|Vitamin D3||Yes||Yes||? |
4 x per day
Vitamin D, Glutamine, Evidence-Based Medicine, and Close Staff Supervision Reduce Mortality Rate at a Level I Trauma Center
Global Journal of Medical and Clinical Case Reports, Dates: Received: 03 March, 2017; Accepted: 08 March, 2017; Published: 09 March, 2017
L Ray Matthews1*, Yusuf Ahmed2, Omar K Danner2, Golda Kwaysi2, Dianne Dennis-Griggs2, Keren Aviva Bashan-Gilzenrat2, Jonathan Nguyen2, Ed W Childs2, Nekelisha Prayor2, Peter Rhee2 and Kenneth L Wilson2
'Morehouse School of Medicine, Department of Surgery, 720 Westview Drive, Atlanta, USA department of Clinical Epidemiology, SIDRA Medical and Research Center, Doha, Qatar, USA
*Corresponding author: L Ray Matthews, Morehouse School of Medicine, Department of Surgery, 720 Westview Drive, Atlanta, USA, Tel: (404)616-1415; Fax: (404)616-1417; E-mail: lematthews@msm edu; rmatt63 at yahoo.com
- Chance of dying in hospital cut in half by just 10 ng higher level of Vitamin D – April 2016
- Concussions (traumatic brain injury) getting big press coverage, vitamin D might be both a cause and a solution
- ICU death rate reduced 3X when a single dose of vitamin D changed the PTH – Nov 2015
- Vitamin D advocate (Dr. Matthews) is now in Who’s Who Marquis – Feb 2018
- ICU survival increased with vitamin D single loading dose - JAMA Sept 2014 - has the following chart
- Traumatic brain injury treated by Vitamin D Progesterone Omega-3 and glutamine – May 2013 Matthews
- Vitamin D and Glutamine resulted in 2.6X reduction in trauma center mortality rate – Dec 2014 Matthews poster
- US Army learning about benefits of vitamin D to trauma – Dec 2013 talking with Matthews
Trauma and surgery contains the followingTrauma and Surgery category has
see also Concussions
Overview Fractures and Falls and Vitamin D
Cancer - After diagnosis chemotherapy
Search VitaminDWiki for TBI OR "Traumatic Brain Injury" 481 items as of May 2018
Search VitaminDWiki for cathelecidin OR hCAP18 569 items as of April 2017
Search VitaminDWiki for ICU OR “critical care” OR “intensive care” OR “acute care” 847 items as of April 2017
Search VitaminDWiki for transplant 794 items as of Jan 2018
- Glutamine Wikipedia
"Glutamine is the most abundant naturally occurring, nonessential amino acid in the human body, and one of the few amino acids that can directly cross the blood–brain barrier. In the body, it is found circulating in the blood, as well as stored in the skeletal muscles. It becomes conditionally essential (requiring intake from food or supplements) in states of illness or injury"
- L-Glutamine Benefits, Medical Use & Side Effects March 2017
Glutamine discovered in 1893, synthetic L-Glutamine made 1935,
Early use: successful intensive care recoveries, later use by athletes
Supports the Human Immune System, Stabilizes Glucose Levels, Regulates Kidney Acid Levels, May Cure Leaky Gut
- "In 2017 it was approved by the FDA to prevent complications in sickle cell disease"
- The Benefits Of Glutamine! BodyBuilding Feb 2017
"Glutamine is the most common amino acid found in your muscles - over 61% of skeletal muscle is Glutamine. Glutamine consists of 19% nitrogen, making it the primary transporter of nitrogen into your muscle cells."
"Bodybuilders should take 10 to 15 grams of L-Glutamine a day - supplementing it 2 to 3 times daily, with each serving at around 5 grams."
- Glutamine Examine.com
"A conditionally essential amino acid which only appears to benefit the body as supplementation when otherwise deficient (vegans, vegetarians with low dairy intake) or during prolonged endurance exercise"
"Glutamine is a very effective intestinal and immune system health compound, as these cells use glutamine as the preferred fuel source rather than glucose."
