Het Vit D - onderzoek dat behoorlijk bersproken wordt en nu zelfs de MSM haalt, her en der: zie onder.
Maar er zijn al meer dan 6 maanden lang enorm overtuigende berichten over de invloed van Vitamine D.
Ze werden met alle geweld weg gedrukt. Een andere verklaring kan ik er niet voor bedenken.
Hier een onderzoek uit dePhilipijnen dat begin april is gepubliceeerd.
De afbeelding ( grafiek) zegt alles, maar ik kan hem alleen tonen in een video: Minuut 3.35 . Als U de video stil zet ziet U: groen zijn de mensen die meer dan 30 nanogram vit D inhun bloed hadden. Bij heb verloopt de ziekte mild.
Rood zijn de mensen die heel weinig Vit D in hun bloed hadden: bijna allemaal worden ze ernstig ziek van Corona.
Dan nu het recente onderzoek:
Artsen geven soms aan oudjes in het verpleeghuis
een injectie met 80.000 units vitamine D, in één keer. ( een 'bolus').
Welnu: oudjes die zo'n injectie kregen, een week voor ze Corona kregen, of zelfs na enkele dagen Corona te hebben, DIE oudjes hadden 89% minder kans om dood te gaan door de ziekte.
The Journal of Steroid Biochemistry and Molecular Biology
Vitamin D and survival in COVID-19 patients: A quasi-experimental study
Keywords
1. INTRODUCTION
Since December 2019, the COVID-19 caused by SARS-CoV-2 is spreading worldwide from China, affecting millions of people and leaving thousands of dead, mostly in older adults. With the lack of effective therapy, chemoprevention and vaccination [1], focusing on the immediate repurposing of existing drugs gives hope of curbing the pandemic. Importantly, a most recent genomics-guided tracing of the SARS-CoV-2 targets in human cells identified vitamin D among the three top-scoring molecules manifesting potential infection mitigation patterns through their effects on gene expression [2]. In particular, by activating or repressing several genes in the promoter region of which it binds to the vitamin D response element [3], vitamin D may theoretically prevent or improve COVID-19 adverse outcomes by regulating (i) the renin-angiotensin system (RAS), (ii) the innate and adaptive cellular immunity, and (iii) the physical barriers [4]. Consistently, epidemiology shows that hypovitaminosis D is more common from October to March at northern latitudes above 20 degrees [3], which corresponds precisely to the latitudes with the highest lethality rates of COVID-19 during the first months of winter 2020 [1]. In line with this, significant inverse associations were found in 20 European countries between serum 25-hydroxyvitamin D (25(OH)D) concentration and the number of COVID-19 cases, as well as with COVID-19 mortality [5]. This suggests that increasing serum 25(OH)D concentration may improve the prognosis of COVID-19. However, no randomized controlled trial (RCT) has tested the effect of vitamin D supplements on COVID-19 outcomes yet. We had the opportunity to examine the association between the use of vitamin D3 supplements and COVID-19 mortality in a sample of frail elderly nursing-home residents infected with SARS-CoV-2. The main objective of this quasi-experimental study was to determine whether bolus vitamin D3 supplementation taken during or just before COVID-19 was effective in improving survival among frail elderly COVID-19 patients living in nursing-home. The secondary objective was to determine whether this intervention was effective in limiting the clinical severity of the infection.
2. MATERIAL AND METHODS
2.1. Study population
The study consisted in a quasi-experimental study in a middle-sized nursing-home in Rhône, South-East of France, the residents of which were largely affected by COVID-19 in March- April 2020 (N = 96, including n = 66 with COVID-19). Data were retrospectively collected from the residents’ records of the nursing-home.
The nursing-home is dedicated to residents with physical disabilities, major neurocognitive and psychiatric disorders. The facility includes 56 single rooms and 21 double rooms, along with communal dining and activity areas. There are no closed units. All residents were allowed to move around the building until 21 March 2020, when social distancing and other preventive measures were implemented. Residents were isolated in their rooms with no communal meals or group activities. No visitors, including families, were allowed in the nursing-home since 10 March 2020. Enhanced hygiene measures were implemented, including cleaning and disinfection of frequently touched surfaces, permanent face masks, and additional hand hygiene stations for staff members.
