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Vitamin D and Muscles

To build muscles you need more than just Vitamin D
   also need Exercise, Protein, Magnesium, Omega-3, and activated Vitamin D Receptors
     In fact, Vitamin D monotherapy sometimes DECREASES muscles.

Notes on Vitamin D Receptor:
Vitamin D Receptors get vitamin D in the blood to the muscle cells
Approximately 20% of people have poos vitamin D receptors
As people age, their Vitamin D receptors also become less activated
There are 12+ low-cost activators for the Vitamin D Receptor
Dr. Greger on Vitamin D and Muscles - May 2020
Vitamin D Supplements for Increasing Aging Muscle Strength

  • "We have known for more than 400 years that muscle weakness is a common presenting symptom of vitamin D deficiency"
  • conservative "U.S. Preventive Services Task Force, the official prevention guideline setting body, and the American Geriatric Society to “recommend vitamin D supplementation for persons who are at high risk of falls.”
  • AGS recommends 4,000 IU to capture 92 percent of the population"

Vitamin D helps muscles in many ways – Sept 2021

Muscle Regeneration and Function in Sports: A Focus on Vitamin D
Medicina 2021, 57(10), 1015; https://doi.org/10.3390/medicina57101015
by Giovanni Iolascon 1,Antimo Moretti 1,*OrcID,Marco Paoletta 1OrcID,Sara Liguori 1 andOmbretta Di Munno 2

  • 1 Department of Medical and Surgical Specialties and Dentistry, University of Campania “Luigi Vanvitelli”, Via de Crecchio, 6, 80138 Naples, Italy
  • 2 Rheumatology Unit, Department of Clinical and Experimental Medicine, University of Pisa, 56122 Pisa, Italy

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Muscle is one of the main targets for the biological effects of vitamin D. This hormone modulates several functions of skeletal muscles, from development to tissue repair after injury, through genomic and non-genomic mechanisms. Vitamin D deficiency and supplementation seem to significantly affect muscle strength in different populations, including athletes, although optimal serum 25(OH)D3 level for sport performance has not been defined so far.
Additionally, vitamin D deficiency results in myopathy characterized by

  • fast-twitch fiber atrophy,
  • fatty infiltration, and
  • fibrosis.

However, less is known about regenerative effects of vitamin D supplementation after sport-related muscle injuries. Vitamin D receptor (VDR) is particularly expressed in the embryonic mesoderm during intrauterine life and in satellite cells at all stages of life for recovery of the skeletal muscle after injury. Vitamin D supplementation enhances muscle differentiation, growth, and regeneration by increasing the expression of myogenic factors in satellite cells. The objective of this narrative review is to describe the role of vitamin D in sport-related muscle injury and tissue regeneration.
 Download the PDF from VitaminDWiki


Muscle in VitaminDWiki

Muscles and Seniors in VitaminDWiki

Exercise helps build muscles

Omega-3

Overview Sports and vitamin D

Overview Sports and vitamin D has the following summary
Athletes are helped by vitamin D by:

  1. Faster reaction time
  2. Far fewer colds/flus during the winter
  3. Less sore/tired after a workout
  4. Fewer micro-cracks and broken bones
  5. Bones which do break heal much more quickly
  6. Increased VO2 and exercise endurance Feb 2011
  7. Indoor athletes especially need vitamin D
  8. Professional indoor athletes are starting to take vitamin D and/or use UV beds
  9. Olympic athletes have used UV/vitamin D since the 1930's
  10. The biggest gain from the use of vitamin D is by those who exercise less than 2 hours per day.
  11. Reduced muscle fatigue with 10,000 IU vitamin D daily
  12. Muscle strength improved when vitamin D added: 3 Meta-analysis
  13. Reduced Concussions
    See also: Sports and Vitamin D category 243 items

