Hostname: page-component-cd9895bd7-q99xh Total loading time: 0 Render date: 2024-12-26T06:49:41.709Z Has data issue: false hasContentIssue false

Causal effects of dietary habits on COVID-19 susceptibility, hospitalisation and severity: a comprehensive Mendelian randomisation study

Published online by Cambridge University Press:  06 November 2023

Xiaoping Li
Affiliation:
Department of Respiratory and Critical Care Medicine, Yantai Yuhuangding Hospital, Yantai, Shandong 264000, People’s Republic of China
Ningning Wang
Affiliation:
Department of Hematology, Yantai Yuhuangding Hospital, Yantai, Shandong, People’s Republic of China
Congjie Wang
Affiliation:
Department of Respiratory and Critical Care Medicine, Yantai Yuhuangding Hospital, Yantai, Shandong 264000, People’s Republic of China
Xiaoqing Chen
Affiliation:
Department of Respiratory and Critical Care Medicine, Yantai Yuhuangding Hospital, Yantai, Shandong 264000, People’s Republic of China
Sai Chen*
Affiliation:
Department of General Practice, Yantai Yuhuangding Hospital, Yantai, Shandong, People’s Republic of China
Wei Jiang*
Affiliation:
Department of Respiratory and Critical Care Medicine, Yantai Yuhuangding Hospital, Yantai, Shandong 264000, People’s Republic of China
*
*Corresponding authors: Sai Chen, email directscience@163.com; Wei Jiang, email jiangwei85@yeah.net
*Corresponding authors: Sai Chen, email directscience@163.com; Wei Jiang, email jiangwei85@yeah.net
Rights & Permissions [Opens in a new window]

Abstract

This study aimed to investigate the causal effect of dietary habits on COVID-19 susceptibility, hospitalisation and severity. We used data from a large-scale diet dataset and the COVID-19 Host Genetics Initiative to estimate causal relationships using Mendelian randomisation. The inverse variance weighted (IVW) method was used as the main analysis. For COVID-19 susceptibility, IVW estimates indicated that milk (OR: 0·82; 95 % CI (0·68, 0·98); P = 0·032), unsalted peanut (OR: 0·53; 95 % CI (0·35, 0·82); P = 0·004), beef (OR: 0·59; 95 % CI (0·41, 0·84); P = 0·004), pork (OR: 0·63; 95 % CI (0·42, 0·93); P = 0·022) and processed meat (OR: 0·76; 95 % CI (0·63, 0·92); P = 0·005) were causally associated with reduced COVID-19 susceptibility, while coffee (OR: 1·23; 95 % CI (1·04, 1·45); P = 0·017) and tea (OR: 1·17; 95 % CI (1·05, 1·31); P = 0·006) were causally associated with increased risk. For COVID-19 hospitalisation, beef (OR: 0·51; 95 % CI (0·26, 0·98); P = 0·042) showed negative correlations, while tea (OR: 1·54; 95 % CI (1·16, 2·04); P = 0·003), dried fruit (OR: 2·08; 95 % CI (1·37, 3·15); P = 0·001) and red wine (OR: 2·35; 95 % CI (1·29, 4·27); P = 0·005) showed positive correlations. For COVID-19 severity, coffee (OR: 2·16; 95 % CI (1·25, 3·76); P = 0·006), dried fruit (OR: 1·98; 95 % CI (1·16, 3·37); P = 0·012) and red wine (OR: 2·84; 95 % CI (1·21, 6·68); P = 0·017) showed an increased risk. These findings were confirmed to be robust through sensitivity analyses. Our findings established a causal relationship between dietary habits and COVID-19 susceptibility, hospitalisation and severity.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2023. Published by Cambridge University Press on behalf of The Nutrition Society

The emergence of the COVID-19 pandemic, caused by the severe acute respiratory syndrome coronavirus 2, has resulted in a devastating impact, with over seven million fatalities reported worldwide(Reference Guan, Ni and Hu1,Reference Wang, Hu and Hu2) . Despite vaccines being the most effective strategy against the pandemic, their efficacy has been unsatisfactory due to mutations in the severe acute respiratory syndrome coronavirus 2 virus, including the Omicron variant(Reference Kelly, Le Rutte and Richter3,Reference Sinha, Ajayababu and Thukral4,Reference Surendranath, Wankhedkar and Lele5) . Thus, it is essential to identify potentially causal factors that can effectively mitigate the risk of COVID-19. This identification is critical for enhancing infection prevention measures and optimising disease management strategies.

