. and M. A. F. S. When agreement could not be reached, L.V. was consulted. All eligible articles were included in this systematic review.
Data extraction and analysis
Data extraction of eligible studies was completed by the first author (K. D.). A second reviewer (M. A. F. S.) verified extracted data and discrepancies for review. Summary of data extracted at each study level (aggregate) was reported. A meta-analysis for each outcome was considered if appropriate. Human and animal studies were analysed separately.
Data extraction included the following: (1) Publication metrics (first author surname, publication year, volume and number of publication), (2) population characteristics (sex, age, number recruited/studied, covariates), (3) disease & co-morbidities, (4) description of intervention, (5) duration and dose and (6) study outcomes and statistical analysis.
Outcome assessment
Due to the breadth of outcomes, assessment tools identified were in accordance with what was described in the literature, with some general trends identified. For both Disease Activity Index (DAI) scores and histology scores, an increase in the scores correspond to greater damage to colon tissue. Specific outcomes and assigned sub-scores varied between tools and are outlined accordingly in the results.
Similarly, colon shortening and increased colon weight are hallmarks of inflammation and indicators for disease progression in experimental colitis in animal models(Reference Randhawa, Singh and Singh23). As such, increased colon weight:length ratios compared with non-colitis animals are typically considered a hallmark of disease severity. Negative effect sizes for DAI, histology score and colon weight:length ratio are indicative of milder disease expression favouring the intervention, with the reverse true for controls. Colon lengths and weight outcomes independent from colon weight:length ratios reported were included in the analysis.
Quantification of inflammatory cytokines and gut microbiome outcomes may vary between studies dependent on the techniques used and the measures selected. Outcomes extracted in the results were dependent on what was described in text, with no assumptions made in the event that no measurement value was described.
WebPlotDigitizer version 4.1 was used to extract graphical data in the absence of raw values. All results are expressed as mean and standard deviation unless stated otherwise. Post-study outcomes were analysed in all studies due to incomplete baseline data. Standard deviations between groups were assumed to be the same if data were not available, and when such assumptions were made, this was identified within tables. Mean values were used for studies expressing population numbers as ranges. An effect size calculator published by the Centre of Evaluation & Monitoring was used to calculate Hedge’s bias-corrected effect sizes (ES) and 95 % CI using values extracted from the literature(24). Interpretation of ES was determined based on the benchmark proposed by Cohen(Reference Cohen25) with effects categorised as small (d = 0·2), medium (d = 0·5) and large (d = 0·8).
Quality assessment
Two review authors K. D. and M. A. F. S. performed the risk of bias assessment independently. Human studies were evaluated using the Cochrane Collaboration Risk of Bias tool(Reference Higgins, Altman and Gøtzsche26) which examines six types of bias comprising selection, performance, detection, attrition, reporting and other bias. The tool assigns each aspects of the trial with high, low or unclear risk of bias. Animal trials were evaluated using the SYRCLE’s Risk of Bias Tool which was developed based on the Cochrane Collaboration Risk of Bias tool. The tool is composed of ten questions which are assigned high, low or unclear risk of bias on aspects of the study pertinent to animal interventions(Reference Hooijmans, Rovers and de Vries27). No final score is assigned for the studies assessed, and outcomes are summarised in the form of tables. Inter-observer variability was evaluated using Kappa statistics based on evaluations by authors K. D. and M. A. F. S.
Results
Thirty-two potentially eligible studies were identified through electronic searches and search alerts (Fig. 1). All human trials identified were excluded due to uncontrolled study design (n 1) and dietary interventions in which the effects of olives could not be isolated (n 2). Ten murine studies were excluded due to non-olive interventions (n 6), interventions bypassing the gastrointestinal tract (n 2) and combined interventions in which the effects of olive components could not be isolated (n 2). This resulted in a total of nineteen eligible animal studies, with no eligible human trials. Studies were heterogeneous which precluded a meta-analysis; however, effect sizes were calculated to demonstrate the magnitude of effect of olive-based intervention in each study.
Fig. 1. Flow diagram of the literature search and selection of eligible studies.
Risk of bias
The overall study quality for eligible studies was deemed to be low. An average of 6/10 items in the risk of bias tool was not reported across all studies. Two of nineteen studies described allocation sequences through simple randomisation(Reference Voltes, Bermúdez and Rodríguez-Gutiérrez28) or by weight(Reference Cariello, Contursi and Gadaleta29) with no additional description. Eight of nineteen studies reported assessing representative histology specimens within each study arm; however, the sampling process was not described in any text (Table 1).
Table 1. SYRCLE’s risk of bias assessment
NR, not reported in text, variables could not be assessed; ✓, Satisfied; X, Not satisfied.
Study characteristics
Characteristics of animals
Twelve mouse studies and seven rat studies, representing more than 849 animals, were identified. The most common strains used were 6-to-8-week-old C57BL/6 mice and Wistar rats, and 10/19 studies used female animals. In all studies reporting age at baseline, all animals had reached sexual maturity but none could be considered old(Reference Dutta and Sengupta30). Study populations could not be assessed in three studies(Reference Giner, Andújar and Recio31–Reference Sánchez-Fidalgo, Villegas and Aparicio-Soto33) (Table 2).
Table 2. Design characteristics of eligible animal studies
F, Female; NR, not reported in text; AIN, American Institute of Nutrition; M, male; 12D–12N, 12-h daylight and 12-h night cycles.
* Total number of animals quantified from study results with the assumption of no mortality.
Environmental and control conditions
Husbandry conditions were poorly reported, with only 3/19 studies adequately describing number of animals per cage(Reference Camuesco, Gálvez and Nieto34–Reference de Paula do Nascimento, Lima and Oyama36). The American Institute of Nutrition-purified rodent diet(37,Reference Bieri38) with modified fat content was the most common food used (7/19 studies), while remaining studies reported various commercial or non-specific diets. Energy content of the diet was described in 4/19 studies and ranged between 2900 and 3970 kcal/kg(Reference Voltes, Bermúdez and Rodríguez-Gutiérrez28,Reference Giner, Andújar and Recio31,Reference Giner, Recio and Ríos32,Reference Camuesco, Gálvez and Nieto34) , while fat content ranged from 4 to 10 % by weight (Table 2). Energy-matched diets between study groups were reported in only 1/19 study(Reference Camuesco, Gálvez and Nieto34), while 5/19 studies(Reference Sánchez-Fidalgo, Villegas and Cárdeno35,Reference Sánchez-Fidalgo, Sánchez De Ibargüen and Cárdeno39–Reference Bigagli, Toti and Lodovici42) described matched fat, protein and carbohydrate content between diets. Sunflower oil was the most commonly used fat source in control diets(Reference Sánchez-Fidalgo, Villegas and Cárdeno35,Reference de Paula do Nascimento, Lima and Oyama36,Reference Sánchez-Fidalgo, Sánchez De Ibargüen and Cárdeno39–Reference Sánchez-Fidalgo, Cárdeno and Sánchez-Hidalgo41) , while maize oil(Reference Bigagli, Toti and Lodovici42) or soyabean oil(Reference Camuesco, Gálvez and Nieto34) were used in the remaining studies.