The inclusion criteria for the present analysis were as follows: 1) residents with clinically obvious or diagnosed COVID-19 with RT-PCR in March-April 2020; 2) data available on the treatments received, including vitamin D supplementation, since the diagnosis of COVID-19 and during the previous month at least; 3) data available on the vital status and COVID-19 evolution as of May 15, 2020; 4) no objection from the resident and/or relatives to the use of anonymized clinical and biological data for research purposes. Sixty-six residents had COVID-19 during the study period. They all met the other inclusion criteria and were included in the present analysis.
2.2. Intervention: bolus vitamin D3 supplementation during or just before COVID-19
All residents in the nursing-home receive chronic vitamin D supplementation with regular maintenance boluses (single oral dose of 80,000 IU vitamin D3 every 2-3 months), without systematically performing serum control test as recommended in French nursing-homes [6] due to the very high prevalence of hypovitaminosis D reaching 90-100% in this population [7]. Here, the "Intervention group" was defined as all COVID-19 residents who received an oral bolus of 80,000 IU vitamin D3 either in the week following the suspicion or diagnosis of COVID-19, or during the previous month. The "Comparator group" corresponded to all other COVID-19 residents who did not receive any recent vitamin D supplementation. None received D2 or intramuscular supplements. All medications were dispended and supervised by a nurse.
2.3. Primary outcome: COVID-19 mortality
The primary outcome was mortality of COVID-19 residents during follow-up. Follow-up started from the day of COVID-19 diagnosis for each patient, and continued until May 15, 2020, or until death if applicable.
2.4. Secondary outcome: OSCI score for COVID-19 in acute phase
The secondary outcome was the score on the World Health Organization’s Ordinal Scale for Clinical Improvement (OSCI) for COVID-19 [8]. The score was calculated by the geriatrician of the nursing-home during the most severe acute phase of COVID-19 for each patient. The OSCI distinguishes between several levels of COVID-19 clinical severity according to the outcomes and dedicated treatments required, with a score ranging from 0 (benign) to 8 (death). A score of 4 corresponds to the introduction of oxygen (nasal oxygen catheter or oral nasal mask), and a score of 6 to intubation and invasive ventilation [8].
2.5. Covariables
Age, gender, number of drugs daily taken, functional abilities, nutritional status, COVID-19 treatment with corticosteroids and/or hydroxychloroquine and/or dedicated antibiotics, and hospitalization for COVID-19 were used as potential confounders. The number of drugs usually taken per day was recovered from prescriptions in the nursing-home and served as a measure of the burden of disease, as previously reported [9]. The use of corticosteroids and/or hydroxychloroquine and/or dedicated antibiotics (i.e., azithromycin or rovamycin) were noted from prescriptions in the nursing-home or during hospitalization, as appropriate. Functional abilities prior to COVID-19 were measured from 1 to 6 (best) with the Iso-Resources Groups (GIR) [10]. Finally, the prognosis related to the nutritional status prior to COVID-19 was evaluated using the last measure of serum albumin concentration during the past semester, as appropriate [11].
2.6. Statistical analysis
Participants’ characteristics were summarized using means and standard deviations (SD) or frequencies and percentages, as appropriate. As the number of observations was higher than 40, comparisons were not affected by the shape of the error distribution and no transform was applied [12]. First, comparisons between participants separated into Intervention and Comparator groups were performed using Mann-Whitney U test or the Chi-square test or Fisher test, as appropriate; and then according to mortality. Secondly, a full-adjusted Cox regression was used to examine the associations of mortality (dependent variable) with bolus vitamin D3 supplements and covariables (independent variables). The model produces a survival function that provides the probability of death at a given time for the characteristics supplied for the independent variables. Third, the elapsed time to death was studied by survival curves computed according to Kaplan-Meier method and compared by log-rank test. Finally, univariate and multiple linear regressions were used to examine the association of bolus vitamin D3 supplementation (independent variable) with OSCI score (dependent variable), while adjusting for potential confounders. P-values<0.05 were considered significant. All statistics were performed using SPSS (v23.0, IBM Corporation, Chicago, IL) and SAS® version 9.4 software (Sas Institute Inc).