"It is generally touted as a muscle builder, but has not been proven to enhance muscle building in healthy individuals; only those suffering from physical trauma such as burns or muscular wounds (knife wounds) or in disease states in which muscle wasting occurs, such as AIDS. In these individuals, however, glutamine is effective at building muscle and alleviating a decrease in muscle mass typical of the ailment."
has 130 studies
- Benefits of magnesium and its role as a glutathione cofactor ImmuneHealth
does not,unfortunately, give details
- TOP 10 GLUTAMINE SUPPLEMENTS LabDoor
- Now supplements
Chart show how quickly Glutamine leaves the bloodstream (wonder if it goes into muscle or urine)
Perhaps should take glutamine multiple times during the day
- "Glutamine: An Obligatory Parenteral Nutrition Substrate in Critical Care Therapy" 2015
"daily nutritional intake contains approximately 10 g Gln"
"The first reports of muscle Gln depletion in trauma and critical illness emerged in the late 1970s and early 1980s. Thereafter, it has been demonstrated repeatedly that critical illnesses such as trauma and/or sepsis, burns and severe acute pancreatitis (AP) are associated with profound intracellular Gln depletion."
Download the PDF from VitaminDWiki
- Glutamine – from conditionally essential to totally dispensable? - 2014
Download the PDF from VitaminDWiki
- Glutamine: An Obligatory Parenteral Nutrition Substrate in Critical Care Therapy - 2015
Download the PDF from VitaminDWiki
- Reduced brain glutamine in female varsity rugby athletes after concussion and in non-concussed athletes after a season of play 2017 10.1002/hbm.23919
- 14 Proven Benefits of Glutamine + Side Effects & Dosage Sefl-Hacked June 2018
1) L-Glutamine Is a Fuel for Gut Cell Growth and Digestive Functions
2) L-Glutamine Prevents and Repairs Leaky Gut
3) L-Glutamine Improves Gut Flow
L-Glutamine Benefits the Immune System and Supports Healing
4) L-Glutamine Supports the Immune System Against Infections
5) Glutamine for Wound Healing
6) Glutamine Decreases Side Effects of Chemotherapy
7) Glutamine Helps with Surgery Recovery
8) Glutamine Increases Nitrogen in the Body When It Is Being Depleted
9) Glutamine Prevents Decrease in Branched-Chain Amino Acids (BCAA) Levels
L-Glutamine and Exercise
10) Prolonged and Intense Exercise Use Up L-Glutamine
11) L-Glutamine Use and Muscle Building
Does L-glutamine Reduce Muscle Soreness?
Glutamine and Growth Hormone
Glutamine and Exercise Recovery
Other Health Benefits of Glutamine
12) Glutamine Protects Against Stress
13) Glutamine Protects the Heart During Heart Attacks and Surgeries
14) Glutamine Prevents Non-Alcoholic Fatty Liver Disease
What to Consider When Supplementing with Glutamine
Glutamine Side Effects
1) Glutamine Supplementation Interferes with the Absorption and Transportation of Other Amino Acids
2) Glutamine Supplementation Reduces Internal Glutamine Production
3) Glutamine Supplementation Impairs Ammonia Detoxification
4) Withdrawing from Glutamine Supplementation Causes Side Effects
5) Other Side Effects of Glutamine Supplementation
Other Glutamine Risks: Cancer
Glutamine Supplementation Contraindications and Drug Interactions
Glutamine Supplementation Dosage
My wife: 73 years old - (she had been taking lots of Vitamin D and Omega-3 - which may be important)
Tripped and hit the back of her head on the concrete floor
Mild concussion - Felt uncertain/unease for 6 days
Took teaspoon of L-Glutamine 6 days later and felt better in a few hours
Took 2nd teaspoon of L-Glutamine later that day
After taking 3rd teaspoon - she felt completely back to normal
Dr. Matthews recommended that she continue with Glutamine for 2 weeks
As a result of chart above, my wife will take it more often than 2 times per day for the 2 weeks
Update Dec 2017
Several of her friends suffering from concussion have also benefited from L-Glutamine - even 2 years after the concussion
Background: It has been estimated that over 400,000 patients die each year from medical errors in the United States. The purpose of this study was to investigate the impact of vitamin D (a steroid hormone and immune modulator) and glutamine supplementation, evidence- based medicine, and close staff supervision on hospital mortality rate in trauma patients. We hypothesized that vitamin D and glutamine supplementation, evidence-based medicine, and close staff supervision has an appreciable or measureable effect in reducing the hospital mortality rate in critically injured patients admitted to surgical intensive care units and to surgical floors.