Induction of colitis
Chemically induced colitis models were the most common method of simulating UC (17/19 studies), which was achieved predominantly using dextran sulphate sodium (DSS) (14/19 studies). Despite variances between study protocols, the overall procedures were similar. Briefly, DSS solution was prepared daily to the desired concentration (wt./vol.) using distilled water. This solution was provided in place of drinking water which could be consumed ad libitum. Duration of DSS exposure and concentration used varied between studies; acute models were induced between 3 and 15 d with a DSS concentration of 2–5 %, while chronic colitis models were induced between 28 and 259 d using 0·7–2 %. The remaining studies used either 2,4,6-trinitrobenzenesulfonic acid(Reference Voltes, Bermúdez and Rodríguez-Gutiérrez28) or rectal administrations of acetic acid(Reference Hamam, Raafat and Shoukry43,Reference Wu, Tung and Chen44) . Two studies reported using transgenic HLA-B27 rats(Reference Bigagli, Toti and Lodovici42) or IL-10 knockout mice(Reference Hegazi, Saad and Mady45) predisposed to inflammation (Table 3).
Table 3. Method of inducing colitis
wt/v, weight/volume; DSS, dextran sulphate sodium; N/A, not applicable; NR, not reported in text; TNBS, 2,4,6-trinitrobenzene sulfonic acid.
Intervention
Interventions comprised olive oil (virgin and refined oils), Oleuropein, Hydroxytyrosol acetate and Tyrosol administered between 5 and 273 d, with a median of 30 d. Most studies combined olive-based intervention into dietary preparations, with 9/19 having enough information to estimate doses. These included 0·2–2·25 ml/d olive oil(Reference Voltes, Bermúdez and Rodríguez-Gutiérrez28,Reference Bigagli, Toti and Lodovici42,Reference Park, Choi and Hwang46) , 10–40 mg/d Oleuropein(Reference Giner, Andújar and Recio31,Reference Giner, Recio and Ríos32,Reference Huguet-Casquero, Xu and Gainza47) , 1·2–4·0 mg/d Hydroxytyrosol acetate(Reference Sánchez-Fidalgo, Villegas and Aparicio-Soto33,Reference Sánchez-Fidalgo, Sánchez De Ibargüen and Cárdeno39) and 3·6–5·0 mg/d Tyorosol(Reference Guvenc, Cellat and Ozkan48). Doses in eight studies could not be calculated due to unreported food consumption, one study due to unreported animal weights(Reference Wu, Tung and Chen44) and one study in which the olive oil was combined with a reagent prior to administration(Reference Voltes, Bermúdez and Rodríguez-Gutiérrez28). Voltes et al. (Reference Voltes, Bermúdez and Rodríguez-Gutiérrez28) was the only study to intervene post-colitis, while all remaining studies administered the intervention either prior to, or concurrent with, colitis induction (Table 4).
Table 4. Characteristics of the intervention and comparator study arms
SD, standard diet; SBO, soyabean oil; EVOO, extra virgin olive oil; Pre UC, prior to induction of experimental colitis; NR, not reported in text; CO, Maize Oil; OO, olive oil; SFO, sunflower oil; Hty-Ac, hydroxytyrosol acetate; NaCl, sodium chloride.
Concurrent, intervention and induction of colitis occurring at the same time points.
Five studies reported food consumption, with mice consuming 3–4 g/d(Reference Giner, Andújar and Recio31,Reference Camuesco, Gálvez and Nieto34,Reference Sánchez-Fidalgo, Villegas and Cárdeno35,Reference Takashima, Sakata and Iwakiri49) , and HLA-B27 rats 15 g/d(Reference Bigagli, Toti and Lodovici42). One study(Reference Bigagli, Toti and Lodovici42) described the method of evaluating food consumption. Lower food intake in untreated animals was reported in one study(Reference Takashima, Sakata and Iwakiri49), while four studies reported no difference between groups(Reference Giner, Andújar and Recio31,Reference Camuesco, Gálvez and Nieto34,Reference Sánchez-Fidalgo, Villegas and Cárdeno35,Reference Bigagli, Toti and Lodovici42) . None of the studies intervening via oral gavage(Reference Cariello, Contursi and Gadaleta29,Reference Hamam, Raafat and Shoukry43,Reference Wu, Tung and Chen44,Reference Park, Choi and Hwang46–Reference Guvenc, Cellat and Ozkan48) or rectal administration(Reference Voltes, Bermúdez and Rodríguez-Gutiérrez28) of an olive-based therapy described matching for potential energy contributions of the intervention.
Study outcomes
Mortality
Mortality was reported in 7/19 studies(Reference Giner, Andújar and Recio31,Reference Giner, Recio and Ríos32,Reference Sánchez-Fidalgo, Sánchez De Ibargüen and Cárdeno39,Reference Bigagli, Toti and Lodovici42,Reference Hamam, Raafat and Shoukry43,Reference Hegazi, Saad and Mady45,Reference Takashima, Sakata and Iwakiri49) and ranged from 0 to 40 %. Animals in the olive-based interventions had lower mortality rates (2·9 ± 6·6 %) compared with controls (13·9 ± 16·9 %), with three studies reporting no mortality in either group (Table 5). Deceased animals were included in the DAI analysis in one study(Reference Sánchez-Fidalgo, Sánchez De Ibargüen and Cárdeno39), while two studies did not report if deceased animals were included in any outcome analyses(Reference Hamam, Raafat and Shoukry43,Reference Takashima, Sakata and Iwakiri49) . None of the studies documented cause of death.
Table 5. Animal mortality at study completion (Percentages)
NR, not reported in text.
Disease activity
All experimental models of colitis in this review demonstrated intestinal inflammation and mucosal damage and symptoms consistent with UC, including rectal bleeding, loose stools, weight changes, altered colon morphology, altered histology and up-regulation of inflammatory markers(Reference Randhawa, Singh and Singh23,Reference Waldner and Neurath50) . Disease severity was reported in 11/19 studies(Reference Giner, Andújar and Recio31–Reference de Paula do Nascimento, Lima and Oyama36,Reference Sánchez-Fidalgo, Sánchez De Ibargüen and Cárdeno39–Reference Sánchez-Fidalgo, Cárdeno and Sánchez-Hidalgo41,Reference Huguet-Casquero, Xu and Gainza47,Reference Takashima, Sakata and Iwakiri49) as DAI, comprised sub-scores for rectal bleeding, weight loss and stool consistency. One study reported rectal bleeding scores and weight loss to characterise disease activity without using a scoring index(Reference Cariello, Contursi and Gadaleta29).