2.7. Standard Protocol Approvals, Registrations, and Patient Consents
The study was conducted in accordance with the ethical standards set forth in the Helsinki Declaration (1983). No participant or relatives objected to the use of anonymized clinical and biological data for research purposes. The study was approved by the Ethical Committee of Angers University Hospital (2020/67). The study protocol was also declared to the National Commission for Information Technology and civil Liberties (CNIL).
3. RESULTS
Sixty-six participants (mean ± SD age 87.7 ± 9.0years, range 63-103years; 77.3% women) were infected with SARS-CoV-2 and included in this quasi-experimental study. The mean follow-up was 36 ± 17days. Fifty-one people survived COVID-19, while 15 died. The two groups were comparable at baseline with no significant difference regarding the age (P = 0.699), gender (P = 0.731), the mean number of drugs usually taken per day (P = 0.053), the GIR score (P = 0.209) and the serum albumin concentration (P = 0.263) (Table 1). Regarding care dedicated to COVID-19, only the proportion of patients who received a bolus of vitamin D3 during or just before COVID-19 differed between deceased participants and survivors, with a higher prevalence in survivors (respectively 92.2% versus 66.7%, P = 0.023). In contrast, there was no between-group difference in the proportion of patients treated with corticosteroids, hydroxychloroquine or dedicated antibiotics, or hospitalized for COVID-19.
Table 1. Characteristics and comparison of COVID-19 participants (n = 66) according to the study arm.
| All COVID-19 participants (n = 66) | Study arm | P-value | ||
|---|---|---|---|---|
| Comparator group* (n = 9) | Intervention group* (n = 57) | |||
| Baseline data | ||||
| Age (years), mean ± SD | 87.7 ± 9.0 | 87.4 ± 7.2 | 87.7 ± 9.3 | 0.660 |
| Female gender | 51 (77.3) | 6 (66.7) | 45 (78.9) | 0.414 |
| Number of drugs usually taken per day, mean ± SD | 7 ± 2 | 5 ± 2 | 7 ± 2 | 0.043 |
| GIR score (/6), mean ± SD | 2 ± 1 | 1 ± 0.4 | 2 ± 1 | 0.003 |
| Serum albumin concentration† (g/L), mean ± SD | 34.2 ± 5.2 | 35.4 ± 2.5 | 34.1 ± 5.4 | 0.250 |
| COVID-19 | ||||
| Dedicated treatments | ||||
| Use of corticosteroids | 4 (6.1) | 1 (11.1) | 3 (5.3) | 0.452 |
| Use of hydroxychloroquine | 2 (3.0) | 0 (0.0) | 2 (3.5) | 1.000 |
| Use of dedicated antibiotics | 34 (51.5) | 3 (33.3) | 21 (54.4) | 0.297 |
| Hospitalization for COVID-19 | 4 (6.1) | 0 (0.0) | 4 (7.0) | 1.000 |
| Outcomes | ||||
| OSCI score for COVID-19 in acute phase | 0.133 | |||
| OSCI 0 | 1 (1.5) | 0 (0.0) | 1 (1.8) | |
| OSCI 1 | 22 (33.3) | 1 (11.1) | 21 (37.5) | |
| OSCI 2 | 19 (28.8) | 1 (11.1) | 18 (32.1) | |
| OSCI 3 | 1 (1.5) | 0 (0.0) | 1 (1.8) | |
| OSCI 4 | 5 (7.6) | 1 (11.1) | 4 (7.1) | |
| OSCI 5 | 3 (4.5) | 1 (11.1) | 2 (3.6) | |
| OSCI 6 | 0 (0) | 0 (0) | 0 (0) | |
| OSCI 7 | 0 (0) | 0 (0) | 0 (0) | |
| OSCI 8 | 15 (22.7) | 5 (55.6) | 10 (17.5) | |
| Mortality | 15 (22.7) | 5 (55.6) | 10 (17.5) | 0.023 |
| Follow-up after COVID-19 diagnosis‡ (days), mean ± SD | 36 ± 17 | 20.9 ± 14.3 | 38.9 ± 15.6 | 0.002 |
Data presented as n (%) where applicable; COVID-19: Coronavirus Disease 2019; GIR: Iso Resource Groups; OSCI: Ordinal Scale for Clinical Improvement of the World Health Organization; *: “Intervention group” defined as COVID-19 patients having received a bolus of vitamin D3 supplement during COVID-19 or in the preceding month; †: measured in preceding 6 months; ‡: data were censored at the time of data cutoff (15 May 2020) or until death, as appropriate.