Study Design: We performed a retrospective study of 6,258 trauma patients listed in the trauma registry who were admitted to the Trauma Service at Grady Memorial Hospital, a Level I trauma center, between January 1, 2000 and December 31, 2011. The analysis compared two groups: standard care treatment group (Control Group)) versus the evidence-based medicine treatment group (Evidence -Based Medicine Group). Trauma patients admitted from 2000-2006 (Control Group, n=3,285) were treated with standard (usual) care. Trauma patients admitted from 2007-2011 (Evidence-Based Medicine Group, n=2,973) were managed with standard care plus vitamin D and glutamine supplementation, evidence - based medicine, and close staff supervision. The primary outcome was mortality rate of the Control Group versus the Evidence-Based Medicine Group.
Results: Our study did not find any statistical difference between standard/usual treatment and evidence-based treatment groups in terms of number of admitted patients (3285 Vs. 2973), gender (76% male in both groups, and 24% female in both groups), age distribution (89% were ages between 15 to 55 in standard/usual group Vs. 89% in evidence based group), trauma type (blunt trauma; 66.6% in both groups, penetrating trauma; 33.4% in both groups) and measured blood alcohol levels (19.0% in both groups had >8mg/dl)
However the overall mortality rate for the trauma patients treated with standard/usual care group was 10.7% compared to 4.1% for the trauma patients treated with evidence-based medicine, a 6.6% absolute reduction in mortality (RRR, 61.6%, 95%CI, 2.26-3.46,P<0.0001).
Conclusion: Our study suggested that, implementation of evidence-based medicine methodology significantly reduces the mortality rate among the trauma patients treated in the Evidence-Based Medicine Group. Further studies are warranted.
In a 1999 report, “To Err Is Human & Building a Safer Health System” the Institute of Medicine (IOM) reported that medical errors are responsible for 98,000 of hospital deaths each year . IOM estimated that medical errors cost the United States about $37.6 billion each year1. Thus, medical errors resulted in a significant loss of life, increased morbidity, and placed a high financial burden on medical centers throughout the United States.
In 2003, the ACGME limited residents’ work hours (80 hours per week) in an effort to reduce medical errors [2,3]. However, no study to date has shown any statistical difference in the reduction of preventable medical errors and mortality rates since resident duty hours went into effect . Although sleep deprivation is a contributing factor, a lack of clinical knowledge and clinical judgement and vitamin D deficiency are the main culprits.
Vitamin D levels less than 18 ng/mL are associated with an increase of all-cause mortality rate of 30%. Vitamin D is a pleotropic steroid hormone that controls 3,000 out of xxxx human genes including the immune response and the inflammatory response systems. Vitamin D levels greater than 50 ng/mL upregulate the CD4 count (T-Cell). Thus, vitamin D deficiency can result in quantitative and qualitative CD4 (T-cell) deficiencies. T-cells need vitamin D for proper immune function. Glutamine works synergistically with vitamin D as the fuel for the immune response system.
The top three causes of medical malpractice lawsuits over the past 2 decades are as follows: 1) medication errors 2) missed diagnosis and 3) a delay in diagnosis . These errors have been attributed to a lack of understanding of pharmacology (drug contraindications, dosages, side effects, and drug interactions) and basic pathophysiology, which are cognitive errors most likely secondary to gaps in clinical knowledge . Consequently, any medical educational reform efforts to reduce medical errors should focus, in part, on strengthening these cognitive aspects of training (pharmacology, pathophysiology, and evidence-based medicine). IOM estimated that 1.5 million patients suffer from mistakes involving medications that are given each year .
“Assessing blame for medical errors” rather than addressing “system errors” as the root cause of preventable medical errors is the primary impediment to improving patient safety in many teaching hospitals. Hospital administrators must take a more active role in patient safety if we want to improve patient outcome. Using the “system errors” approach, we decreased our mortality rate by 46.3%.
A retrospective study of all trauma patients admitted to Morehouse School of Medicine Trauma Services from 20002008 was performed using information contained in the Trauma Registry from the Institutional Review Board. Approval was obtained from Morehouse School of Medicine.
Basic demographic data obtained included: age, gender, type of trauma (blunt or penetrating), injury severity score (ISS), and positive alcohol and drug screen levels, (Table 1). Trauma patients were characterized into two groups: standard group (2000-2006) and exposed group (2007-2008). The exposed group of trauma patients was treated using evidence-based medicine (Table 2), vitamin D and glutamine supplementation, on and close staff supervision. The top ten cause of medical, malpractice lawsuits were used to shape the focus, af our didactic teaching curriculum and monthly surgical exams.
