American Journal of Biomedical Science & Research DOI: 10.34297/AJBSR.2020.08.001250.
Omar K Danner1*, Erin Danielle Danner2 and Leslie Ray Matthews1
1Department of Surgery, Morehouse School of Medicine, USA 2College of Arts and Sciences, University of Georgia, USA
- Vitamin D, glutathione, and heat shock protein to treat concussions, etc. – US Patent Dec 2019
- UN invited Dr. Matthews to speak about Vitamin D in both Sept and Oct 2018
- FDA decided to double vitamin D in milk after talking 4 times with by Dr. Matthews – July 2016
- US Army learning about benefits of vitamin D to trauma – Dec 2013
- Hospital ICU added high dose vitamin D - malpractice lawsuit costs dropped from 26 million dollars to ZERO - Oct 2016
- Congressional Black Caucus Foundation (Wash D.C) invited Dr. Mathews to speak to them on Vitamin D – Sept 2018
- Army Training trying performance readiness bars with 1400 IU of Vitamin D (Dr. Matthews) – Sept 2018
- Fastest US High School sprinters are both at the school taking lots of vitamin D (Matthews) May 2016
- Hospital ICU added high dose vitamin D - malpractice lawsuit costs dropped from 26 million dollars to ZERO - Oct 2016
- Surgeon on a mission to promote vitamin D - Dec 2012
- Grady (where he works) is one of the busiest Level 1 trauma centers in the entire United States
- He works between 80 to 100 hours a week
- 98.8% of our ICU patients were vitamin D deficient
- Interviewer: So vitamin D works sort of across the board in helping you survive whatever it is that is wrong with you
- I've had to go as high as like 70 to 80 on some patients to get the proper response
- UN presentation – They had never heard anything, how vitamin D can affect the whole nation, the country, the world, or the world health organizations. So they had no clue
- US…can probably save over $800 Billion a year if we got everybody's vitamin D level above 40
- Vitamin D is “most common nutritional deficiency in the world”
- Many blacks believe that they get more VItamin D from the sun, rather than 5X less
- Trauma and Surgery category listing has
307 items along with related searches
Items in both categories Trauma Surgery and Loading Dose are listed here:
- Half as much AFIB after bypass if 600,000 IU of vitamin D before surgery – RCT April 2022
- ICU mortality reduced by non-oral vitamin D – meta-analysis May 2021
- Taking Vitamin D just before and after surgery helps (open-heart in this case) – RCT Feb 2021
- Half as many problems if take Vitamin D (300,000 IU) before thyroid surgery – RCT Jan 2021
- Fewer days in hospital if 300,000 IU of vitamin D before brain surgery - RCT Feb 2021
- ICU Vitamin D injection (300,000 IU) helped - RCT Feb 2021
- Those getting an injection of 300,000 IU Vitamin D got out of the ICU a week sooner – RCT Dec 2020
- ICU patients greatly helped by Vitamin D loading doses – if gut-friendly – Oct 2020
- Fewer days in ICU after 300,000 IU of vitamin D, but not 540,000 – meta-analysis Aug 2020
- 3X less Septic Shock in children with sepsis getting 150,000 IU of Vitamin D - RCT June 2020
- 100,000 IU daily of Vitamin D for 5 days increased Hemoglobin in Mechanically Ventilated adults – RCT Jan 2018
- Traumatic Brain Injury – 120,000 IU of Vitamin D resulted in 3 fewer days on ventilators – RCT March 2020
- Hip surgery with multiple doses of 50,000 IU of vitamin D weekly both before and after – RCT 2023
- Use of Vitamin D in a trauma surgery - Dr. Matthews on Facebook – Jan 2020
- Surgeries often deplete Vitamin D - 300,000 IU resulted in little response – Nov 2018
- 10 fewer days of ICU Mechanical Ventilation 300,000 IU injection of vitamin D – RCT March 2019
- Intensive Care (ICU) helped by Vitamin D – review of past and on-going studies – Dec 2018
- ICU adults getting 540,000 IU of Vitamin D were 2X more likely to be alive 30 days later – RCT June 2019
- Traumatic Brain Injury recovery helped by injection of 100,000 IU of Vitamin D – March 2019
- Rapidly restore Vitamin D levels with 10,000 IU per kg for children in ICU – RCT 2024
- Esophageal Cancer surgery helped by 300,000 IU of Vitamin D – RCT Sept 2018
- Severe sepsis may be prevented by 400,000 IU of vitamin D – RCT 2023
- Critically ill children – randomized clinical trial to give single doses of up to 400,000 IU of vitamin D – 2019
- Vitamin D loading doses reduce ICU mortality by 30 percent – meta-analysis April 2017
- Children in Intensive Care need Vitamin D loading dose of 10000 IU per kg (nearing a consensus) - Oct 2016
- Vitamin D Loading dose - 20,000 IU daily is not enough if obese, etc. (Cancer) great table and chart – Oct 2016
- Rapid Normalization of Vitamin D in Critically Ill Children (10,000 IU per kg) – clinical trial