Table 1 indicates the characteristics of participants separated into Intervention (n = 57) and Comparator (n = 9) groups. Their baseline characteristics (age, gender, albuminemia) did not differ between groups, with the exception of the number of drugs usually taken (which involved the use of vitamin D supplements) and the disability score (Table 1). Similarly, the proportion of participants at each OSCI severity level as well as the use of dedicated COVID-19 drugs did not differ between Intervention and Comparator groups. At the end of the follow-up, 82.5% of patients from the Intervention group survived COVID-19, compared to only 44.4% in the Comparator group (P = 0.023).
Fig. 1 shows a statistically significant and clinically relevant protective effect against mortality of bolus vitamin D3 supplementation received during or just before COVID-19. The hazard ratio (HR) for mortality according to vitamin D3 supplementation was 0.21 [95% confidence interval (95%CI): 0.07;0.63] P = 0.005 in the unadjusted model, and HR = 0.11 [95%CI: 0.03;0.48] P = 0.003 after adjustment for all potential confounders. No other covariables were associated with mortality, in particular no other dedicated treatments. Using the season of the COVID-19 diagnosis as an additional potential confounder did not affect the results (data not shown). Consistently, Kaplan-Meier distributions showed in Fig. 2 that the residents who had not recently received vitamin D3 supplements had shorter survival time than those having received vitamin D3 supplementation during or just before COVID-19 (log-rank P = 0.002).
Fig. 1. Hazard ratio for mortality in frail elderly COVID-19 patients according to the use of bolus vitamin D3 supplements during or just before COVID-19, adjusted for potential confounders (n = 66).
CI: confidence interval; COVID-19: Coronavirus Disease 2019; GIR: Iso Resource Groups; *: measured in preceding 6 months.
Fig. 2. Kaplan-Meier estimates of the cumulative probability of participants’ survival according to the use of bolus vitamin D3 supplements during or just before COVID-19 (n = 66).
Finally, the linear regression model illustrated in Table 2 showed that bolus vitamin D3 supplementation during or just before COVID-19 was inversely associated with the OSCI score for COVID-19 in acute phase. Similar results were found before (β=-2.96 [95%CI: -4.79;-1.12], P = 0.002) and after adjusting the analyses for potential confounders (β=-3.84 [95%CI: -6.07;-1.62], P = 0.001).
Table 2. Univariate and multiple linear regressions showing the association of the use of bolus vitamin D3 supplements during or just before COVID-19 (independent variable) with the OSCI score for COVID-19 in acute phase (dependent variable), adjusted for participants' characteristics (n = 66).
| OSCI score for COVID-19 in acute phase | ||||
|---|---|---|---|---|
| Unadjusted model | Full-adjusted model | |||
| Unadjusted β [95% CI] | P-value | Full-adjusted β [95% CI] | P-value | |
| Bolus vitamin D3 supplementation during or just before COVID-19 | -2.96 [-4.79;-1.12] | 0.002 | -3.84 [-6.07;-1.62] | 0.001 |
| Age | 0.02 [-0.05;0.10] | 0.563 | 0.04 [-0.05;0.12] | 0.400 |
| Female gender | -0.13 [-1.76;1.49] | 0.870 | 0.36 [-1.41;2.12] | 0.687 |
| Number of drugs usually taken per day | -0.26 [-0.54;0.02] | 0.070 | -0.18 [-0.51;0.15] | 0.273 |
| GIR score | -0.28 [-0.86;0.30] | 0.333 | 0.21 [-0.48;0.89] | 0.617 |
| Serum albumin concentration* | 0.03 [-0.11;0.17] | 0.647 | -0.001 [-0.15;0.15] | 0.993 |
| Use of corticosteroids | 2.41 [-0.36;5.20] | 0.087 | 3.53 [0.30;6.75] | 0.033 |
| Use of hydroxychloroquine | 1.83 [-2.11;5.76] | 0.357 | 2.49 [-1.59;6.57] | 0.226 |
| Use of dedicated antibiotics | -0.22 [-1.59;1.14] | 0.746 | -0.56 [-2.21;1.10] | 0.503 |
| Hospitalization for COVID-19 | 1.09 [-1.75;3.92] | 0.446 | 0.72 [-2.48;3.93] | 0.652 |
β: coefficient of regression corresponding to a change in OSCI score for COVID-19 in acute phase (/8); CI: confidence interval; COVID-19: Coronavirus Disease 2019; GIR: Iso Resource Groups; OSCI: Ordinal Scale for Clinical Improvement of the World Health Organization; *: measured in preceding 6 months.