The Roles of Vitamin D in Skeletal Muscle Feb 2013

The Roles of Vitamin D in Skeletal Muscle: Form, Function, and Metabolism
Endocrine Reviews February 1, 2013 vol. 34 no. 1 33-83
Christian M. Girgis, Roderick J. Clifton-Bligh, Mark W. Hamrick, Michael F. Holick and Jenny E. Gunton
Garvan Institute of Medical Research (C.M.G., J.E.G.) and St. Vincent's Clinical School (J.E.G.), University of New South Wales, Sydney, New South Wales 2010, Australia; Faculty of Medicine (C.M.G., R.J.C.-B., J.E.G.), University of Sydney, Sydney, New South Wales 2052, Australia; The Kolling Institute of Medical Research (R.J.C.-B.) and Royal North Shore Hospital (R.J.C.-B.), Sydney, New South Wales 2065, Australia; Georgia Health Sciences University (M.W.H.), Augusta, Georgia 30912; Boston University Medical Center (M.F.H.), Boston, Massachusetts 02118; and Department of Endocrinology and Diabetes (J.E.G.), Westmead Hospital, Sydney, New South Wales 2145, Australia
Address requests for reprints to: Dr. Christian M. Girgis or Associate Professor Jenny E. Gunton, Garvan Institute of Medical Research, 384 Victoria Street, Darlinghurst, New South Wales, Australia. E-mail: c.girgis at garvan.org.au or j.gunton at garvan.org.au.

Beyond its established role in bone and mineral homeostasis, there is emerging evidence that vitamin D exerts a range of effects in skeletal muscle. Reports of profound muscle weakness and changes in the muscle morphology of adults with vitamin D deficiency have long been described. These reports have been supplemented by numerous trials assessing the impact of vitamin D on muscle strength and mass and falls in predominantly elderly and deficient populations. At a basic level, animal models have confirmed that vitamin D deficiency and congenital aberrations in the vitamin D endocrine system may result in muscle weakness. To explain these effects, some molecular mechanisms by which vitamin D impacts on muscle cell differentiation, intracellular calcium handling, and genomic activity have been elucidated. There are also suggestions that vitamin D alters muscle metabolism, specifically its sensitivity to insulin, which is a pertinent feature in the pathophysiology of insulin resistance and type 2 diabetes. We will review the range of human clinical, animal, and cell studies that address the impact of vitamin D in skeletal muscle, and discuss the controversial issues. This is a vibrant field of research and one that continues to extend the frontiers of knowledge of vitamin D's broad functional repertoire.

I. Introduction
II. Background Physiology

A. The vitamin D pathway
B. Skeletal muscle physiology
C. Calcium and muscle contraction
D. Calcium and exercise-related glucose uptake
E. Calcium and insulin-stimulated glucose uptake

III. Vitamin D and Muscle: Cell Models

A. VDR in muscle
B. Calcium homeostasis
C. Phosphate homeostasis
D. Proliferation and differentiation
E. Muscle contractile proteins
F. Phospholipid composition
G. Bone-muscle cross talk and vitamin D
H. Cell models and molecular pathways for insulin signaling and diabetes

IV. Vitamin D and Muscle: Studies in Animal Models

A.1 VDRKO mice
B. Other animal models
C. Animal studies on insulin sensitivity and diabetes
D. Summary: vitamin D and muscle function in animal studies

V. VDR Polymorphisms and Muscle Function

A. FokI polymorphisms
B. BsmI polymorphisms
C. VDR polymorphisms and insulin resistance/type 2 diabetes

VI. Vitamin D and Muscle: Human Studies

A. Myopathy
B. Myalgia and vitamin D deficiency
C. Fibromyalgia
D. Drug-related myopathy and vitamin D
E. Falls and vitamin D
F. Muscle strength and physical performance
G. Muscle morphology and electromyography (EMG)
H. Insulin sensitivity and glucose handling VII. Conclusions

Conclusions
  • Vitamin D exerts rapid and genomic effects in primary muscle cells and cell lines.
    These effects relate to intracellular calcium handling,differentiation and contractile protein composition.
  • In vivo, it is not clear whether VDR is expressed in adult skeletal muscle.
  • Whole-body VDRKO mice and vitamin D-deficient animals display significant defects in muscle function and development.
  • In humans, single nucleotide polymorphisms in the gene encoding VDR have been associated with differences in muscle strength.
  • Changes in muscle morphology in humans with severe vitamin D deficiency have been reported since the 1970s.
  • Proximal myopathy and muscle pain in subjects with severe vitamin D deficiency resolve following vitamin D supplementation.
  • Associations between vitamin D deficiency, muscle weakness and falls are confounded by factors including frailty and lower exposure to sunlight.
    Clinical parameters of muscle function are not standardized making data aggregation difficult.
  • Randomized data suggest that vitamin D supplementation may reduce falls in older individuals but not all studies support this conclusion.
  • The recommended dose of vitamin D supplementation and vitamin D targets remain hotly contested issues.
Outstanding questions
  • Does the VDR exist in fully differentiated adult muscle and does it have physiological relevance at this site?
    Or rather, as suggested by in vitro studies, is its role predominantly related to the function of immature muscle cells such as in myogenesis?
  • Are changes in muscle function and morphology directly related to vitamin D or indirectly to its effects in calcium and mineral homeostasis?
  • Does skeletal muscle possess the ability to 1-a-hydroxylate 25D at any stage in its development?
  • As suggested by studies on phosphate handling in myocytes, does 25D itself exert direct effects on muscle?
  • Is vitamin D deficiency or its reversal an important consideration among those with other muscle disorders such as congenital dystrophies and acquired immune-related myositis?