- VITdAL-ICU - AMA RCT Sept 2014
- Critically ill need vitamin D – how much and which test to use is TBD – Nov 2014
- ICU survival increased with vitamin D single 540K IU loading dose - JAMA Sept 2014
- 540000 IU before ICU raised vitamin D by 25 ng in 2 days – March 2011
- Hip surgery followed by 100000 IU then 1000 IU of vitamin D daily – June 2010
- 600,000 IU intramuscular D3 helped BMD after pancreatic surgery – June 2010
In 2008, Giovanucci et al.  showed that men with low vitamin D levels suffered 2.42 times more myocardial infarctions than those with normal vitamin D status . Alternatively, a sufficient amount of serum 25-hydroxyvitamin D3, [25(OH)D], appears to improve the risk of almost every disease of aging. Dobnig et al.  similarly demonstrated people with an inadequate vitamin D status have twice the likelihood of death over seven years [2,3]. Vitamin D sufficiency, define as serum 25(OH)D levels of 30ng/ mL (75nmol/L) and above, improves various health outcomes, including bone mineral density, fractures, and colorectal cancer, based on analysis of observational studies . Vitamin D levels of 21-29ng/mL delineates insufficiency and a concentration of 20ng/ mL or less defines vitamin D deficiency . When vitamin D levels are inadequate, and particularly fall below 17.8ng/mL, mortality risk increases by as much as 26% from all-cause mortality in the general population [3,5]. Current data suggests hypovitaminosis D plays a significant role in the development of numerous common chronic diseases and inflammatory conditions, including coronary artery disease, cerebrovascular disease, diabetes mellitus, autoimmune disorders, such as systemic lupus erythematosus, scleroderma and multiple sclerosis and 17 different forms of cancer [6-12]. Vitamin D deficiency is arguably one of the most prevalent but underrated nutritional deficiency worldwide [6,7]. It continues to be associated with increased overall mortality risk in several studies [8-12]. Several observational studies on hypovitaminosis D over the past decade support the persistent existence of a high prevalence of vitamin D insufficiency and deficiency in as many as 50 to 90% of hospitalized patients, with a particular predilection in the setting of critical illness [6-9, 12-14]. Although full elucidation of the role vitamin D status plays in patients requiring admission to the intensive care unit (ICU) is an area undergoing active investigation, epidemiological data supports the findings that vitamin D sufficiency may decrease the risk of systemic inflammatory from all causes as well as sepsis in general [12,15]. Investigations by our group examining the prevalence and effects of insufficient or deficient serum vitamin D levels on our critically-ill and/or severely- injured trauma patients revealed increased risk of unfavorable outcomes when serum vitamin D levels fell below a level of 30ng/ mL (75nmol/mL] in SICU trauma patients who survived their initial injury and resuscitative efforts [6,16]. According to some of the world's leading vitamin D experts, optimal serum levels of 25[OH]D range between 30 and 50ng/mL. Those individuals with 25 (OH) D3 (calcidiol) levels below 30 ng/mL are considered to have vitamin D insufficiency as noted above [5,6, 8,15,16] looked at the risk of 30- day and in-hospital mortality after initiation of critical care services in patients with severe vitamin D deficiency. There was a 1.9-fold higher risk of death than in those patients with vitamin D levels of <30ng/mL . Inadequate levels of 25[OH]D in the insufficient cohort remained a significant predictor of increased likelihood of mortality, even after multivariate adjustment .
Under normal circumstances, vitamin D is a hormone produced principally by the skin in response to natural sunlight. However,
when the sun hits the northern hemisphere below 45 degrees in the spring and summer, it cannot produce UVB rays of the proper wavelengths from 290 to 315 nm, which is required for the production of vitamin D in the skin between 10:00 a.m. and approximately 3:00 p.m. [6,17]. At latitudes of 32 degrees or above, vitamin D levels are the lowest, particularly during the winter months and early spring, due to the lack of sunlight at the suitable wavelength [6,17]. During the fall and winter months, vitamin D stores decrease by approximately 20 to 30%. Furthermore, vitamin D deficiency is very common in Western society as it is nearly impossible to get adequate amounts of vitamin D from diet alone without purposeful exogenous supplementation [6,7,17]. Therefore, reversal of hypovitaminosis D may not be quick or easy without supplementation.