Colitis induction increased the DAI in all studies, while cessation of reagents used improved DAI outcomes, although they did not return to non-colitis levels in any study. Inclusion of an olive-based intervention reduced disease activity scores (between –0·07 and –2·1 points) compared with control–colitis animals, indicating milder symptoms, in ten of twelve studies(Reference Cariello, Contursi and Gadaleta29,Reference Giner, Andújar and Recio31–Reference Sánchez-Fidalgo, Villegas and Cárdeno35,Reference Sánchez-Fidalgo, Cárdeno and Sánchez-Hidalgo40,Reference Sánchez-Fidalgo, Cárdeno and Sánchez-Hidalgo41,Reference Huguet-Casquero, Xu and Gainza47,Reference Takashima, Sakata and Iwakiri49) reporting this outcome. The differences between groups were statistically significant in nine studies(Reference Cariello, Contursi and Gadaleta29,Reference Giner, Andújar and Recio31–Reference Sánchez-Fidalgo, Villegas and Cárdeno35,Reference Sánchez-Fidalgo, Cárdeno and Sánchez-Hidalgo40,Reference Sánchez-Fidalgo, Cárdeno and Sánchez-Hidalgo41,Reference Takashima, Sakata and Iwakiri49) , with all but one of these(Reference Sánchez-Fidalgo, Villegas and Cárdeno35) reporting moderate-to-large effects (ES –0·66 (95 % CI –1·56, 0·24) to –12·70 (95 % CI –16·8, –8·7)). Disease activity improvements were not seen in transgenic HLA-B-27 rats, however(Reference Bigagli, Toti and Lodovici42) (Table 6). Improvements to stool consistency(Reference Giner, Andújar and Recio31) and reduced rectal bleeding(Reference Giner, Recio and Ríos32) were the greatest contributors to the differences in DAI; however, only three studies reported these sub-scores(Reference Giner, Andújar and Recio31,Reference Giner, Recio and Ríos32,Reference Sánchez-Fidalgo, Villegas and Cárdeno35) . Comparing studies using the same intervention, higher intervention doses for Hydroxytyrosol(Reference Sánchez-Fidalgo, Villegas and Aparicio-Soto33,Reference Sánchez-Fidalgo, Sánchez De Ibargüen and Cárdeno39,Reference Rosillo, Sánchez-Hidalgo and González-Benjumea51) and Oleuropein(Reference Giner, Andújar and Recio31,Reference Giner, Recio and Ríos32,Reference Huguet-Casquero, Xu and Gainza47) were associated with greater DAI differences between groups.
Table 6. Post-Study disease activity index (DAI) score
(Numbers; mean values and standard deviations; 95 % confidence intervals)
* sd values unavailable in the intervention group, assumed to be same with controls.
† Negative effect size indicates lower disease activity scores and reduced severity.
‡ Mean difference, Hedges’ g Effect Size, and CI for Effect Sizes are all post-study outcomes comparing colitis animals between study arms. Effect Sizes calculated using post-test measures at kill divided by pooled Standard Deviation.
Weight changes post-study
Ten of nineteen studies(Reference Voltes, Bermúdez and Rodríguez-Gutiérrez28,Reference Cariello, Contursi and Gadaleta29,Reference Sánchez-Fidalgo, Villegas and Aparicio-Soto33,Reference de Paula do Nascimento, Lima and Oyama36,Reference Sánchez-Fidalgo, Cárdeno and Sánchez-Hidalgo40–Reference Bigagli, Toti and Lodovici42,Reference Hegazi, Saad and Mady45,Reference Park, Choi and Hwang46,Reference Takashima, Sakata and Iwakiri49) reported weight changes as an outcome independent of the DAI score. Seven of ten studies showed benefit in the intervention group indicated by reduced weight loss (–19 ± 21·3 % from baseline measures in the intervention group, −28 ± 25·3 % from baseline measures in controls)(Reference Cariello, Contursi and Gadaleta29,Reference Sánchez-Fidalgo, Villegas and Aparicio-Soto33,Reference Sánchez-Fidalgo, Cárdeno and Sánchez-Hidalgo40,Reference Sánchez-Fidalgo, Cárdeno and Sánchez-Hidalgo41,Reference Hegazi, Saad and Mady45,Reference Park, Choi and Hwang46) or greater weight gain at study completion (246 ± 18·4 g in the intervention group, 184 ± 18·4 g in animals receiving control diets)(Reference Takashima, Sakata and Iwakiri49).
Among the studies reporting outcomes favouring the intervention, four were statistically significant (P < 0·05 - 0·001)(Reference Cariello, Contursi and Gadaleta29,Reference Sánchez-Fidalgo, Villegas and Aparicio-Soto33,Reference Sánchez-Fidalgo, Cárdeno and Sánchez-Hidalgo40,Reference Sánchez-Fidalgo, Cárdeno and Sánchez-Hidalgo41) and six studies reported large ES between 0·97 (95 % CI 0·12, 1·82) and 8·73 (95 % CI 6·14, 11·33)(Reference Cariello, Contursi and Gadaleta29,Reference Sánchez-Fidalgo, Villegas and Aparicio-Soto33,Reference Sánchez-Fidalgo, Cárdeno and Sánchez-Hidalgo40,Reference Hegazi, Saad and Mady45,Reference Park, Choi and Hwang46,Reference Takashima, Sakata and Iwakiri49) . Within the remaining studies, one study using DSS mouse models(Reference de Paula do Nascimento, Lima and Oyama36) and HLA-B27 rats(Reference Bigagli, Toti and Lodovici42) reported greater weight gain in controls, while a study using 2,4,6-trinitrobenzenesulfonic acid colitis models reported non-significant outcomes with no examinable data(Reference Voltes, Bermúdez and Rodríguez-Gutiérrez28). No differences were observed between studies using acute(Reference Voltes, Bermúdez and Rodríguez-Gutiérrez28,Reference Sánchez-Fidalgo, Villegas and Aparicio-Soto33,Reference de Paula do Nascimento, Lima and Oyama36,Reference Sánchez-Fidalgo, Cárdeno and Sánchez-Hidalgo41,Reference Bigagli, Toti and Lodovici42,Reference Park, Choi and Hwang46) v. chronic(Reference Sánchez-Fidalgo, Cárdeno and Sánchez-Hidalgo40,Reference Takashima, Sakata and Iwakiri49) models of colitis (Table 7). None of the studies investigated the source of weight loss; thus, it is unknown if weight changes were attributed to anorexia, secondary effects of inflammation, altered fluid balance or other physiological changes.
Table 7. Post-study weight changes
(Numbers, mean values and standard deviations; 95 % confidence intervals)
NR, not reported in text.
* Studies reporting ‘% From Baseline Weight’ and ‘% Weight Change’ assumes animals are 100 % at baseline.
† Positive effect sizes indicate higher weights in the study intervention.
‡ Mean difference, Hedges’ g Effect Size, and CI for Effect Sizes are all post-study outcomes comparing colitis animals between study arms. Effect Sizes calculated using post-test measures at kill divided by pooled Standard Deviation.
