Dried Fruits, Nuts, and Cancer Risk and Survival: A Review of the Evidence and Future Research Directions
Abstract
:1. Introduction
2. Dietary Strategies to Prevent Cancer
3. Dried Fruits and Cancer
3.1. Preclinical Studies Relating Dried Fruits and Cancer
3.2. Human Intervention Studies of Dried Fruits and Cancer
3.3. Epidemiological Studies of Dried Fruits and Cancer
3.3.1. Cancer Incidence (or Risk)
3.3.2. Cancer Mortality and Survival
3.4. Research Gaps, Needs, and Priorities Related to Dried Fruits and Cancer
4. Tree Nuts, Peanuts, and Cancer
4.1. Preclinical Studies Related to Nuts and Cancer
4.2. Human Intervention Studies of Nuts and Cancer
4.3. Epidemiological Studies of Nuts and Cancer
4.3.1. Cancer Incidence
4.3.2. Cancer Mortality and Survival
4.4. Research Gaps, Needs, and Priorities Related to the Study of Nuts and Cancer
5. Summary and Recommendations
Supplementary Materials
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Acknowledgments
Disclaimer
Conflicts of Interest
References
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Study Type | Participants | Cancer Type | Outcome (95% CI) | Reference |
---|---|---|---|---|
Systematic review | n = 437,298 from 16 studies | Pancreatic, prostate, colorectal polyps | Dose-response trend from prospective studies | Mossine et al., 2020 [51] |
Stomach, pancreatic, colorectal, nasopharyngeal, bladder | Total dried fruit, raisins, or dates reduced incidence from case–control studies | |||
Cohort | UK Women’s Cohort Study (n = 35,372 women aged 35–69 in England, Wales, and Scotland) | Breast | HR 1.04 (0.98,1.13) | Dunneram et al., 2019 [60] |
Endometrial | HR 0.60 (0.37, 0.97) | |||
Ovarian | HR 1.06 (0.89, 1.26) | |||
Prospective cohort | National Institutes of Health-American Association of Retired Persons Diet and Health Study (n = 485,403 men and women aged 50–71 at baseline in the United States) | Liver | HR (Q5 vs. Q1) 0.73 (0.60, 0.89) | Zhao et al., 2022 [61] |
Mendelian randomization | UK Biobank (n ~500,000 men and women aged 49–69 in the United Kingdom) | Oral cavity/pharyngeal | IVW OR 0.17 (0.04, 0.69) | Jin et al., 2022 [62] |
Lung | IVW OR 0.33 (0.17, 0.64) | |||
Squamous cell lung | IVW OR 0.23 (0.09, 0.60) | |||
Breast | IVW OR 0.47 (0.32, 0.68) | |||
Pancreatic | IVW OR 0.03 (0.001, 0.68) | |||
Cervical | IVW OR 0.99 (0.9897, 0.9998) | |||
Lung adenocarcinoma, endometrial, thyroid, prostate, bladder, brain | IVW OR not significant |
Author Year | Cancer Model | Putative Mechanism of Nuts Dietary Factor | Dietary Factor |
---|---|---|---|
Breast Cancer-Related Studies | |||
Hardman and Ion 2008 [90] | Human breast cancer tumors in nude mice | Suppression of cell proliferation or suppression of metastasis | 18% of dietary calories from walnuts |
Hardman et al., 2011 [75] | C(3)1 TAg transgenic mice, breast cancer | Alterations in cell signaling related to proliferation, differentiation, and apoptosis | Walnuts in the diet |
Garcia et al., 2015 [76] | Implanted mammary gland adenocarcinoma in BALB/c mouse model | Inhibition of cyclooxygenase and lipoxygenase | 6% walnut oil or 6% walnut flour containing phytomelatonin |
Chen et al., 2015 [77] | Breast cancer cells | Growth inhibition of breast cancer cells through cell cycle arrest and inhibition of proliferation | Ellagic acid that is abundant in walnuts |
Colorectal Cancer-Related Studies | |||
Hong et al., 2022 [78] | Colonic cell proliferation, apoptosis, and gene expression in rat model | Reduced DNA damage possibly via downregulation of RelA inflammation gene expression without changes to colonic cell proliferation and apoptosis | Mixed nuts in the diet |
Chen et al., 2020 [79] | Mouse tumor bioassay after colonotropic carcinogen exposure | Favorably altering the gut microbiota | Walnuts in a Western diet |
Nagel et al., 2012 [80] | HT-29 human colon cancer cells in nude mice | Inhibition of tumor growth rate through suppression of angiogenesis | Walnut and flaxseed oil |
Nakanishi et al., 2016 [81] | Mice treated with organotropic colon carcinogen | Tumor suppression associated with alterations in gut bacteria | Dietary walnut of up to 15% of total caloric intake |
Davis and Iwahashi 2001 [82] | Aberrant crypt foci (ACF) in rats treated with azoxymethane | ACF and cell turn over reduced | Whole almond-, almond meal- or almond oil-containing diet |
Prostate Cancer-Related Studies | |||
Davis et al., 2012 [85] | Transgenic adenocarcinoma of the mouse prostate (TRAMP) | Reduced TRAMP mouse prostate cancer growth and size; declines in plasma IGF-1, resistin, and LDL | Whole almonds as part of a high-fat diet |
Kim et al., 2014 [86] | TRAMP | Reduced TRAMP mouse prostate cancer growth and size; improved insulin sensitivity and effects on cellular energy status, tumor suppression | Whole walnuts, walnut oil |
Reiter et al., 2013 [87] | Implanted tumor model in nude mice | Reduced number and growth of LNCaP human prostate cancer cells; decreased oxidative stress | Standard mouse diet supplemented with walnuts |
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Bolling, B.W.; Aune, D.; Noh, H.; Petersen, K.S.; Freisling, H. Dried Fruits, Nuts, and Cancer Risk and Survival: A Review of the Evidence and Future Research Directions. Nutrients 2023, 15, 1443. https://doi.org/10.3390/nu15061443
Bolling BW, Aune D, Noh H, Petersen KS, Freisling H. Dried Fruits, Nuts, and Cancer Risk and Survival: A Review of the Evidence and Future Research Directions. Nutrients. 2023; 15(6):1443. https://doi.org/10.3390/nu15061443
Chicago/Turabian StyleBolling, Bradley W., Dagfinn Aune, Hwayoung Noh, Kristina S. Petersen, and Heinz Freisling. 2023. "Dried Fruits, Nuts, and Cancer Risk and Survival: A Review of the Evidence and Future Research Directions" Nutrients 15, no. 6: 1443. https://doi.org/10.3390/nu15061443
APA StyleBolling, B. W., Aune, D., Noh, H., Petersen, K. S., & Freisling, H. (2023). Dried Fruits, Nuts, and Cancer Risk and Survival: A Review of the Evidence and Future Research Directions. Nutrients, 15(6), 1443. https://doi.org/10.3390/nu15061443