Disc Degeneration in women is 1.7X more likely if poor Vitamin D Receptor – meta-analysis Jan 2017

Association Between the FokI and ApaI Polymorphisms in the Vitamin D Receptor Gene and Intervertebral Disc Degeneration: A Systematic Review and Meta-Analysis.

Genet Test Mol Biomarkers. 2017 Jan;21(1):24-32. doi: 10.1089/gtmb.2016.0054. Epub 2016 Oct 31.
Pabalan N1, Tabangay L2, Jarjanazi H3, Vieira LA4, Dos Santos AA5, Barbosa CP5, Rodrigues LM4, Bianco B5.
1 Center for Research and Development, Angeles University Foundation , Angeles City, Philippines .
2 Department of Biological Sciences, Angeles University Foundation , Angeles City, Philippines .
3 Environmental Monitoring and Reporting Branch, Ontario Ministry of the Environment and Climate Change , Etobicoke, Canada .
4 Orthopedics and Traumatology, Faculdade de Medicina do ABC-Santo André , São Paulo, Brazil .
5 Department of Collective Health, Faculdade de Medicina do ABC, Human Reproduction and Genetics Center , São Paulo, Brazil .

VitaminDWiki

Items in both categories Osteoporosis and Vitamin D Receptor are listed here:

Items in both categories Back Pain and Vitamin D Receptor are listed here:


Vitamin D Receptor category has the following

510 studies in Vitamin D Receptor category

Vitamin D tests cannot detect Vitamin D Receptor (VDR) problems
A poor VDR restricts Vitamin D from getting in the cells

See also: 47 studies in the Resveratrol category

It appears that 30% of the population have a poor VDR (40% of the Obese )
Several diseases protect themselves by deactivating the Vitamin D receptor. Example: Breast Cancer
- - - - - - - -
The Vitamin D Receptor is associated with many health problems

Health problems include: Autoimmune (19 studies), Breast Cancer (22 studies), Colon Cancer (13 studies), Cardiovascular (23 studies), Cognition (16 studies), Diabetes (24 studies), Hypertension (9 studies), Infant (21 studies), Lupus (6 studies), Metabolic Syndrome (4 studies), Mortality (4 studies), Multiple Sclerosis (12 studies), Obesity (16 studies), Pregnancy (24 studies), Rheumatoid Arthritis (10 studies), TB (8 studies), VIRUS (36 studies),   Click here for details
Some health problems, such as Breast Cancer, Diabetes, and COVID protect themselves by reducing VDR activation

55 health problems associated with poor VDR


A poor VDR is associated with the risk of 55 health problems  click here for details
The risk of 48 diseases at least double with poor VDR as of Jan 2023  click here for details
Some health problem, such as Breast Cancer reduce the VDR

VDR at-home test $29 - results not easily understood in 2016
There are hints that you may have inherited a poor VDR


How to increase VDR activation


Compensate for poor VDR by increasing one or more:

IncreasingIncreases
1) Vitamin D supplement  Sun
Ultraviolet -B
Vitamin D in the blood
and thus in the cells
2) MagnesiumVitamin D in the blood
 AND in the cells
3) Omega-3 Vitamin D in the cells
4) Resveratrol Vitamin D Receptor
5) Intense exercise Vitamin D Receptor
6) Get prescription for VDR activator
   paricalcitol, maxacalcitol?
Vitamin D Receptor
7) Quercetin (flavonoid) Vitamin D Receptor
8) Zinc is in the VDRVitamin D Receptor
9) BoronVitamin D Receptor ?,
etc
10) Essential oils e.g. ginger, curcuminVitamin D Receptor
11) ProgesteroneVitamin D Receptor
12) Infrequent high concentration Vitamin D
Increases the concentration gradient
Vitamin D Receptor
13) Sulfroaphane and perhaps sulfurVitamin D Receptor
14)Butyrate especially gutVitamin D Receptor

Note: If you are not feeling enough benefit from Vitamin D, you might try increasing VDR activation. You might feel the benefit within days of adding one or more of the above

Far healthier and stronger at age 72 due to supplements Includes 6 supplements that help the VDR