Numerous observational studies have reported an association between dietary behaviours and the risk of COVID-19 or influenza. For instance, Vu et al. discovered that in the UK Biobank (UKB) cohort, consuming coffee, tea, fish and fruit independently was associated with a decreased risk of future pneumonia or influenza events. On the other hand, consuming red meat was correlated with an increased risk(Reference Vu, Van Horn and Achenbach6). Additionally, they also reported that higher consumption of coffee and vegetables, being breastfed and reducing intake of processed meat were associated with a reduced risk of COVID-19 infection(Reference Vu, Rydland and Achenbach7). However, it is important to acknowledge that the existing observational studies have not been able to establish a causal effect between diet and COVID-19 due to the presence of confounding variables and the inherent limitations. Therefore, it is imperative to highlight the necessity for more rigorous study designs that can effectively investigate the potential causal impact of diet on COVID-19.

Mendelian randomisation (MR) is a widely used method in epidemiology and genetics research to investigate causal relationships between modifiable risk factors and the incidence of outcomes(Reference Sekula, Del Greco and Pattaro8,Reference Ference, Holmes and Smith9) . This approach employs genetic variants that are known to be linked with the risk factor of interest as instrumental variables (IV) to establish causality. Based on the principles of Mendelian genetics, where genetic variants are randomly assigned at conception and unaffected by environmental factors or reverse causation, MR provides a robust framework for assessing causality(Reference Davies, Holmes and Davey Smith10). By utilising genetic variants as IV, MR offers stronger evidence for causality compared with traditional observational studies, which are susceptible to confounding and reverse causation(Reference Ference11).

Given the current dearth of evidence regarding the causal relationship between dietary habits and COVID-19, the purpose of this study was to examine the potential causal effect of twenty-six dietary habits on COVID-19 susceptibility, hospitalisation and severity, employing the MR method.

Materials and methods

Study design

The study design is presented in Fig. 1. A two-sample MR approach was employed to evaluate the potential causal relationship between dietary habits and COVID-19 susceptibility, hospitalisation and severity. First, they should exhibit an association with the risk factor under investigation, which in this instance pertains to dietary behaviour. Second, these genetic variants should not be correlated with any confounding factors influencing the relationship between the risk factor and the outcomes of interest, namely COVID-19 susceptibility, hospitalisation and severity. Lastly, the genetic variant’s impact on the outcomes should solely occur through its influence on the risk factor, without involvement in any other pathways, a concept known as pleiotropy.

Fig. 1. Study design. GWAS, genome-wide association study; MR, Mendelian randomisation; IV, instrumental variable.

The analysis presented in this study is a secondary analysis of publicly available data, and no new studies involving human or animal subjects were conducted. All genome-wide association study (GWAS) datasets utilised in this study were openly accessible in the public domain, thereby eliminating the need for individual ethical approval or informed consent. Moreover, the study’s findings were reported in accordance with the Strengthening the Reporting of Observational Studies in Epidemiology Using Mendelian Randomisation guidelines from 2021(Reference Skrivankova, Richmond and Woolf12).