Colon morphology
Histology score
Sixteen of nineteen studies(Reference Voltes, Bermúdez and Rodríguez-Gutiérrez28,Reference Cariello, Contursi and Gadaleta29,Reference Giner, Andújar and Recio31,Reference Sánchez-Fidalgo, Villegas and Aparicio-Soto33–Reference de Paula do Nascimento, Lima and Oyama36,Reference Sánchez-Fidalgo, Sánchez De Ibargüen and Cárdeno39–Reference Bigagli, Toti and Lodovici42,Reference Wu, Tung and Chen44–Reference Park, Choi and Hwang46,Reference Guvenc, Cellat and Ozkan48,Reference Takashima, Sakata and Iwakiri49) reported histology outcomes using parameters of colonic damage(Reference Solomon, Mansor and Mallon52,Reference Brenna, Furnes and Drozdov53) . Grading methods varied between studies, with scores ranging between 4 and 120. Fourteen studies reported blinded assessments(Reference Voltes, Bermúdez and Rodríguez-Gutiérrez28,Reference Giner, Andújar and Recio31,Reference Sánchez-Fidalgo, Villegas and Aparicio-Soto33–Reference de Paula do Nascimento, Lima and Oyama36,Reference Sánchez-Fidalgo, Sánchez De Ibargüen and Cárdeno39–Reference Bigagli, Toti and Lodovici42,Reference Hegazi, Saad and Mady45,Reference Park, Choi and Hwang46,Reference Guvenc, Cellat and Ozkan48,Reference Takashima, Sakata and Iwakiri49) .
Improved histology outcomes favouring the intervention group were demonstrated in fourteen of sixteen studies(Reference Voltes, Bermúdez and Rodríguez-Gutiérrez28,Reference Cariello, Contursi and Gadaleta29,Reference Giner, Andújar and Recio31,Reference Sánchez-Fidalgo, Villegas and Aparicio-Soto33–Reference Sánchez-Fidalgo, Villegas and Cárdeno35,Reference Sánchez-Fidalgo, Sánchez De Ibargüen and Cárdeno39–Reference Sánchez-Fidalgo, Cárdeno and Sánchez-Hidalgo41,Reference Wu, Tung and Chen44–Reference Park, Choi and Hwang46,Reference Guvenc, Cellat and Ozkan48,Reference Takashima, Sakata and Iwakiri49) , with nine studies(Reference Cariello, Contursi and Gadaleta29,Reference Giner, Andújar and Recio31,Reference Sánchez-Fidalgo, Villegas and Aparicio-Soto33,Reference Sánchez-Fidalgo, Sánchez De Ibargüen and Cárdeno39,Reference Sánchez-Fidalgo, Cárdeno and Sánchez-Hidalgo40,Reference Wu, Tung and Chen44,Reference Park, Choi and Hwang46,Reference Guvenc, Cellat and Ozkan48,Reference Takashima, Sakata and Iwakiri49) showing large ES between –0·81 (95 % CI –1·64, 0·02) and –4·51 (95 % CI –6·16, –2·86). Microscopic outcomes were reported in one study(Reference Guvenc, Cellat and Ozkan48), with statistically significant improvements in mucosal architecture, cell infiltration, crypt abscess formation and preservation of goblet cells (ES –0·5 (95 % CI –0·78, 1·98) to –1·15 (95 % CI –0·01, 2·89), P < 0·001). Five studies using DSS-colitis models reported sub-scores for proximal, middle and distal colon sections with the greatest difference noted in middle(Reference Sánchez-Fidalgo, Cárdeno and Sánchez-Hidalgo40) and distal(Reference Sánchez-Fidalgo, Villegas and Aparicio-Soto33,Reference Sánchez-Fidalgo, Sánchez De Ibargüen and Cárdeno39,Reference Sánchez-Fidalgo, Cárdeno and Sánchez-Hidalgo41,Reference Takashima, Sakata and Iwakiri49) colon sections. (Table 8).
Table 8. Histology score from colon samples
(Numbers; mean values and standard deviations; 95 % confidence intervals)
ACF, Aberrant Crypt Foci.
* For all scoring methods, lower scores indicate less damage on the colon samples.
† Negative effect size indicates lower histology scores and less tissue damage.
‡ Mean difference, Hedges’ g Effect Size, and CI for Effect Sizes are all post-study outcomes comparing colitis animals between study arms. Effect Sizes calculated using post-test measures at kill divided by pooled Standard Deviation.
Colon weight:length ratio
Nine of nineteen studies(Reference Giner, Andújar and Recio31,Reference Giner, Recio and Ríos32,Reference Camuesco, Gálvez and Nieto34–Reference de Paula do Nascimento, Lima and Oyama36,Reference Sánchez-Fidalgo, Sánchez De Ibargüen and Cárdeno39–Reference Sánchez-Fidalgo, Cárdeno and Sánchez-Hidalgo41,Reference Huguet-Casquero, Xu and Gainza47) reported colon weight:length ratios which were expressed as either mg/cm in five studies(Reference Giner, Andújar and Recio31,Reference Giner, Recio and Ríos32,Reference Camuesco, Gálvez and Nieto34,Reference de Paula do Nascimento, Lima and Oyama36,Reference Sánchez-Fidalgo, Sánchez De Ibargüen and Cárdeno39) , g/cm(Reference Sánchez-Fidalgo, Villegas and Cárdeno35) or percentages compared with non-colitis animals in two studies(Reference Sánchez-Fidalgo, Cárdeno and Sánchez-Hidalgo40,Reference Sánchez-Fidalgo, Cárdeno and Sánchez-Hidalgo41) . Favourable weight:length ratios in intervention animals were reported in six studies, with a mean difference of –11·9 ± 3·1 mg/cm(Reference Giner, Andújar and Recio31,Reference Giner, Recio and Ríos32,Reference Camuesco, Gálvez and Nieto34,Reference Sánchez-Fidalgo, Sánchez De Ibargüen and Cárdeno39) and –67·5 ± 10·6 %(Reference Sánchez-Fidalgo, Cárdeno and Sánchez-Hidalgo40,Reference Sánchez-Fidalgo, Cárdeno and Sánchez-Hidalgo41) compared with controls. Four studies showed large effects with an ES between –1·31 (95 % CI –2·27, –0·34) and –2·41 (95 % CI –3·56, –1·26)(Reference Giner, Andújar and Recio31,Reference Giner, Recio and Ríos32,Reference Sánchez-Fidalgo, Cárdeno and Sánchez-Hidalgo40,Reference Sánchez-Fidalgo, Cárdeno and Sánchez-Hidalgo41) . Results were omitted in one paper reporting no statistically significant differences between groups(Reference Huguet-Casquero, Xu and Gainza47) (Table 9).
Table 9. Colon weight/length ratio
(Numbers; mean values and standard deviations; 95 % confidence intervals)
NR, not reported in text.
* Percentage of colon weight:length ratios compared with non-colitis control animals at kill; control animals were assumed to be 100 %.
† Negative effect size indicates lower weight/length ratio in the intervention.
‡ Mean difference, Hedges’ g Effect Size, and CI for Effect Sizes are all post-study outcomes comparing colitis animals between study arms. Effect Sizes calculated using post-test measures at kill divided by pooled Standard Deviation.