4. DISCUSSION
The main finding of this nursing-home-based quasi-experimental study is that, irrespective of all measured potential confounders, bolus vitamin D3 supplementation during or just before COVID-19 was associated with less severe COVID-19 and better survival rate in frail elderly. No other treatment showed protective effect. This novel finding provides a scientific basis for vitamin D replacement trials attempting to improve COVID-19 prognosis.
To our knowledge we provide here the first quasi-experimental data examining the effect of vitamin D supplementation on the survival rate of COVID-19 patients. To date, only rare observational data, all of which are consistent, are available on the link between vitamin D and COVID-19. The first reports in COVID-19 patients indicated that hypovitaminosis D is highly prevalent in this population, reaching 85% [13], and that serum 25(OH)D concentrations are lower in COVID-19 patients compared to controls [14]. Similarly, significant inverse correlations were found in 20 European countries between the mean serum 25(OH)D concentrations and the number of COVID-19 cases/1 M, as well as with mortality/1 M [5]. The severity of hypovitaminosis D appears to relate to the prognosis of COVID-19 since the mortality rate was multiplied by 7.6 among people with hypovitaminosis D <75 nmol/L, and by 10.1 among those with hypovitaminosis D <50 nmol/L (P < 0.001) [15]. Similarly, another observational study in 212 COVID-19 cases showed that, for each standard deviation increase in serum 25(OH)D, the probability of mild rather than severe COVID-19 was multiplied by 7.9 (P < 0.001), while the probability of mild rather than critical COVID-19 was multiplied by 19.6 (P < 0.001) [16]. These results suggest that increasing serum 25(OH)D concentration may improve the prognosis of COVID-19. Interventional studies dedicated to COVID-19 are yet warranted for investigating the role of vitamin D supplementation on COVID-19 outcomes. Interestingly, previous meta-analyses found that high-dose prophylactic vitamin D supplementation was able to reduce the risk of respiratory tract infections [17]. Based on this observation, we and others are conducting an RCT designed to test the effect of high-dose versus standard-dose vitamin D3 on 14-day mortality in COVID-19 older patients (https://clinicaltrials.gov/ct2/show/NCT04344041). While waiting for the recruitment of this RCT to be completed, the findings of the present quasi-experimental study strongly suggest a benefit of bolus vitamin D3 supplementation on COVID-19 outcomes and survival.
How vitamin D supplementation may improve COVID-19 outcomes and survival is not fully elucidated. Three mechanisms are possible: regulation of (i) the RAS, (ii) the innate and adaptive cellular immunity, and (iii) the physical barriers [4]. First, vitamin D reduces pulmonary permeability in animal models of acute respiratory distress syndrome (ARDS) by modulating the activity of RAS and the expression of the angiotensin-2 converting enzyme (ACE2) [18]. This action is crucial since SARS-CoV-2 reportedly uses ACE2 as a receptor to infect host cells [19] and downregulates ACE2 expression [20]. ACE2 is expressed in many organs, including the endothelium and the pulmonary alveolar epithelial cells, where it has protective effects against inflammation [21]. During COVID-19, downregulation of ACE2 results in an inflammatory chain reaction, the cytokine storm, complicated by ARDS [22]. In contrast, a study in rats with chemically-induced ARDS showed that the administration of vitamin D increased the levels of ACE2 mRNA and proteins [23]. Rats supplemented with vitamin D had milder ARDS symptoms and moderate lung damage compared to controls. Second, many studies have described the antiviral effects of vitamin D, which works either by induction of antimicrobial peptides with direct antiviral activity against enveloped and non-enveloped viruses, or by immunomodulatory and anti-inflammatory effects [24]. These are potentially important during COVID-19 to limit the cytokine storm. Vitamin D can prevent ARDS [25] by reducing the production of pro-inflammatory Th1 cytokines, such as TNFα and interferon γ [24]. It also increases the expression of anti-inflammatory cytokines by macrophages [24]. Third, vitamin D stabilizes physical barriers [4]. These barriers are made up of closely linked cells to prevent outside agents (such as viruses) from reaching tissues susceptible to viral infection. Although viruses alter the integrity of the cell junction, vitamin D contributes to the maintenance of functional tight junctions via E-cadherin [4]. All these antiviral effects could potentiate each other and explain our results.