There is a suggestion by researchers that vitamin D deficiency is present in at least 50% to 80% of critically ill patients admitted to surgical and medical ICUs. Nevertheless, based on the definition of normal and subtherapeutic vitamin D status, vitamin D insufficiency in western society may be grossly underestimated [6-14,16]. The true prevalence and extent of vitamin D deficiency might be much worse. This understanding is particularly pertinent considering we have entered the season of increased risk for acute respiratory illness, where a robust immune system is of paramount importance for fighting off upper respiratory tract infections. This underappreciation of vitamin D deficiency may be associated with increased relative risk of adverse outcomes in fragile and critically ill patient populations [6-14,16]. In our prior investigations, we evaluated a cutoff >40 ng/mL as a surrogate marker to define a normal vitamin D level, and levels of <40 ng/mL to represent a relative insufficiency in our ICU patients . We found higher 25[OH]D levels improved outcomes in surgical ICU patients [6,8,16]. There is other evidence that supports the body functions better at this higher vitamin D level. Other authors have suggested that maximal bone density (BMD) can only be achieved when the 25-hydroxyvitamin D level reaches 40ng/mL or greater . As fractures are very common in critically injured elderly trauma patients, achieving adequate vitamin D levels becomes increasingly important in this fragile, at-risk patient population. Based on prior observations demonstrating the need for calcidiol levels > 40ng/ mL to adequately suppress serum parathyroid hormone levels and achieve maximal bone density in the hips and lumbar spine patients, it is plausible to suggest that higher vitamin D levels may portend a protective effect in the other severely injured and/or critically ill individuals [5,6,15,18-20].
To achieve a vitamin D of 30 to 50ng/mL and maintain it long term, investigators have found that it takes over 4,000 to 5,000 units of 25-(0H) vitamin D supplementation per day [18,20]. This amounts to over 5 to 10 times the current recommended daily intake . The importance of this recommendation is that optimal local concentrations of serum 25-(OH) D >30 ng/mL [6,24,25] are required for optimal paracrine conversion to 1,25-(OH)2-vitamin D (calcitriol) by macrophages and other immune cells. The serum concentration needs to be > 30 (>75 nmol/L) [6,7,21-24] to activate the vitamin D receptors (VDR) that regulates the immune response. Activation of the VDR by bioactive vitamin D up-regulates the anti-inflammatory cytokines IL-8 and IL-10, which promotes the expression of a T-suppressor cell lineage and helps to turn off the adaptive immune response once the job is complete [23-25]. Thus, it is understandable that patients with moderate to severe vitamin D deficiency syndromes are less capable of mounting a successful immune response to severe insults, injury, and acute viral and bacterial infections. Furthermore, they have higher risk of ICU- related septic complications, acute respiratory distress syndrome (ARDS) and death.
Published data suggests critically-ill patients with inadequate serum vitamin D stores may enter into a vicious inflammatory cycle due to low levels of the bioactive form of vitamin D, calcitriol, which leads to increased production of pro-inflammatory cytokines, which may not be easily reversed with vitamin D supplementation [6,8,24]. This review may provide a plausible link between the excess mortality observed in people during an acute outbreak of novel acute respiratory syndromes in the general population and especially patients in the ICU setting who are at a higher risk of frankly deficient vitamin D levels. Therefore, we recommend checking serum 25-OH vitamin D levels on all hospitalized ICU patients, and particularly those with acute respiratory or unexplained infectious/inflammatory illness. Although it is difficult to prove clinical effectiveness in the setting of acute infectious illness, supplementation of vitamin D stores to augment the immune system using cholecalciferol (Vitamin D3) at doses of 4,000 to 5,000 units daily may not be unreasonable, especially during this uncharacteristically aggressive flu season, and more so in light of the worldwide coronavirus [COVID-19] epidemic.
Critically Ill or injured patients need 30-50 ng of Vitamin D – Matthews March 2020
- Giovannucci E, Liu Y, Hollis BW, Rimm EB (2008) 25-hydroxyvitamin D and risk of myocardial infarction in men: a prospective study. Arch Intern Med 168(11): 1174-1180.