Genome-wide association study summary statistics data for dietary habits

The present study obtained GWAS data of dietary intake from a cohort of approximately 500 000 individuals aged 40–69 years between 2006 and 2010 in the UKB(Reference Bycroft, Freeman and Petkova13). Within the UKB, information on dietary habits was retrospectively collected during the baseline assessment through a concise food frequency touchscreen questionnaire. The original list encompassed twenty-six dietary intakes, with corresponding sample sizes, including milk intake (n 64 949), yogurt intake (n 64 949), salted peanuts intake (n 64 949), unsalted peanuts intake (n 64 949), salted nuts intake (n 64 949), unsalted nuts intake (n 64 949), coffee intake (n 428 860), tea intake (n 447 485), cheese intake (n 451 486), cereal intake (n 441 640), bread intake (n 452 236), oily fish intake (n 460 443), non-oily fish intake (n 460 880), beef intake (n 461 053), lamb intake (n 460 006), pork intake (n 460 162), bacon intake (n 64 949), processed meat intake (n 461 981), cooked vegetable intake (n 448 651), raw vegetable intake (n 435 435), fresh fruit intake (n 446 462), dried fruit intake (n 421 764), red wine intake (n 327 026), beer intake (n 327 634), SFA (n 114 999) and PUFA (n 114 999). The dataset for each dietary pattern consisted of integer variables, such as the average daily consumption of coffee in cups, and categorical variables indicating the frequency of poultry consumption (online Supplementary Table S1). To ensure the quality and reliability of the data, any unreasonable responses were excluded during the data submission process. Additionally, the dietary habit assessment questions and detailed definitions of measurement units (e.g. tablespoons or cups) utilised in this study can be accessed through the UKB website (https://biobank.ctsu.ox.ac./crystal/label.cgi?id=100052uk (accessed on 17 October 2023) and https://biobank.ctsu.ox.ac./crystal/field.cgi?id=1558uk (accessed on 17 October 2023)). The GWAS summary statistics of dietary intake were derived from individuals of European descent (Table 1).

Table 1. Characteristics of the summary datasets for this study

Genome-wide association study summary statistics data for COVID-19

This study analysed GWAS summary statistics for COVID-19 susceptibility, hospitalisation and severity obtained from Round 7 of the COVID-19 Host Genetic Initiative dataset(Reference Initiative14) (https://www.covid19hg.org/results/r7/). The COVID-19 susceptibility trait was defined as ‘positive v. negative’ and included 122 616 COVID-19-positive cases and 2 475 240 COVID-19-negative controls. The COVID-19 hospitalisation trait was defined as ‘hospitalised positive v. non-hospitalised positive’ and included 32 519 hospitalised COVID-19-positive cases and 2 062 805 non-hospitalised COVID-19-positive cases. The COVID-19 severity trait was defined as ‘severe positive v. non-severe positive’ and included 13 769 severe COVID-19-positive cases and 1 072 442 non-severe COVID-19-positive controls. The details of each definition for the three COVID-19 traits are listed in online Supplementary Table S2. These GWAS summary statistics were collected exclusively from individuals of European descent, except for those who participated in the UKB study (Table 1).

Selection of instrumental variables

We selected IV according to the following criteria: (1) SNP at the genome-wide significance level (P < 5 × 10−8). However, since milk, yogurt, salted nuts, unsalted nuts, salted peanuts and unsalted peanuts had fewer than 5 SNP that met the genome-wide significance (P < 5 × 10−8), we utilised a relaxed threshold (P < 1 × 10−5) to select SNP for these diets. (2) We only selected SNP with no significant linkage disequilibrium (R 2 < 0·01, kb > 5000). (3) SNP with a minimum allele frequency ≥ 0·05 were included, while those with a lower frequency were excluded due to their unstable association with dietary intake. (4) We also excluded SNP that had a significant association with the outcome of interest (P < 5 × 10−8). (5) Finally, we evaluated the F statistics of SNP, and only those with F statistics > 10 were included in the analysis. Here, we defined ‘F statistics’ as the product of the variance of exposure explained by IV, represented by R 2, and the scaling factor of (n-2)/(1-R 2), where N denotes the sample size. Detailed information on the SNP used in the analysis can be found in online Supplementary Table S3.

Mendelian randomisation analysis

The primary analysis employed in this study was the random effect inverse variance weighted (IVW) method, a widely used approach known for generating reliable causal estimates even in the absence of directional pleiotropy. To complement the MR results, we also utilised other four methods, such as the MR-Egger, weighted median, simple mode and weighted mode. MR-Egger regression can identify directional pleiotropy, which occurs when the genetic instrument affects the outcome through a pathway that is independent of the exposure(Reference Bowden, Davey Smith and Burgess15,Reference Bowden, Del Greco and Minelli16) . Weighted median is a robust approach that can provide consistent causal estimates even if up to 50 % of the genetic instruments are invalid(Reference Burgess and Thompson17). Simple mode estimates the causal effect of the exposure on the outcome by taking the mode of the estimated causal effects from each individual IV. Weighted mode is an extension of the simple mode method that weights each IV by the inverse of its variance(Reference Hartwig, Davey Smith and Bowden18). Using multiple methods can provide a more comprehensive understanding of the causal effect between dietary habits and the susceptibility, hospitalisation and severity of COVID-19.