Increased risk associated with a poor Vitamin D Receptor
   Note: Some diseases reduce VDR activation
those with a * are known to decrease activation

Risk
increase
Health Problem
50Lyme Disease *
28Leprosy - another says 3X
15Chronic Heart Failure
15Temporary hair loss
14,7Childhood solid cancers
14Hand, Foot, and Mouth disease
13Sepsis
12COVID Death
11Metabolic Syndrome
9.6Chronic Periodontitis
   and smoke
8Juvenile Rheumatoid Arthritis
7.6Crohn's disease
7.5Respiratory Tract Infections
5.8Low back pain in athletes
5 Respiratory Distress in preemies
5Ulcerative Colitis
5Coronary Artery Disease
5Asthma Child see also 1.3, 2.0 and 3.6
4.6Breast Cancer * 16.9 X another study
4.3Severe COVID in kids
4.1Vitiligo
4Polycystic ovary syndrome
3.8Lupus
3.6 Pneumonia - children
3.3 Pre-term birth
3.1 Colon Cancer survival
3 Multiple Sclerosis
3Dengue
3 Waist size
3 Ischemic Stroke
3Alzheimer’s
9X in women
3Parkinson’s
3Gestational Diabetes
2.9Hand, Foot, Mouth Disease
2.8Osteoporosis & COPD
2.7Gastric Cancer
2.6Lupus in children
2.5 Lumbar Disc Degeneration
2.4Lung Cancer
2.3Cardio
2.3Autism
2.2Juvenile idiopathic arthritis
2.1Adolescent idiopathic scoliosis in Asians
2Diabetic Retinopathy
2Parkinson's
2 Wheezing/Asthma see also 5X
2 Melanoma   Non-melanoma Skin Cancers
2Myopia
2Preeclampsia
1.9Uterine Fibroids
1.9Early tooth decay
1.8Diabetic nephropathy
1.8Sleep Apnea
1.6Diabetes - Type I
1.6Prostate Cancer while black
1.5 Diabetes -Type II
1.5Gout
1.5Pertussis
1.5Obesity
1.4Graves Disease
1.4 Rheumatoid arthritis
1.3Hypertension
1.3Childhood asthma see also 5X
1.3Psoriasis in Caucasians
1.3Tuberculosis
?? Rickets - Vitamin D resistant

See also PubMed


 Download the PDF from VitaminDWiki

BACKGROUND:
Evidence supporting an association of intervertebral disc degeneration (DD) with polymorphisms of the vitamin D receptor (VDR) gene has been controversial. We performed a meta-analysis of these studies to determine if there was substantial evidence to support such an association between the VDR polymorphisms and DD.

METHODS:
PubMed, Embase, and Science Direct databases were searched for studies that investigated associations of the FokI (rs2228570, rs10735810), and ApaI (rs7975253) polymorphisms of the VDR gene with DD. From the extracted genotype data from 14 publications, we estimated risk (odds ratio OR with 95% confidence intervals).

RESULTS:
Overall associations of FokI with DD were absent (OR 0.96-1.04, p = 0.73-0.95) with heterogeneity in the dominant and codominant models (pheteroegeneity <0.10, I2 = 47-57%). Post-outlier pooled effects yielded dominant significance indicating reduced risk (OR 0.77, p = 0.01) with concomitant zero heterogeneity (I2 = 0%). ApaI effects pointed to reduced risks, with overall dominant significance (OR 0.69, p = 0.04) and Asian subgroup nonsignificance (OR 0.75-0.93, p = 0.17-0.74). In FokI, Non-Hispanic Caucasians (OR 0.77, p = 0.01) and males (OR 0.36-0.66, p = 0.001-0.04) were protected but not Hispanic Caucasians (OR 1.39-1.85, p = 0.006-0.05) and females (OR 1.72, p = 0.05). Tests of interaction between the genders highlighted female susceptibility and male protection (p = 0.001-0.005). Zero heterogeneity (I2 = 0%) is a key strength of these significant effects.

CONCLUSION:
This meta-analysis confirmed the protective role of the ApaI polymorphism, however, susceptibility and protective effects of the FokI polymorphism may be ethnic and gender specific.

PMID: 27797588 DOI: 10.1089/gtmb.2016.0054

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