- Dobnig H, Pilz S, Scharnagi H, Renner W, Seelhorst U, et al. (2008) Independent association of low serum 25-hydroxyvitamin d and 1,25-dihydroxyvitamin D levels with all-cause and cardiovascular mortality, Arch Intern Med 168(12): 1340-1349.
- Melamed ML, Michos ED, Post W, Astor B (2008) 25-hydroxyl vitamin D levels and the risk of mortality in the general population, Arch Intern Med 168(15): 1629-1637.
- Bischoff-Ferrari HA, Giovannucci E, Willett WC, Dietrich T, Dawson- Hughes B, et al. (2006) Estimation of optimal serum concentrations of 25-hydroxyvitamin D for multiple health outcomes. Am J Clin Nutr 84(1): 18-28.
- Amer M, Qayyam R (2013) Relationship between 25-Hydroxyvitamin D and All-Cause and Cardiovascular Disease Mortality. Am J Med 126(6): 509-514.
- Matthews LR, Ahmed Y, Dennis-Griggs D, Wilson K, Danner OK, et al. (2012) Worsening severity of vitamin D deficiency is associated with increased length of stay, surgical intensive care unit cost, and mortality rate in surgical intensive care unit patients. Am J Surg 204(1):37-43.
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- Flynn L, Zimmerman LH, McNorton K, et al. (2012) Effects of vitamin D deficiency in critically ill surgical patients. American Journal of Surgery; 203(3): 379-382.
- Venkatram S, Chilimuri S, Adrish M, Salako A, Patel M, et al. (2011) Vitamin D deficiency is associated with mortality in the medical intensive care unit. Critical Care 15(6): 292.
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- Arnson Y, Gringauz I, Itzhaky D, Amittal H (2012)Vitamin D deficiency is associated with poor outcomes and increased mortality in severely ill patients, OJM: An International Journal of Medicine 105(7): 633-639.
- Lucidarme O, Messai E, Mazzoni T, Arcade M, du Cheyron D (2010) Incidence and risk factors of vitamin D deficiency in critically ill patients: results from a prospective observational study, Intensive Care Med 36(9):1609-1611.
- Grant W (2009) Solar ultraviolet-B irradiance and vitamin D may reduce the risk of septicemia, Dermatoendocrinol 1(1): 37-42.
- Danner OK, Ruben Burbank, Diane Dennis-Griggs, Kenneth L Wilson, Frank Jones, et al. (2016) Vitamin D Insufficiency is Associated with a Higher Risk of In-Hospital Mortality in Critically-Injured Trauma Patients. EC Nutrition 4(6): 996-1005.
- Binkley N, Novotny R, Krueger D, Kawahara T, Daida YG, (2007) Low Vitamin D Status despite Abundant Sun Exposure. The Journal of Clinical Endocrinology & Metabolism 92(6): 2130-2135.
- Vieth R (1999) Vitamin D supplementation, 25-hydroxyvitamin D concentrations, and safety. Am J Clin Nutr 69(5): 842-856.
- Thacher TD, Clarke BL (2011) Vitamin D insufficiency. Mayo Clin Proc. 86(1): 50-60.
- Dawson-Hughes B, Heaney RP, Holick MF, Lips P, Meunier PJ, et al. (2005) Estimates of optimal vitamin D status, Osteoporos Int 16(7): 713-716.
- Kinyamu HK, Gallagher JC, Rafferty KA, Balhorn KE (1998) Dietary calcium and vitamin D intake in elderly women: effect on serum parathyroid hormone and vitamin D metabolites. Am J Clin Nutr 67(2): 342-348.
- Hollis BW (2004) The determination of circulating 25-hydroxyvitamin D: no easy task. J Clin Endocrinol Metab 89(7): 3149-3151.
- Hollis BW, Wagner CL (2011) Vitamin D requirements and supplementation during pregnancy. Current Opinion in Endocrinology, Diabetes and Obesity 18(6): 371-375.
- MathieuC, L Adorini (2002) The coming of age of 1,25-dihydroxyvitamin D-3 analogs as immunomodulatory agents. Trends Mol Med 8(4): 174179.
- Danner OK, Matthews LR, Francis S, Rao VN, Harvey CP, et al. (2016) Vitamin D3 suppresses class II invariant chain peptide expression on activated B-lymphocytes: a plausible mechanism for downregulation of acute inflammatory conditions. Journal of Nutrition and Metabolism pp.1-9.
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