Sensitivity analysis

For the IVW analysis, we utilised the I 2 index and Cochran’s Q statistic to assess the heterogeneity of the effects of SNP related to twenty-six dietary habits on COVID-19 susceptibility, hospitalisation and severity. A P value greater than 0·05 indicated no heterogeneity. Meanwhile, to detect potential pleiotropy and evaluate its impact on the risk estimation, we employed MR regression intercept test and calculated the Rucker’s Q statistic. A P value greater than 0·05 indicated no pleiotropy.

Statistical analyses

We estimated the causal effect of dietary habits on COVID-19 susceptibility, hospitalisation and severity using the OR and a 95 % CI. To correct for multiple testing, we applied the Bonferroni correction with a threshold of 0·0019 (0·05/26) to control the false discovery rate. An association with a nominal P value less than 0·05 but greater than 0·0019 was considered suggestive, and an association with a P value less than 0·0019 was deemed significant. We conducted all statistical analyses using R software (version 4.2.1) and employed the ‘TwoSampleMR’ package to perform the IVW, MR-Egger regression, weighted median, simple mode and weighted mode methods.

Results

Genetic instrumental variables for dietary habits

We selected 19 SNP for milk, 6 SNP for yogurt, 7 SNP for salted peanuts, 22 SNP for unsalted peanuts, 11 SNP for salted nuts, 13 SNP for unsalted nuts, 26 SNP for coffee, 35 SNP for tea, 47 SNP for cheese, 25 SNP for cereal, 24 SNP for bread, 47 SNP for oily fish, 7 SNP for non-oily fish, 8 SNP for beef, 21 SNP for lamb, 8 SNP for pork, 8 SNP for bacon, 15 SNP for processed meat, 10 SNP for cooked vegetables, 8 SNP for raw vegetables, 32 SNP for fresh fruit, 30 SNP for dried fruit, 10 SNP for red wine, 11 SNP for beer, 26 SNP for SFA and 42 SNP for PUFA as the IV. The F-statistic for each genetic variant exceeded 10, which avoids weak instrument bias. The details of each genetic variant for the twenty-six dietary habits are listed in online Supplementary Table S3.

The causal effect between dietary habits and COVID-19 susceptibility

Fig. 2 illustrates the MR estimates obtained from the IVW method, depicting the causal effect of twenty-six dietary habits on COVID-19 susceptibility. Our findings showed that milk intake (OR: 0·82, 95 % CI (0·68, 0·98), P = 0·032), unsalted peanuts intake (OR: 0·53, 95 % CI (0·35, 0·82), P = 0·004), beef intake (OR: 0·59, 95 % CI (0·41, 0·84), P = 0·004), pork intake (OR: 0·63, 95 % CI (0·42, 0·93), P = 0·022) and processed meat intake (OR: 0·76, 95 % CI (0·63, 0·92), P = 0·005) were suggestively associated with a lower risk of COVID-19 susceptibility, while coffee intake (OR: 1·23, 95 % CI (1·04, 1·45), P = 0·017) and tea intake (OR: 1·17, 95 % CI (1·05, 1·31), P = 0·006) were suggestively associated with a higher risk. The results from the other four methods were consistent with these findings, as shown in online Supplementary Table S4.

Fig. 2. Causal effect of dietary habits on COVID-19 susceptibility: MR estimates from IVW method. MR, Mendelian randomisation; IVW, inverse variance weighted.

The causal effect between dietary habits and COVID-19 hospitalisation

Fig. 3 displays the MR estimates obtained from the IVW method, depicting the causal effect of twenty-six dietary habits on COVID-19 hospitalisation. Our findings showed that beef intake (OR: 0·51, 95 % CI (0·26, 0·98), P = 0·042) was suggestively associated with a lower risk of COVID-19 hospitalisation, while tea intake (OR: 1·54, 95 % CI (1·16, 2·04), P = 0·003), dried fruit intake (OR: 2·08, 95 % CI (1·37, 3·15), P = 0·001) and red wine intake (OR: 2·35, 95 % CI (1·29, 4·27), P = 0·005) were associated with a higher risk. The results from the other four methods were consistent with these findings, as shown in online Supplementary Table S5.