The primary outcome compared was in- hospital mortality rate (Figure 1). Discharge to home or to a rehabilitation facility was considered a good outcome. Statistics were analyzed using Self- Propelled Semi-Submersible statistical software version (SPSS Inc. Chicago, Illinois), Fisher exact test, unpaired t-test was used to compare similarities and differences between the groups, and a P value of less than 0.05 was considered significant.
Table 1 2000-2006 Control Group population characteristics.
Demographic information was obtained from the Trauma Registry on 4,618 patients over a 9 year period (2000-2008). The patients were divided into 2 groups (standard -vs- exposed) for comparison according to mortality rates (Table 3). Mean age and sex distribution was similar among the two groups. Approximately one-third of the trauma patients in both groups had injury severity scores (ISS)>15. The percentage of penetrating -vs- blunt trauma was also similar in both groups.
The mortality rate for the standard group was 9.3% -vs- 5.0% for the exposed group, a 46.3% reduction in mortality rate (p-value <0.0001 and odds ratio of 1.94) (Figures 2,3). There was a significant difference between the two groups for overall survival. Our study suggests that a lack of evidence- based medicine, vitamin D and glutamine supplementation, and close staff supervision are independent risk factors for mortality.
Initiatives to reduce the number of preventable deaths from medical errors have received widespread awareness, both in medical literature and in the lay press. Five years after the IOM report, Leepe and Borwick published a grim account on the lack of progress that the medical community has made in enhancing patient safety [8,9]. The mortality rates from medical errors have not changed over the last ten years since the Institute of Medicine Report. Thus, our efforts to educate and train residents in error reduction has fallen short.
Despite this pessimistic view, a few reports of improvement have been published over the last several years. Our investigators demonstrated in this report that the majority of medical errors may be due to flaws in cognitive thinking and technical errors. Being proactive and taking ownership of patient safety results in significant reduction in medical errors and patient mortality rate . By incorporating policies and addressing patient safety in medical care education, a hospital may decrease its mortality rate by 20 to 70%5. We conclude that this study shows that mortality rates and medical errors can be reduced appreciably using evidence-based medicine, didactic teaching and monthly surgical exams, and close staff supervision.
In our study, residents were given immediate, nonthreatening feedback from Morbidity and Mortality Conference, Morning Report, and the Trauma Outcome Registry Committee (TORC) about medical errors and preventable deaths [11,12]. Residents received monthly written exams on surgical diagnosis, treatment, pathophysiology and pharmacology. A teaching file on all medical errors was created to teach residents how to avoid the many pitfalls in medicine [13-16]. We were able to reduce our overall trauma mortality rate from 9.3% to 5%, a 46.3% reduction in mortality rate over a two year period using this multidimensional approach.
Despite the growing body of evidence that links most medical errors with flaws in cognitive thinking, graduate medical education programs continue to pay insufficient attention to the importance of pharmacology (medicine errors) and pathophysiology (missed diagnosis and delay in treatment). However, the real culprit may be the lack of cognitive medical knowledge and vitamin D deficiency.
The safety record of the health care system is a far cry from the enviable record of the similarly complex aviation industry [17-19]. The equivalent of 390 jumbo jets full of people die each year due to preventable medical errors, making this the 5th leading cause of death in the United States, states Dr. Samantha Collier, Vice President of Medical Affairs at Health Grades. The IOM says that the health care system is at least a decade behind the aviation industry in safeguarding consumer lives and health.
In a December 2002 the Kaiser Family Foundation survey, indicated only 5% of physicians identified medical errors as a top health care concern. We will not become safe until we choose to become safe. Despite technological advances, preventing medical errors will always depend on the vigilance of health care professionals.
Vitamin D deficiency has been shown to be associated with over 100 different chronic diseases [20-24]. Vitamin D is one of the strongest anti-inflammatory and antimicrobial agents known.
We conclude that evidence based medicine, vitamin D and glutamine supplementation, and close staff supervision reduce hospital mortality rates. Further studies are needed.
- Kohn LT, Corrigan JM, Donaldson MS (2000) To Err Is Human. Building a Safer Health System. Natl Acad Press 26-48. Link: https://goo.gl/8jle4v
- 2008 Resident Duty Hours: Enhancing sleep, supervision, and safety: Committee on optimizing graduate medical trainee (Resident) hours and work schedules to improve patient safety. Washington, DC: Natl Acad Press.