We also found that none of the other dedicated drugs used in this quasi-experimental study was associated with better survival rate in COVID-19 patients. The interest of these drugs in COVID-19 is still debated, whether for corticosteroids [26], hydroxychloroquine [27] or azithromycin [28]. However, it should be noted that these drugs were given here as part of patient care in the most severe clinical situations, which could have biased and masked their effectiveness (if any).
The strengths of the present study include i) the originality of the research question on an emerging infection for which there is no scientifically validated treatment, ii) the detailed description of the participants’ characteristics allowing the use of multivariate models to measure adjusted associations, and iii) the standardized collection of data from a single research center.
Regardless, a number of limitations also existed. First, the study cohort was restricted to a limited number of nursing-home residents who might be unrepresentative of all older adults. Second, although we were able to control for the important characteristics that could modify the association, residual potential confounders might still be present such as the serum concentration of 25(OH)D at baseline - a low level classically ensuring the effectiveness of the supplementation [29]. As this analysis was not initially planned, no concerted efforts were made to systematically measure the serum 25(OH)D concentration before and after supplementation. Third, the quasi-experimental design of our study is less robust than an RCT. Participants in the Comparator group did not receive vitamin D placebo, and there was no randomization. It should yet be noted that the characteristics of the two groups did not differ at baseline, which allows interpreting the survival difference as linked to the vitamin D3 supplementation.
5. CONCLUSIONS
In conclusion, we were able to report among frail elderly residents that bolus vitamin D3 supplementation taken during or just before COVID-19 was associated with less severe COVID-19 and better survival rate. No other treatment showed protective effect.
Vitamin D3 supplementation may represent an effective, accessible and well-tolerated treatment for COVID-19, the incidence of which increases dramatically and for which there are currently no validated treatments. Further prospective, preferentially interventional, studies are needed to confirm whether supplementing older adults with bolus vitamin D3 during or just before the infection could improve, or prevent, COVID-19.
SPONSOR’S ROLE
No sources of funding were used to assist in this study.
AUTHORS CONTRIBUTION
- -
CA has full access to all of the data in the study, takes responsibility for the data, the analyses and interpretation and has the right to publish any and all data, separate and apart from the attitudes of the sponsors. All authors have read and approved the manuscript.
- -
Study concept and design: CA, BH, CGE, JMS, LL and TC.
- -
Acquisition of data: BH and CGE.
- -
Analysis and interpretation of data: CA and TC.
- -
Drafting of the manuscript: CA.
- -
Critical revision of the manuscript for important intellectual content: BH, CGE, JMS, LL and TC.
- -
Obtained funding: Not applicable.
- -
Statistical expertise: CA.
- -
Administrative, technical, or material support: CA and TC.
- -
Study supervision: CA.
Declaration of Competing Interest
The authors report no declarations of interest.
Acknowledgments
The authors wish to thank their collaborators:
- Angeline MEY, MD, from the Department of Clinical Gerontology, University Hospital of Saint-Etienne, Saint-Etienne, France;
- Pauline GUILLEMIN, MD, from the Geriatric Hospital of Saint Symphorien sur Coise, Saint Symporien sur Coise, France;
- Jennifer GAUTIER, MS, from the Research Center on Autonomy and Longevity, University Hospital, Angers, France.
There was no compensation for their contribution.