Fig. 3. Causal effect of dietary habits on COVID-19 hospitalisation: MR estimates from IVW method. MR, Mendelian randomisation; IVW, inverse variance weighted.

The causal effect between dietary habits and COVID-19 severity

Fig. 4 depicts the MR estimates obtained from the IVW method, showing the causal effect of twenty-six dietary habits on COVID-19 severity. Our findings showed that coffee intake (OR: 2·16, 95 % CI (1·25, 3·76), P = 0·006), dried fruit intake (OR: 1·98, 95 % CI (1·16, 3·37), P = 0·012) and red wine intake (OR: 2·84, 95 % CI (1·21, 6·68), P = 0·017) were suggestively associated with a higher risk of COVID-19 severity. The results from the other four methods were consistent with these findings, as shown in online Supplementary Table S6.

Fig. 4. Causal effect of dietary habits on COVID-19 severity: MR estimates from IVW method. MR, Mendelian randomisation; IVW, inverse variance weighted.

Sensitivity analysis

Online Supplementary Tables S7–S9 present the results of the MR-Egger intercept test and MR-Egger regression, which can identify unmeasured pleiotropy and generate estimates while accounting for horizontal pleiotropy, respectively. Despite the presence of heterogeneity in certain findings, we persisted in using the IVW method as the primary analytical method due to its efficacy in controlling pooled heterogeneity. Additionally, the MR-Egger intercept test did not identify any horizontal pleiotropy that could have influenced the MR results.

Discussion

To the best of our knowledge, this is the first study to investigate the causal effect between dietary habits and the susceptibility, hospitalisation and severity of COVID-19. In the current study, we have established a causal relationship between certain dietary habits and the risk of COVID-19 susceptibility, hospitalisation and severity. Our results suggested that consuming milk, unsalted peanuts, beef, pork, processed meat, coffee and tea had a causal effect on the risk of COVID-19 susceptibility. Additionally, the consumption of beef, tea, dried fruit and red wine had a causal effect on the risk of COVID-19 hospitalisation. Finally, the consumption of coffee, dried fruit and red wine may be causally linked with a higher risk of COVID-19 severity. Overall, our findings emphasise the need for a comprehensive approach to COVID-19 prevention that includes lifestyle modifications, such as dietary changes.

Beef is a good source of protein and essential nutrients such as Fe and Zn, which are important for maintaining a healthy immune system(Reference Lau, Fulgoni and Van Elswyk19). The causal relationship observed between beef intake and COVID-19 hospitalisation risk may be due to a number of factors, including the nutritional content of beef and its potential effects on the immune system or underlying health conditions(Reference Myers, Jaros and Andersen20). For example, previous studies have suggested that certain nutrients in beef, such as Zn and vitamin B12, may have a beneficial effect on the immune system, potentially reducing the risk of viral infections(Reference Xu, Wang and Zhao21,Reference Fan, Wang and Wu22,Reference Cassiano, Cavalcante-Silva and Oliveira23) . Further research is needed to fully understand the mechanisms underlying this relationship.

The study found that coffee intake was causally associated with an increased risk of COVID-19 susceptibility and severity. However, the mechanisms by which coffee intake could affect COVID-19 outcomes are not entirely clear. One possibility is that caffeine, which is found in both tea and coffee, may have adverse effects on the immune system and contribute to inflammation(Reference Sepkowitz24,Reference Kanginakudru, Gilson and Jose25) . Caffeine has been shown to increase the release of cortisol, a stress hormone that can suppress immune function and increase inflammation. Another possible explanation is that tea and coffee intake may be associated with other lifestyle factors or underlying health conditions that increase the risk of severe COVID-19 outcomes(Reference Chen, Chen and Fang26). For example, people who consume large amounts of tea or coffee may have a higher overall intake of caffeine, which can disrupt sleep patterns, increase stress levels and contribute to the development of chronic health conditions such as diabetes and CVD(Reference Meneo, Bacaro and Curati27,Reference Frosztega, Wieckiewicz and Nowacki28) .