56 page PDF is attached at the bottom of this page

Feb 2013



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48,000 IU monthly for a year did not help elderly muscles- June 2019

No effect of monthly supplementation with 12000 IU, 24000 IU or 48000 IU vitamin D3 for one year on muscle function: The vitamin D in older people study.
J Steroid Biochem Mol Biol. 2019 Jun;190:256-262. doi: 10.1016/j.jsbmb.2018.12.008. Epub 2018 Dec 21.Ranathunga RMTK1, Hill TR2, Mathers JC2, Francis RM3, Prentice A4, Schoenmakers I5, Aspray TJ6; Vitamin D in Older People Study group.

Vitamin D plays a role in muscle function through genomic and non-genomic processes. The objective of this RCT was to determine the effect of monthly supplemental vitamin D3 onmuscle function in 70+ years old adults. Participants (n = 379) were randomized to receive, 12,000 IU, 24,000 IU or 48,000 IU of vitamin D3 monthly for 12 months. Standardized Hand Grip Strength (GS) and Timed-Up and Go (TUG) were measured before and after vitamin D3 supplementation. Fasting total plasma 25 hydroxyvitamin D (25OHD) and Parathyroid Hormone (PTH) concentrations were measured by Liquid Chromatography Tandem Mass Spectrometry (LC-MSMS) and immunoassay, respectively. Baseline plasma 25OHD concentrations were 41.3 (SD 19.9), 39.5 (SD 20.6), 38.9 (SD 19.7) nmol/L; GS values were 28.5 (SD 13.4), 28.8 (SD 13.0) and 28.1 (SD 12.1) kg and TUG test values were 10.8 (SD 2.5), 11.6 (SD 2.9) and 11.9 (SD 3.6) s for the 12,000 IU, 24,000 IU and 48,000 IU dose groups, respectively. Baseline plasma 25OHD concentration < 25 nmol/L was associated with lower GS (P = 0.003). Post-interventional plasma 25OHD concentrations increased to 55.9 (SD 15.6), 64.6 (SD15.3) and 79.0 (SD 15.1) nmol/L in the 12,000 IU, 24,000 IU and 48,000 IU dose groups, respectively and there was a significant dose-related response in post-interventional plasma 25OHD concentration (p<0.0001). Post-interventional GS values were 24.1 (SD 10.1), 26.2 (SD10.6) and 25.7 (SD 9.4) kg and TUG test values were 11.5 (SD 2.6), 12.0 (SD 3.7) and 11.9 (SD 3.2) s for 12,000 IU, 24,000 IU and 48,000 IU dose groups, respectively. The change (Δ) in GS and TUG from pre to post-intervention was not different between treatment groups before and after the adjustment for confounders, suggesting no effect of the intervention. Plasma 25OHD concentration was not associated with GS and TUG test after supplementation. In conclusion, plasma 25OHD concentration < 25 nmol/L was associated with lower GS at baseline. However, monthly vitamin D3 supplementation with 12,000 IU, 24,000 IU and 48,000 IU, for 12 months had no effect on muscle function in older adults aged 70+ years. Trial Registration : EudraCT 2011-004890-10 and ISRCTN35648481.
 Download the PDF from VitaminDWiki


Sarcopenia: 3.3 X higher risk if low bio-available vitamin D - August 2021

Comparative analysis of the association between various serum vitamin D biomarkers and sarcopenia
J Clin Lab Anal. 2021 Aug 5;e23946. doi: 10.1002/jcla.23946
Jun-Il Yoo 1, Hye Jin Chung 2, Bo Gyu Kim 3, Youn-Kwan Jung 3, Kyung-Wan Baek 1, Myung-Geun Song 1, Min-Chul Cho 4 5

Total Vitamin D - not bio-available
Image
 Download the PDF from VitaminDWiki

Background: Vitamin D status is associated with muscle strength and maintenance of muscle fibers. However, which serum vitamin D biomarker better reflects sarcopenia remains unclear. The aim of this study was to investigate associations between various serum vitamin D biomarkers (total 25-hydroxy vitamin D [25(OH)D], bioavailable 25(OH)D, 24,25-dihydroxyvitamin D [24,25(OH)2 D], and vitamin D metabolite ratio [VMR]) and sarcopenia.