Colon length
Colon length was reported by 6/19 studies, comprised four mouse studies(Reference Giner, Andújar and Recio31,Reference Sánchez-Fidalgo, Villegas and Aparicio-Soto33,Reference de Paula do Nascimento, Lima and Oyama36,Reference Park, Choi and Hwang46) and two rat studies(Reference Wu, Tung and Chen44,Reference Takashima, Sakata and Iwakiri49) . Average colon length of non-colitis animals was 7·9 ± 0·7 cm for mice and 17·3 ± 2·8 cm for rats, which was shortened in all animals induced with colitis, a sign of inflammation and colonic injury. Olive-based interventions attenuated this change, with longer colon lengths reported in intervention animals (mean 6·3 ± 0·6 cm in mice, 13·1 ± 1·4 cm in rats) compared with controls (mean 5·9 ± 0·6 cm in mice, 11·2 ± 1·3 cm in rats). One of six studies reported statistical significance favouring the intervention(Reference Wu, Tung and Chen44), while 4/6 studies(Reference Giner, Andújar and Recio31,Reference Sánchez-Fidalgo, Villegas and Aparicio-Soto33,Reference Wu, Tung and Chen44,Reference Takashima, Sakata and Iwakiri49) reported large ES between +0·88 (95 % CI 0·04, 1·72) and +2·36 (95 % CI 1·22, 3·50) (Table 10).
Table 10. Colon length between study arms
(Numbers; mean values and standard deviations; 95 % confidence intervals)
NR, not reported in text.
* In studies not reporting colon lengths of non-colitis intervention animals (NR), Mean and Standard Deviation values assumed to be the same as non-colitis controls.
† Positive effect sizes indicate greater colon lengths favouring the intervention arm.
‡ Mean difference, Hedges’ g Effect Size, and CI for Effect Sizes are all post-study outcomes comparing colitis animals between study arms. Effect Sizes calculated using post-test measures at kill divided by pooled Standard Deviation.
Inflammatory cytokines
TNF-α
Fourteen studies reported TNF-α outcomes post-kill(Reference Giner, Andújar and Recio31,Reference Camuesco, Gálvez and Nieto34–Reference de Paula do Nascimento, Lima and Oyama36,Reference Sánchez-Fidalgo, Sánchez De Ibargüen and Cárdeno39–Reference Wu, Tung and Chen44,Reference Park, Choi and Hwang46–Reference Takashima, Sakata and Iwakiri49) ; nine studies reported concentrations in colon tissue(Reference Giner, Andújar and Recio31,Reference Camuesco, Gálvez and Nieto34–Reference de Paula do Nascimento, Lima and Oyama36,Reference Hamam, Raafat and Shoukry43,Reference Wu, Tung and Chen44,Reference Huguet-Casquero, Xu and Gainza47–Reference Takashima, Sakata and Iwakiri49) , three studies quantified TNF-α mRNA in tissue samples(Reference Sánchez-Fidalgo, Cárdeno and Sánchez-Hidalgo40–Reference Bigagli, Toti and Lodovici42), one study expressed TNF-α in percentages compared with non-colitis animals(Reference Sánchez-Fidalgo, Sánchez De Ibargüen and Cárdeno39) and one study reported number of cells expressing antibodies(Reference Park, Choi and Hwang46). Twelve of fourteen studies(Reference Giner, Andújar and Recio31,Reference Camuesco, Gálvez and Nieto34,Reference Sánchez-Fidalgo, Villegas and Cárdeno35,Reference Sánchez-Fidalgo, Sánchez De Ibargüen and Cárdeno39–Reference Wu, Tung and Chen44,Reference Park, Choi and Hwang46–Reference Guvenc, Cellat and Ozkan48) reported lower TNF-α expression in the intervention group compared with controls, with nine studies statistically significant (P < 0·001 to 0·05)(Reference Giner, Andújar and Recio31,Reference Sánchez-Fidalgo, Sánchez De Ibargüen and Cárdeno39,Reference Sánchez-Fidalgo, Cárdeno and Sánchez-Hidalgo41–Reference Wu, Tung and Chen44,Reference Park, Choi and Hwang46–Reference Guvenc, Cellat and Ozkan48) . ES ranged from –0·34 (95 % CI –1·15, 0·48) to –4·63 (95 % CI –6·31, –2·95), with nine of fourteen moderate-to-large favouring the intervention(Reference Giner, Andújar and Recio31,Reference Camuesco, Gálvez and Nieto34,Reference Sánchez-Fidalgo, Cárdeno and Sánchez-Hidalgo41–Reference Wu, Tung and Chen44,Reference Park, Choi and Hwang46–Reference Guvenc, Cellat and Ozkan48) . One study reported outcomes favouring controls(Reference de Paula do Nascimento, Lima and Oyama36) which was not statistically significant but had a large ES (+0·95, 95 % CI 0·00, 1·89). (Table 11).
Table 11. TNF-α in colon tissue post kill
(Numbers; mean values and standard deviations; 95 % confidence intervals)
NR, not reported in text.
† Negative effect size indicates lower colon TNF-α expression in the intervention group.
‡ Mean difference, Hedges’ g Effect Size, and CI for Effect Sizes are all post-study outcomes comparing colitis animals between study arms. Effect Sizes calculated using post-test measures at kill divided by pooled Standard Deviation.
IL
Four families were identified in this systematic review: IL-1β, IL-6, IL-10 and IL-17.
IL-1β
Nine studies assessed pro-inflammatory IL-1β expressed as quantities in tissue(Reference Giner, Andújar and Recio31,Reference Giner, Recio and Ríos32,Reference de Paula do Nascimento, Lima and Oyama36,Reference Wu, Tung and Chen44) , relative gene expression(Reference Cariello, Contursi and Gadaleta29,Reference Bigagli, Toti and Lodovici42) , percentages compared with non-colitis animals(Reference Sánchez-Fidalgo, Sánchez De Ibargüen and Cárdeno39) and number of stained cells in sampled colon tissue(Reference Park, Choi and Hwang46). Induction of experimental colitis resulted in higher IL-1β expression compared with non-colitis animals in all studies. Animals receiving an olive-based intervention showed a lower expression of IL-1β in 6/9 studies (ES −0·54 (95 % CI − 1·61, 0·52) to −3·57 (95 % CI − 5·40, −1·75)(Reference Cariello, Contursi and Gadaleta29,Reference Giner, Andújar and Recio31,Reference Giner, Recio and Ríos32,Reference Bigagli, Toti and Lodovici42,Reference Wu, Tung and Chen44,Reference Park, Choi and Hwang46) . Statistical significance (P < 0·05) was reported in 3/9 studies(Reference Cariello, Contursi and Gadaleta29,Reference Giner, Andújar and Recio31,Reference Wu, Tung and Chen44) , all favouring the intervention. Results were omitted in one paper reporting no statistically significant differences between groups(Reference Takashima, Sakata and Iwakiri49). (Table 12).
Table 12. IL-1β in colon tissue post kill
(Numbers; mean values and standard deviations; 95 % confidence intervals)
NR, not reported in text.
* Expressions in % refer to proportions compared with non-colitis control animals at time of kill.