REFERENCES
- [1]
- D.G. Ahn, H.J. Shin, M.H. Kim, L Sunhee, K Hae-Soo, M Jinjong, et al.Current Status of Epidemiology, Diagnosis, Therapeutics, and Vaccines for Novel Coronavirus Disease 2019 (COVID-19)J Microbiol Biotechnol, 30 (2020), pp. 313-324
- [2]
- G. GlinskyVitamin D, Quercetin, and Estradiol manifest properties of candidate medicinal agents for mitigation of the severity of pandemic COVID-19 defined by genomics-guided tracing of SARS-CoV-2 targets in human cellsChemRxiv (2020), 10.26434/chemrxiv.12052512.v7Preprint
- [3]
- A Hossein-nezhad, MF HolickVitamin D for health: a global perspectiveMayo Clin Proc, 88 (2013), pp. 720-755
- [4]
- W.B. Grant, H. Lahore, S.L. McDonnell, C.A. Baggerly, C.B. French, J.L. Aliano, et al.Evidence That Vitamin D Supplementation Could Reduce Risk of Influenza and COVID-19 Infections and DeathsNutrients, 12 (4) (2020)
- [5]
- P.C. Ilie, S. Stefanescu, L. SmithThe role of vitamin D in the prevention of coronavirus disease 2019 infection and mortalityAging Clin Exp Res (2020), pp. 1-4
- [6]
- Y Rolland, P de Souto Barreto, G Abellan Van Kan, C Annweiler, O Beauchet, H Bischoff-Ferrari, et al.Vitamin D supplementation in older adults: searching for specific guidelines in nursing-homesJ Nutr Health Aging, 17 (2013), pp. 402-412
- [7]
- C. Annweiler, J.C. Souberbielle, A.M. Schott, L. de Decker, G. Berrut, O. BeauchetVitamin D in the elderly: 5 points to rememberGeriatr Psychol Neuropsychiatr Vieil, 9 (2011), pp. 259-267
- [8]
- WHO Coronavirus disease (COVID-2019) R&D. WHO. https://www.who.int/teams/blueprint/covid-19 Accessed 19 May 2020.
- [9]
- L. De Decker, C. Launay, C. Annweiler, A. Kabeshova, O. BeauchetNumber of drug classes taken per day may be used to assess morbidity burden in older inpatients: a pilot cross-sectional studyJ Am Geriatr Soc, 61 (2013), pp. 1224-1225
- [10]
- JM Vetel, R Leroux, JM DucoudrayAGGIR. Practical use. Geriatric Autonomy Group Resources NeedsSoins Gerontol (13) (1998), pp. 23-27
- [11]
- S. Cabrerizo, D. Cuadras, F. Gomez-Busto, I. Artaza-Artabe, F. Marín-Ciancas, V. MalafarinaSerum albumin and health in older people: Review and meta analysisMaturitas, 81 (2015), pp. 17-27
- [12]
- J. Rochon, M. Gondan, M. KieserTo test or not to test: Preliminary assessment of normality when comparing two independent samplesBMC Med Res Methodol, 12 (2012), p. 81
- [13]
- G. El JamesVitamin D Level of Mild and Severe Elderly Cases of COVID-19: A Preliminary Report.SSRN (2020)Preprint
- [14]
- A. D’Avolio, V. Avataneo, A. Manca, J. Cusato, A. De Nicolò, R. Lucchini, et al.25-Hydroxyvitamin D Concentrations Are Lower in Patients with Positive PCR for SARS-CoV-2Nutrients, 12 (5) (2020)
- [15]
- P. Raharusun, S. Priambada, C. Budiarti, E. Agung, C. BudiPatterns of COVID-19 Mortality and Vitamin D: An Indonesian StudySSRN (2020)Prepint
- [16]
- M. AlipioVitamin D supplementation could possibly improve clinical outcomes of patients infected with Coronavirus-2019 (COVID-2019)SSRN (2020)Preprint
- [17]
- A.R. Martineau, D.A. Jolliffe, R.L. Hooper, L. Greenberg, J.F. Aloia, P. Bergman, et al.Vitamin D supplementation to prevent acute respiratory tract infections: systematic review and meta-analysis of individual participant dataBMJ, 356 (2017), p. i6583
- [18]