Methods: The data for 83 hip fracture patients were finally included in the analysis. Sarcopenia was defined according to the Asia Working Group for Sarcopenia (AWGS) criteria. Measurements of 24,25(OH)2 D and 25(OH)D were made using solid-phase extraction (SPE) and subsequent liquid chromatography-tandem mass spectrometry (LC-MS/MS). Vitamin D binding protein (VDBP) concentration was measured using an enzyme-linked immunosorbent assay. The VMR was calculated by dividing serum 24,25(OH)2 D by serum 25(OH)D and then multiplying by 100. Based on total 25(OH)D, VDBP, and albumin concentrations, bioavailable 25(OH)D concentrations were calculated using the equations from the other previous studies.

Results: Bioavailable 25(OH)D levels were significantly (p = 0.030) decreased in the sarcopenia group compared with the non-sarcopenia group. Results of ROC analysis for the diagnosis of sarcopenia using serum level of bioavailable of 25(OH)D revealed that the cutoff point for bioavailable 25(OH)D was 1.70 ng/ml (AUC = 0.649, p < 0.001). In the group with a bioavailable 25(OH)D less than 1.70 ng/ml, the incidence of sarcopenia increased by 3.3 times (odds ratio: 3.33, p = 0.013).

Conclusion: We demonstrated that bioavailable 25(OH)D was associated with sarcopenia among the various serum vitamin D biomarkers. Bioavailable vitamin D might be helpful for assessing the risk of sarcopenia.


Some reduced muscle function associated with many Vitamin D genes - Review Sept 2021

Association between Polymorphisms in Vitamin D Pathway-Related Genes, Vitamin D Status, Muscle Mass and Function: A Systematic Review
 Download the PDF from VitaminDWiki

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Created by admin. Last Modification: Saturday September 25, 2021 14:52:57 GMT-0000 by admin. (Version 44)
Vitamin D and Muscles        
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ID Name Comment Uploaded Size Downloads
16281 Muscle 2021.jpg admin 25 Sep, 2021 14:51 118.01 Kb 12
16280 Muscle Regeneration.pdf PDF 2021 admin 25 Sep, 2021 14:50 517.02 Kb 3
16172 Vitamin D genes and muscles.pdf PDF 2021 admin 04 Sep, 2021 08:41 697.62 Kb 37
16032 Sacro bioavailable.jpg admin 05 Aug, 2021 18:16 21.11 Kb 17
16031 Sarcopenia levels.jpg admin 05 Aug, 2021 17:58 32.15 Kb 127
16030 Sarcopenia 3X.pdf admin 05 Aug, 2021 17:57 799.40 Kb 50
12976 48,000 IU monthly muscle.pdf PDF 2019 admin 15 Nov, 2019 21:37 607.57 Kb 346
2719 Muscle T7B.jpg admin 03 Jul, 2013 20:36 41.56 Kb 3336
2718 Muscle T7A.jpg admin 03 Jul, 2013 20:36 69.38 Kb 3157
2717 Muscle T6.jpg admin 03 Jul, 2013 20:36 109.97 Kb 3181
2716 Muscle T5D.jpg admin 03 Jul, 2013 20:35 41.24 Kb 3026
2715 Muscle T5C.jpg admin 03 Jul, 2013 20:35 79.00 Kb 3121
2714 Muscle T5B.jpg admin 03 Jul, 2013 20:35 69.68 Kb 3062
2713 Muscle T5A.jpg admin 03 Jul, 2013 20:35 103.22 Kb 3137
2712 Muscle T4.jpg admin 03 Jul, 2013 20:34 96.45 Kb 3143
2711 Muscle T3.jpg admin 03 Jul, 2013 20:34 74.43 Kb 3131
2710 Muscle T2.jpg admin 03 Jul, 2013 20:34 97.35 Kb 3276
2709 Skeletal muscle.pdf PDF 2013 admin 03 Jul, 2013 20:33 1.86 Mb 1512
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