The study revealed a causal association between red wine consumption and an elevated risk of COVID-19 hospitalisation and severity. However, the potential explanations for this relationship may be related to the compounds present in red wine. Alcohol consumption, including red wine, has been linked to various health conditions, such as liver disease, cancer and CVD, which can heighten the risk of developing severe COVID-19 complications and hospitalisation(Reference Campane, Nucci and Nishiyama29,Reference Haunschild and Marx30) . Furthermore, excessive red wine consumption could detrimentally affect the immune system and overall health, potentially increasing the susceptibility to viral infections and severe COVID-19 outcomes(Reference Tu, Gallagher and Elliott31,Reference Dai, Tan and Ren32) . It is important to note that the study did not investigate the specific mechanisms underlying the impact of red wine intake on COVID-19 hospitalisation and severity. Therefore, further research is necessary to comprehensively understand the underlying mechanisms of this association.

The present study has several notable strengths. First, the use of a MR design allowed for the investigation of causal relationships between dietary habits and COVID-19 outcomes, thereby mitigating potential confounding factors that can affect observational studies. Second, a large and diverse sample of over 500 000 individuals was analysed, providing robust statistical power for the analysis. Third, a comprehensive dietary assessment tool was employed to capture a wide range of dietary habits, including food and beverage intake. Last, the study examined the relationship between dietary habits and three distinct COVID-19 outcomes, namely susceptibility, hospitalisation and severity, thereby offering a more comprehensive understanding of the potential impact of dietary habits on COVID-19 outcomes. Overall, these strengths increase confidence in the causal relationships between certain dietary habits and COVID-19 outcomes identified in the study.

However, our study is not without limitations. First, the use of self-reported dietary data is subject to recall bias and measurement error, and the study did not account for changes in dietary habits during the study period. Second, the sample consisted primarily of individuals of European descent, which may restrict the generalisability of the findings to other populations. Third, the study was limited to three COVID-19 outcomes, namely susceptibility, hospitalisation and severity, and did not investigate other important outcomes such as mortality and long-term complications. Fourth, the study did not account for potential confounding factors such as social determinants of health and healthcare access that may influence COVID-19 outcomes. Fifth, it is important to acknowledge that there exist overlapping sets of participants among the twenty-six dietary habits. However, a study by Minelli et al. (Reference Minelli, Del Greco and van der Plaat33) demonstrated that the majority of two-sample methods can be applied safely in the context of one-sample MR studies with a substantial sample size. Taken together, caution is advised when interpreting the findings of the study, and further research is warranted to validate our findings and explore the underlying mechanisms.

Conclusions

Our findings established a causal relationship between certain dietary habits and COVID-19 susceptibility, hospitalisation and severity, highlighting the importance of maintaining a healthy diet to reduce the risk of COVID-19.

Acknowledgements

We would like to give special thanks to the investigators, workers and participants of GWAS summary statistics data for dietary habits and COVID-19 for their contributions to the realisation of this research.

This research received no specific grant from any funding agency, commercial or not-for-profit sectors.

Conceptualisation: X. L., N. W., S. C. and W. J.; formal analysis and original draft preparation, X. L.; data preparation: N. W., C. W. and X. C.; review and editing, and interpretation of data: X. L., N. W., C. W., X. C., S. C. and W. J. All authors contributed to interpretation of the results, preparation and review of the manuscript and approval of the final manuscript for publication.

The authors declare that they have no competing interests in this study.

Supplementary material

For supplementary material referred to in this article, please visit https://doi.org/10.1017/S0007114523002556

Footnotes

These authors contributed equally to this work and share first authorship.