† Negative effect size indicates lower expression of IL-1β in the intervention group.
‡ Mean difference, Hedges’ g Effect Size, and CI for Effect Sizes are all post-study outcomes comparing colitis animals between study arms. Effect Sizes calculated using post-test measures at kill divided by pooled Standard Deviation.
IL-6
Ten studies examined pro-inflammatory IL-6 expressed as tissue concentration(Reference Giner, Andújar and Recio31,Reference Giner, Recio and Ríos32,Reference Sánchez-Fidalgo, Villegas and Cárdeno35,Reference de Paula do Nascimento, Lima and Oyama36,Reference Wu, Tung and Chen44,Reference Huguet-Casquero, Xu and Gainza47,Reference Guvenc, Cellat and Ozkan48) , number of stained cells in colon samples(Reference Park, Choi and Hwang46) or relative gene expression(Reference Cariello, Contursi and Gadaleta29). Nine of ten studies(Reference Cariello, Contursi and Gadaleta29,Reference Giner, Andújar and Recio31,Reference Giner, Recio and Ríos32,Reference Sánchez-Fidalgo, Villegas and Cárdeno35,Reference de Paula do Nascimento, Lima and Oyama36,Reference Wu, Tung and Chen44,Reference Park, Choi and Hwang46–Reference Guvenc, Cellat and Ozkan48) reported lower IL-6 favouring the intervention group, with 6/10 statistically significant (P < 0·01 to P < 0·001)(Reference Cariello, Contursi and Gadaleta29,Reference Giner, Andújar and Recio31,Reference Giner, Recio and Ríos32,Reference Wu, Tung and Chen44,Reference Huguet-Casquero, Xu and Gainza47,Reference Guvenc, Cellat and Ozkan48) . Seven of ten studies had large ES between –0·84 (95 %CI –1·76, 0·07) and –2·81 (95 % CI –4·29, –1·33)(Reference Cariello, Contursi and Gadaleta29,Reference Giner, Andújar and Recio31,Reference Giner, Recio and Ríos32,Reference Wu, Tung and Chen44,Reference Park, Choi and Hwang46–Reference Guvenc, Cellat and Ozkan48) . Results were omitted in one paper reporting no statistically significant differences between groups(Reference Takashima, Sakata and Iwakiri49) (Table 13).
Table 13. Interleukin-6 post kill
(Numbers; mean values and standard deviations; 95 % confidence intervals)
NR, not reported in text.
† Negative effect size indicates lower expression of IL-6 in the intervention group.
‡ Mean difference, Hedges’ g Effect Size, and CI for Effect Sizes are all post-study outcomes comparing colitis animals between study arms. Effect Sizes calculated using post-test measures at kill divided by pooled Standard Deviation.
IL-10
Three studies reported anti-inflammatory IL-10 outcomes which were expressed using varying units of measure(Reference Giner, Recio and Ríos32,Reference de Paula do Nascimento, Lima and Oyama36,Reference Sánchez-Fidalgo, Sánchez De Ibargüen and Cárdeno39) . Colitis induction reduced IL-10 expression in all the animals, which was attenuated by olive-based interventions in 2/3 studies(Reference Giner, Recio and Ríos32,Reference Sánchez-Fidalgo, Sánchez De Ibargüen and Cárdeno39) . Measures of IL-10 were 34–43 % greater in intervention animals compared with controls at kill. Outcomes from two studies were statistically significant, with large ES of +0·99 (95 % CI 0·13, 1·85)(Reference Sánchez-Fidalgo, Sánchez De Ibargüen and Cárdeno39) and +10·33 (95 % CI 6·30, 14·17)(Reference Giner, Recio and Ríos32). Results were omitted in one paper reporting no statistically significant differences between groups(Reference de Paula do Nascimento, Lima and Oyama36).
IL-17
Park et al. was the only study reporting pro-inflammatory IL-17 outcome, expressed as number of positive cells(Reference Park, Choi and Hwang46). Mean cell count expressing IL-17 in non-colitis animals was 10·5 ± 5·4 cells, while induction of colitis resulted in a marked increase in IL-17 expression. This increase was milder in intervention animals (55·9 ± 12·0 cells) compared with controls (71·2 ± 5·0 cells). This outcome was not statistically significant; however, calculated ES was –1·49 (95 % CI –2·89, –0·09).
Other outcomes
Microbiome outcomes were reported in only 1/19 studies(Reference Wu, Tung and Chen44), expressed as colony forming units of three bacteria families. Experimental colitis reduced Lactobacillus spp. and Bifidobacterium spp. counts in all study arms, while Clostridium perfringens counts remained stable. Animals supplemented with olive oil maintained greater Lactobacillus spp. counts compared with controls post induction of colitis, while Bifidobacterium spp. counts were not impacted by the intervention.
Outcomes not discussed due to word limits include myeloperoxidase activity, cyclo-oxygenase-2, monocyte chemoattractant protein-1, PPAR-γ, inducible nitric oxide synthase, p38 mitogen-activated protein kinases, interferon gamma, alkaline phosphatase activity, glutathione concentration, leukotriene B4, proliferating cell nuclear antigen, erythropoietin activity, N-acetyl-B-D-glucosaminidase activity, IκB kinase activity, pJNK, proteins p53, p65, STAT3, prostaglandin E synthase, pERK1/2 activation, caspase 3, NF-κB, b-catenin staining pattern, matrix metalloproteinase-9, Foxp3 expression and A1 mRNA expression.
Discussion
To our knowledge, this is the first systematic review investigating the effects of olive-based interventions on the expression of UC in both humans and animal models. A significant body of work has been done in murine models of colitis, while no randomised controlled trials in humans have been published at the time of writing. Studies were heterogeneous, which precluded a meta-analysis; however, general trends were identified, as discussed below.
Overall effects of olive-based interventions
Animals receiving olive-based interventions had milder UC severity in most studies, as shown by lower disease activity scores and favourable inflammatory markers compared with controls at kill. Interestingly, such findings were not replicated in HLA-B27 rats(Reference Bigagli, Toti and Lodovici42) and one study using C57BL/6 mice(Reference de Paula do Nascimento, Lima and Oyama36). All remaining studies using C57BL/6 mice models demonstrated outcomes favouring the intervention(Reference Cariello, Contursi and Gadaleta29,Reference Giner, Recio and Ríos32,Reference Sánchez-Fidalgo, Villegas and Aparicio-Soto33,Reference Sánchez-Fidalgo, Villegas and Cárdeno35,Reference de Paula do Nascimento, Lima and Oyama36,Reference Sánchez-Fidalgo, Sánchez De Ibargüen and Cárdeno39–Reference Sánchez-Fidalgo, Cárdeno and Sánchez-Hidalgo41,Reference Park, Choi and Hwang46,Reference Huguet-Casquero, Xu and Gainza47) , while no other study used HLA-B27 models. Other rat models however demonstrated outcomes favouring olive-based interventions(Reference Voltes, Bermúdez and Rodríguez-Gutiérrez28,Reference Camuesco, Gálvez and Nieto34,Reference Hamam, Raafat and Shoukry43,Reference Wu, Tung and Chen44,Reference Guvenc, Cellat and Ozkan48,Reference Takashima, Sakata and Iwakiri49) ; thus, it is unclear if the use of HLA-B27 rat models or other experimental variables influenced these outcomes.