- J. Kong, X. Zhu, Y. Shi, T. Liu, Y. Chen, I. Bhan, et al.VDR Attenuates Acute Lung Injury by Blocking Ang-2-Tie-2 Pathway and Renin-Angiotensin SystemMol Endocrinol, 27 (2013), pp. 2116-2125
- [19]
- M. Hoffmann, H. Kleine-Weber, N. Krüger, M. Müller, C. Drosten, S PöhlmannThe Novel Coronavirus 2019 (2019-nCoV) Uses the SARS-Coronavirus Receptor ACE2 and the Cellular Protease TMPRSS2 for Entry into Target CellsbioRxiv (2020), 10.1101/2020.01.31.92904201.31.929042
- [20]
- R. Dijkman, M.F. Jebbink, M. Deijs, A. Milewska, K. Pyrc, E. Buelow, et al.Replication-Dependent Downregulation of Cellular Angiotensin-Converting Enzyme 2 Protein Expression by Human Coronavirus NL63J Gen Virol, 93 (2012), pp. 1924-1929
- [21]
- C. Annweiler, Z. Cao, Y. Wu, E. Faucon, S. Mouhat, H. Kovacic, et al.Counter-regulatory’ Renin-Angiotensin’ System-based Candidate Drugs to Treat COVID-19 Diseases in SARS-CoV-2-infected patientsInfect Disord Drug Targets (2020), 10.2174/1871526520666200518073329Epub May 17
- [22]
- X. Ji, C. Zhang, Y. Zhai, Z. Zhang, C. Zhang, Y. Xue, et al.TWIRLS, an Automated Topic-Wise Inference Method Based on Massive Literature, Suggests a Possible Mechanism via ACE2 for the Pathological Changes in the Human Host after Coronavirus InfectionbioRxiv (2020), 10.1101/2020.02.27.96758802.27.967588
- [23]
- J. Yang, H. Zhang, J. XuEffect of Vitamin D on ACE2 and Vitamin D receptor expression in rats with LPS-induced acute lung injuryChinese J Emerg Med, 25 (2016), pp. 1284-1289
- [24]
- A. Fabbri, M. Infante, C. RicordiEditorial - Vitamin D status: a key modulator of innate immunity and natural defense from acute viral respiratory infectionsEur Rev Med Pharmacol Sci, 24 (2020), pp. 4048-4052
- [25]
- R.C. Dancer, D. Parekh, S. Lax, V. D’Souza, S. Zheng, C.R. Bassford, et al.Vitamin D Deficiency Contributes Directly to the Acute Respiratory Distress Syndrome (ARDS)Thorax, 70 (2015), pp. 617-624
- [26]
- Z. Ye, Y. Wang, L.E. Colunga-Lozano, M. Prasad, W. Tangamornsuksan, B. Rochwerg, et al.Efficacy and safety of corticosteroids in COVID-19 based on evidence for COVID-19, other coronavirus infections, influenza, community-acquired pneumonia and acute respiratory distress syndrome: a systematic review and meta-analysisCMAJ (2020), 10.1503/cmaj.200645Epub May 14. pii: cmaj.200645
- [27]
- RE Ferner, JK AronsonChloroquine and hydroxychloroquine in covid-19BMJ, 369 (2020), p. m1432, 10.1136/bmj.m1432
- [28]
- K. Gbinigie, K. FrieShould azithromycin be used to treat COVID-19? A rapid reviewBJGP Open (2020), 10.3399/bjgpopen20X101094Epub May 12. pii: bjgpopen20X101094
- [29]
- RP HeaneyGuidelines for optimizing design and analysis of clinical studies of nutrient effectsNutr Rev, 72 (2014), pp. 48-54
Quiz vraag: Wat is dwisenbin?
ReplyDeleteJe hoeft er niet om te gaan zoeken hoor.
Als je je huiswerk doet, kom je er wel achter.
Vandaag een vriendelijke drogist bezocht. DA, meer cosmetisch georienteerd. Ik had wat maagzuurpillen nodig.
ReplyDeleteDe Vitamine D is uitverkocht, slechts de heel dure merkpotjes zijn verkrijgbaar. (voor de slecht geinformeerde leken: koop en neem het!).
Toen ik het leuke kassa meisje vertelde dat D echt zeer krachig is was ze geinteresseerd! Maar toen ik ivermectine (met korte uitleg) noemde haakte ze totaal af!