References

Guan, WJ, Ni, ZY, Hu, Y, et al. (2020) Clinical characteristics of coronavirus disease 2019 in China. N Engl J Med 382, 17081720.CrossRefGoogle ScholarPubMed
Wang, D, Hu, B, Hu, C, et al. (2020) Clinical characteristics of 138 hospitalized patients with 2019 novel coronavirus-infected pneumonia in Wuhan, China. JAMA 323, 10611069.CrossRefGoogle ScholarPubMed
Kelly, SL, Le Rutte, EA, Richter, M, et al. (2022) COVID-19 vaccine booster strategies in light of emerging viral variants: frequency, timing, and target groups. Infect Dis Ther 11, 20452061.CrossRefGoogle ScholarPubMed
Sinha, S, Ajayababu, A, Thukral, H, et al. (2022) Efficacy of Bacillus Calmette-Guerin (BCG) vaccination in reducing the incidence and severity of COVID-19 in high-risk population (BRIC): a Phase III, multi-centre, quadruple-blind randomised control trial. Infect Dis Ther 11, 22052217.CrossRefGoogle ScholarPubMed
Surendranath, M, Wankhedkar, R, Lele, J, et al. (2022) A modern perspective on vaccinating healthcare service providers in India: a narrative review. Infect Dis Ther 11, 8199.CrossRefGoogle ScholarPubMed
Vu, TT, Van Horn, L, Achenbach, CJ, et al. (2022) Diet and respiratory infections: specific or generalized associations? Nutrients 14, 1195.CrossRefGoogle ScholarPubMed
Vu, TT, Rydland, KJ, Achenbach, CJ, et al. (2021) Dietary behaviors and incident COVID-19 in the UK Biobank. Nutrients 13, 2114.CrossRefGoogle ScholarPubMed
Sekula, P, Del Greco, MF, Pattaro, C, et al. (2016) Mendelian randomization as an approach to assess causality using observational data. J Am Soc Nephrol 27, 32533265.CrossRefGoogle ScholarPubMed
Ference, BA, Holmes, MV & Smith, GD (2021) Using Mendelian randomization to improve the design of randomized trials. Cold Spring Harb Perspect Med 11, a040980.CrossRefGoogle ScholarPubMed
Davies, NM, Holmes, MV & Davey Smith, G (2018) Reading Mendelian randomisation studies: a guide, glossary, and checklist for clinicians. BMJ 362, k601.CrossRefGoogle ScholarPubMed
Ference, BA (2015) Mendelian randomization studies: using naturally randomized genetic data to fill evidence gaps. Curr Opin Lipidol 26, 566571.CrossRefGoogle ScholarPubMed
Skrivankova, VW, Richmond, RC, Woolf, BAR, et al. (2021) Strengthening the reporting of observational studies in epidemiology using Mendelian randomisation (STROBE-MR): explanation and elaboration. BMJ 375, n2233.CrossRefGoogle ScholarPubMed
Bycroft, C, Freeman, C, Petkova, D, et al. (2018) The UK Biobank resource with deep phenotyping and genomic data. Nature 562, 203209.CrossRefGoogle ScholarPubMed
Initiative, C-HG (2020) The COVID-19 Host Genetics Initiative, a global initiative to elucidate the role of host genetic factors in susceptibility and severity of the SARS-CoV-2 virus pandemic. Eur J Hum Genet 28, 715718.CrossRefGoogle Scholar
Bowden, J, Davey Smith, G & Burgess, S (2015) Mendelian randomization with invalid instruments: effect estimation and bias detection through Egger regression. Int J Epidemiol 44, 512525.CrossRefGoogle ScholarPubMed
Bowden, J, Del Greco, MF, Minelli, C, et al. (2016) Assessing the suitability of summary data for two-sample Mendelian randomization analyses using MR-Egger regression: the role of the I2 statistic. Int J Epidemiol 45, 19611974.Google ScholarPubMed
Burgess, S & Thompson, SG (2017) Interpreting findings from Mendelian randomization using the MR-Egger method. Eur J Epidemiol 32, 377389.CrossRefGoogle ScholarPubMed
Hartwig, FP, Davey Smith, G & Bowden, J (2017) Robust inference in summary data Mendelian randomization via the zero modal pleiotropy assumption. Int J Epidemiol 46, 19851998.CrossRefGoogle ScholarPubMed