Insufficient intervention doses may have contributed to this discrepancy. Polyphenol content was not described in one study(Reference de Paula do Nascimento, Lima and Oyama36), while Bigagli et al. reported hydroxytyrosol concentration of 15 mg/kg olive oil, equivalent to a daily dose of 90 μg/kg body weight in HLA-B27 rats(Reference Bigagli, Toti and Lodovici42). By contrast, findings from other studies in this review suggest clinically significant outcomes were associated with polyphenol concentrations above 0·4 mg/kg body weight(Reference Sánchez-Fidalgo, Sánchez De Ibargüen and Cárdeno39,Reference Sánchez-Fidalgo, Cárdeno and Sánchez-Hidalgo40) . Similarly, in this review, we identified greater attenuation of disease scores at higher concentration of Hydroxytyrosol(Reference Sánchez-Fidalgo, Villegas and Aparicio-Soto33,Reference Sánchez-Fidalgo, Sánchez De Ibargüen and Cárdeno39,Reference Rosillo, Sánchez-Hidalgo and González-Benjumea51) and Oleuropein(Reference Giner, Andújar and Recio31,Reference Giner, Recio and Ríos32) . It should be noted that adverse effects may occur at higher doses(Reference Kouka, Tekos and Papoutsaki54); however, this was not evident in any study in this review. Furthermore, a dose–response relationship cannot yet be established due to the small sample sizes, heterogeneity of studies and variable reporting of experimental methods.
Effects on body weight
Weight loss and malnutrition are known complications associated with colitis in both animal models(Reference Goyal, Rana and Ahlawat55,Reference Antoniou, Margonis and Angelou56) and human cohorts(Reference Alastair, Emma and Emma9,Reference Cabré and Gassull57) . Anorexia, malabsorption, dietary restrictions and gut microbiome disturbances are some of the contributors to this phenomenon(Reference Scaldaferri, Pizzoferrato and Lopetuso58–Reference Tuzun, Uygun and Yesiolva60). In this systematic review, olive-based interventions improved weight outcomes concordant with milder disease activity, as indicated by weight maintenance or increased weight gain. Energy density of control and intervention diets was matched in most studies; however, such precautions were not evident in studies intervening through oral gavage or rectal administration. As such, it is unknown if these interventions influenced daily energy intake and subsequent weight outcomes. Similarly, housing conditions and husbandry were poorly described in most studies and potential confounders for feeding behaviour and subsequent weight outcomes(Reference Yamauchi, Fujita and Obara61,Reference Nicholson, Malcolm and Russ62) .
Interestingly, olive oil supplementation increased oral intake in one study(Reference Takashima, Sakata and Iwakiri49). Although exact mechanisms are unclear, associations between gastrointestinal dysfunction and feeding behaviours are plausible(Reference Tuzun, Uygun and Yesiolva60), as milder symptoms may promote feeding behaviour. In conjunction with these changes, mucosal healing as indicated by stool consistency and histology outcomes may offer greater opportunity for fluid and nutrient absorption along the gastrointestinal tract. In combination, these changes may ultimately contribute towards favourable weight outcomes in intervention animals. This relationship remains speculative as few studies quantified oral intake, further complicated by multiple animals per cage and ad libitum feeding.
Finally, gut microbiome favourable shifts mediated by olive interventions may have contributed to the outcomes observed. Reduced gut bacterial diversity and abundance of commensal species have been associated with disease severity in both UC and experimental colitis(Reference Fabia, Ar’Rajab and Johansson63). Such changes are significant considering the microbiome’s role in supporting gut barrier integrity, gut inflammatory tone and intestinal immunity through the production of SCFA (e.g., butyrate) and other host interactions. By contrast, previous studies have shown that olive oil supplementation promotes α-diversity of commensal bacterial species and accumulation of lean muscle mass in healthy C57BL/6J mice(Reference Patterson, O’ Doherty and Murphy64), a finding which was replicated in this review(Reference Wu, Tung and Chen44). No other study assessed microbiome outcomes; thus, any conclusions are premature.
Colon morphology
Chemically induced colitis results in several features which differ depending on the reagent and dosage used. DSS-colitis models exhibit loss of surface epithelium which subsequently increases mucosal permeability, predominantly impacting the distal colon. Administration of 2,4,6-trinitrobenzenesulfonic acid results in thickening of the proximal colon accompanied by loss of haustration, while intra-rectal administration of acetic acid solution results in necrosis of intestinal mucosa and submucosa(Reference Randhawa, Singh and Singh23). Despite the variability of these changes, several shared features such as oedema, ulcerations, granulocyte infiltration and dysplasia can be used to ascertain severity of experimental colitis.
Findings from this review suggest that olive-based interventions may have a role in preserving colonic architecture and metabolic-immunological function in experimental UC. This was evident through milder microscopic and macroscopic outcomes, histology scores and normalised weight:length ratios favouring intervention animals. It should be noted that olive-based interventions did not prevent intestinal injury in any study; however, the degree of damage was considerably lower compared with animals in the control arm.
Comparing sub-sections of the colon, middle and distal sections are known to be most affected by colitis(Reference Diaz-Granados, Howe and Lu65,Reference Chassaing, Aitken and Malleshappa66) . Importantly, these sub-sections showed the greatest improvements in response to olive-based interventions, suggesting specific protection on these sites. Promotion of wound healing and protection against oxidative damage of intestinal cells mediated by olive polyphenols have previously been demonstrated(Reference Giner, Recio and Ríos32) which may explain how olive-based interventions protect against chemically induced colitis.
Beneficial alterations to the microbiome mediated by olive polyphenols may have conferred additional protective effects against experimental colitis. Consumption of olive oil and olive polyphenols has been demonstrated to facilitate growth of butyrate producing bacteria such as Lactobacillus and Bifidobacterium (Reference Farràs, Martinez-Gili and Portune67), increase mucosal concentrations of SCFA(Reference Farràs, Martinez-Gili and Portune67) and inhibit growth of pathogenic species associated with inflammation(Reference Rodríguez-García, Sánchez-Quesada and Algarra68). SCFA such as butyrate play a vital role in preserving intestinal epithelial barrier and serve as fuel for colonocytes(Reference Parada Venegas, De la Fuente and Landskron69,Reference Rivière, Selak and Lantin70) . Furthermore, SCFA have been demonstrated to exert anti-inflammatory effects in the intestinal mucosa(Reference Parada Venegas, De la Fuente and Landskron69). Metabolism of SCFA is impaired in UC and has been correlated with poorer histology and endoscopy outcomes(Reference De Preter, Arijs and Windey71). As such, strategies targeting both the microbiome and SCFA production may assist in maintaining colon homoeostasis; however, current evidence remains inconsistent, and further investigations are warranted.
Inflammatory markers
Many health outcomes of olive-based interventions have been ascribed to component effects on inflammatory responses. Olive oil is predominantly composed of the MUFA oleic acid, which has been shown to protect against oxidative stress, regulate immune function in intestinal smooth muscle cells and disrupt arachidonic acid and NF-κB signalling pathways associated with chronic inflammation(Reference Cariello, Contursi and Gadaleta29,Reference Gálvez, Camuesco, Rodríguez-Cabezas, Preedy and Watson72) . Prospective studies in healthy cohorts suggest an inverse association between oleic acid consumption and risk of developing UC(Reference De Silva, Luben and Mc Taggart16), although such findings have yet to be replicated in larger studies(Reference Hart, Luben and Olsen73). Similarly, associations between dietary oleic acid and disease severity in individuals living with UC remain inconclusive despite promising findings in pre-clinical and clinical data(Reference Barnes, Nestor and Onyewadume74).
Consumption of olive oil may confer additional benefits through displacing less desirable fatty acids in the diet. Specific fatty acids such as n-6 PUFA, saturated fats, trans fats and high fat diets have been associated with increased markers of pro-inflammatory cytokines(Reference Wiese, Horst and Brown75), increased risk of developing UC(Reference De Silva, Luben and Mc Taggart16) and worsening symptoms in individuals living with UC and animal models(Reference Wiese, Horst and Brown75,Reference Nishida, Miwa and Shigematsu76) . Similarly, inclusion of n-3 fatty acids have been demonstrated to exert protective effects against experimental colitis(Reference Dennis and Norris77,Reference Bosco, Brahmbhatt and Oliveira78) ; however, its role in prevention and treatment of UC remains controversial(Reference Barbalho, Goulart and Quesada79–Reference Turner, Shah and Steinhart81). Finally, although dietary fat manipulation through olive oil consumption may confer some benefits on inflammatory markers and disease outcomes, it is unlikely that the effects observed in this review could be attributed to the fatty acid profile alone.
Previous experiments have highlighted the bioavailability and anti-inflammatory properties of olive oil polyphenols such as Oleuropein, Hydroxytyrosol and Oleocanthal in the gut(Reference Corona, Tzounis and Assunta DessÌ82). In this review, we identified dose-dependent associations between Hydroxytyrosol and Oleuropein interventions with lower cytokine expression in concert with improved disease outcomes in murine models of UC. These findings further support previous in vitro studies on colonic biopsies of UC cohorts(Reference Larussa, Oliverio and Suraci83) and healthy cohorts(Reference Martin-Pelaez, Castaner and Sola84,Reference Papageorgiou, Tousoulis and Psaltopoulou85) , in which cytokine expression was reduced by olive polyphenols such as Hydroxytyrosol and Oleuropein.
Regulation of inflammatory markers has been identified as a potential therapeutic target in IBD, as increased secretion of pro-inflammatory (TNF-α, IL-1β, IL-6) and reduction of anti-inflammatory cytokines (IL-10) are associated with chronic inflammation and symptoms(Reference Cioffi, Rosa and Serao86–Reference Reimund, Wittersheim and Dumont88). However, limited evidence is available on the specific markers associated with UC outcomes and their response to olive-based interventions, with several inconsistencies identified in the literature. Moraes et al. found minimal differences in cytokine expression between a cross-sectional study of UC cohorts with and without gastrointestinal symptoms(Reference Moraes, Magnusson and Mavroudis89). Similarly, an uncontrolled study comparing 50 ml/d extra virgin olive oil and rapeseed oil interventions in UC cohorts reported alleviation of gastrointestinal symptoms and reduction of hs-CRP without alterations to serum TNF-α favouring extra virgin olive oil, although no other markers were quantified(Reference Morvaridi, Jafarirad and Seyedian90). Finally, a meta-analysis in non-IBD populations similarly reported no changes to TNF-α despite favourable CRP and IL-6 outcomes with olive oil interventions(Reference Schwingshackl, Christoph and Hoffmann91). The discrepancies between animal data in this review and human studies highlight the limitations of translating our findings to human cohorts and current gaps in the evidence. As such, although olive-based interventions appear to influence disease activity and symptoms as well as attenuation of pro-inflammatory cytokine expression in experimental UC models, it is unknown if findings would be replicated in human trials. Therefore, further investigations are warranted.
Limitations of this review methodology
The search strategy for this review was comprehensive, although no unpublished studies were sought, and no non-English language databases were searched, which could have limited the number of trials available for review. In addition, only one author (K. D.) performed the search and initial selection of eligible articles. However, the final selection was agreed upon by all authors.
Limitations of the literature to date
The studies identified were heterogeneous, with variations between experimental models, outcome measures and methods of evaluating disease severity. Chemically induced colitis models formed the majority of the evidence, which may limit the translation of our findings to other models of UC and human cohorts. Scaling up of olive oil doses described in this review for individuals living with UC should consider the feasibility and safety of implementing these interventions. Furthermore, quality of the evidence through the SYRCLE’s Risk of Bias tool was sub-optimal due to limited reporting of key domains such as animal characteristics and husbandry; factors known to influence disease severity and experimental outcomes (such as individual animal stool volumes), as well as determine actual individual animal consumption of both food and olive-based product(Reference Mähler, Bristol and Leiter92,Reference Bramhall, Flórez-Vargas and Stevens93) . Moreover, strength to murine models of IBD would be further enhanced if researchers conducting the histology studies were unsighted to the collected colon samples.
Most of the studies intervened prior to, or during induction of, experimental colitis, limiting our ability to determine the efficacy of such strategies post-colitis. It does lend support to epidemiological data on consumption patterns and risk of developing disease(Reference Triantafillidis, Emmanouilidis and Manousos14–Reference De Silva, Luben and Mc Taggart16). However, translation to therapeutic interventions in cohorts who have established UC or similar conditions require explicit human studies with robust experimental designs.
Conclusion
Olive-based interventions exerted protective effects against chemically induced colitis in murine models. Despite these promising outcomes, conclusions are limited by the overall low quality of existing animal trials due to sub-optimal reporting of key parameters. Future investigations should include well-defined baseline characteristics, greater transparency regarding randomisation, blinding and husbandry as well as mortality. Most importantly, translation of these basic studies to human trials is warranted given the absence of robustly designed trials investigating the relationship between olive-based interventions and outcomes in UC cohorts.
Acknowledgements
The authors would like to acknowledge the contributions of Associate Professor Helen O’Connor during the conception and design phase of this manuscript, as well as supervision of author K. D.
This research received no specific grant from any funding agency, commercial or not-for-profit sectors.
All authors contributed equally towards the study conception and design. K. D. was responsible for data extraction and analysis. Data integrity and accuracy were confirmed by K. D. and M. A. F. S. and K. D. drafted the manuscript, which was revised by L. V. and M. A. F. S. All authors read and approved the final manuscript.
There are no conflicts of interest.
Supplementary material
For supplementary material referred to in this article, please visit https://doi.org/10.1017/S0007114521001999