Lau, CS, Fulgoni, VL 3rd, Van Elswyk, ME, et al. (2023) Trends in beef intake in the United States: analysis of the national health and nutrition examination survey, 2001–2018. Nutrients 15, 2475.CrossRefGoogle ScholarPubMed
Myers, GM, Jaros, KA, Andersen, DS, et al. (2023) Nutrient recovery in cultured meat systems: impacts on cost and sustainability metrics. Front Nutr 10, 1151801.CrossRefGoogle ScholarPubMed
Xu, S, Wang, D, Zhao, W, et al. (2023) Non-negligible role of trace elements in influenza virus infection. Metabolites 13, 184.CrossRefGoogle ScholarPubMed
Fan, S, Wang, H, Wu, D, et al. (2023) Pharmaceutical approaches for COVID-19: an update on current therapeutic opportunities. Acta Pharm 73, 157173.CrossRefGoogle ScholarPubMed
Cassiano, LMG, Cavalcante-Silva, V, Oliveira, MS, et al. (2023) Vitamin B12 attenuates leukocyte inflammatory signature in COVID-19 via methyl-dependent changes in epigenetic markings. Front Immunol 14, 1048790.CrossRefGoogle ScholarPubMed
Sepkowitz, KA (2013) Energy drinks and caffeine-related adverse effects. JAMA 309, 243244.CrossRefGoogle ScholarPubMed
Kanginakudru, S, Gilson, T, Jose, L, et al. (2022) Effects of caffeine, a DNA damage response inhibitor, on papillomavirus genome replication. Pathogens 11, 1298.CrossRefGoogle ScholarPubMed
Chen, TT, Chen, CY, Fang, CP, et al. (2022) Causal influence of dietary habits on the risk of major depressive disorder: a diet-wide Mendelian randomization analysis. J Affect Disord 319, 482489.CrossRefGoogle ScholarPubMed
Meneo, D, Bacaro, V, Curati, S, et al. (2023) A systematic review and meta-analysis of the association between young adults’ sleep habits and substance use, with a focus on self-medication behaviours. Sleep Med Rev 70, 101792.CrossRefGoogle ScholarPubMed
Frosztega, W, Wieckiewicz, M, Nowacki, D, et al. (2023) The effect of coffee and black tea consumption on sleep bruxism intensity based on polysomnographic examination. Heliyon 9, e16212.CrossRefGoogle ScholarPubMed
Campane, LZ, Nucci, MP, Nishiyama, M, et al. (2022) Long term effects of red wine consumption in brain: an MRI, fMRI and neuropsychological evaluation study. Nutr Neurosci 26, 112.Google Scholar
Haunschild, R & Marx, W (2022) On health effects of resveratrol in wine. Int J Environ Res Public Health 19, 3110.CrossRefGoogle ScholarPubMed
Tu, SJ, Gallagher, C, Elliott, AD, et al. (2022) Alcohol intake and bradyarrhythmia risk: a cohort study of 407 948 individuals. Europace 24, 14691474.CrossRefGoogle Scholar
Dai, XJ, Tan, L, Ren, L, et al. (2021) COVID-19 risk appears to vary across different alcoholic beverages. Front Nutr 8, 772700.CrossRefGoogle ScholarPubMed
Minelli, C, Del Greco, MF, van der Plaat, DA, et al. (2021) The use of two-sample methods for Mendelian randomization analyses on single large datasets. Int J Epidemiol 50, 16511659.CrossRefGoogle ScholarPubMed
Figure 0

Fig. 1. Study design. GWAS, genome-wide association study; MR, Mendelian randomisation; IV, instrumental variable.

Figure 1

Table 1. Characteristics of the summary datasets for this study

Figure 2

Fig. 2. Causal effect of dietary habits on COVID-19 susceptibility: MR estimates from IVW method. MR, Mendelian randomisation; IVW, inverse variance weighted.

Figure 3

Fig. 3. Causal effect of dietary habits on COVID-19 hospitalisation: MR estimates from IVW method. MR, Mendelian randomisation; IVW, inverse variance weighted.

Figure 4

Fig. 4. Causal effect of dietary habits on COVID-19 severity: MR estimates from IVW method. MR, Mendelian randomisation; IVW, inverse variance weighted.

Supplementary material: File

Li et al. supplementary material

Li et al. supplementary material
Download Li et al. supplementary material(File)
File 171.7 KB