- Barger LK, Ayas NT, Cade BE, Cronin JW, Rosner B, et al. (2006) Impact of extended- duration shifts on medical errors, adverse events, and attention failures. PLOS Med 3: e4B7 Link: https://goo.gl/yZNCgW
- Salim A, Teixeira PG, Chan L, Oncel D, Inaba K, et al. (2007) Impact of the 80- hour workweek on patient care at a Level I trauma center. Arch Surg 142: 708-714 Link: https://goo.gl/OSJQNU
- Glabman M (2004) The top ten malpractice claims [and how to minimize them]. Trustee magazine. Hosp Health Netw 78: 60-62. Link: https://goo.gl/2LRrXs
- Stripe SC, Best LC, Cole-Harding S, Fifield B, Talebdoost F (2006) Aviation model cognitive risk factors applied to medical malpractice cases. J Am Board Fam Med 19: 627-632. Link:
- Kohn LT, Corrigan JM, Donaldson MS (2006) Preventing Medication Errors. Washington, DC: Natl Acad Press 26-48.
- Leape L, Berwick D (2005) Five years after To Err is Human - What have we learned? JAMA 293:2384-2390. Link: https://goo.gl/u4w3pv
- Leave L (1994) Error in Medicine. JAMA 272: 1851- 18857. Link: https://goo.gl/tVP2CV
- Hilfiker D (1984) Facing our Mistakes. N Engl J Med 310: 118-122. Link: https://goo.gl/lhG9mX
- Piernissi E, Fisher MA, Campbell AR, Landefeld CS (2003) Discussion of medical errors in morbidity and mortality conferences. JAMA 209: 28382842. Link: https://goo.gl/lfbqC7
- Wu Aw, Folkman S, McPhee SJ, Lo B (1991) Do house officers learn from their mistakes? JAMA 265:2089- 2094. Link: https://goo.gl/dAZddV
- Rogers DA Regehr G, MacDonald J (2002) A role for error training in surgical technical skill instruction and evaluation. AM J Surg 183: 242-245. Link: https://goo.gl/MNqjV6
- Bann S, Khan M, Darzi A (2005) Surgical skill is predicated by the ability to detect errors. Am J Surg 189:412-415. Link: https://goo.gl/istJAk
- Bogner MS (1994) Human Error In Medicine Building a Safer Health System. Lawrence Erlbaum Associate 53.
- Newman-Toker DE, Pronovost PJ (2009). Diagnostic Errors- The next frontier for patient safety. JAMA 301:1060-1062. Link: https://goo.gl/lnoyxT
- Rivers RM, Swain D, Nixon WR (2003) Using aviation safety measures to enhance patient outcomes. AORN J 77:158-162. Link: https://goo.gl/lij6zQ
- Shojania KG, Wald H, Gross R (2002) Understanding medical error and improving patient safety in the inpatient setting. Med Clin North Am 86:847867 Link: https://goo.gl/zcD4Wh
- Grogan EL, Stiles RA France DJ, Speroff T, Morris JA (2004) The impact of Aviation- Based teamwork training on the attitudes of health care professionals. J Am Coll Surg 199:843-848. Link: https://goo.gl/nLYl6G
- Matthews LR, Ahmed Y, Wilson KL, Griggs DD, Danner OK (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." The American Journal of Surgery 204: 37-43. Link: https://goo.gl/gxqcOo
- Matthews LR, Ahmed Y, Wilson KL, Griggs DD, Danner OK, et al. (2012) "Combination Therapy with Vitamin D3, Progesterone, Omega 3-Fatty Acids, and Glutamine Reverses Coma and Improves Clinical Outcomes in Patients with Severe Traumatic Brain Injuries: A Case Series of Three Patients”. International Journal of Case Reports and Images 4: 143-149 Link: https://goo.gl/20NvTE
- Matthews LR, Gustafson C (2015) "Leslie Ray Matthews, MD: Enhanced Surgical Outcomes and Boosted Soft-tissue Wellness from Vitamin D Supplementation," Matthews, LR, Gustafson; PMID; 26026147 (PubMed - indexed for Medline). Altern Ther Health Med 21: 68-72 Link: https://goo.gl/3QAmYe
- Matthews LR, Ahmed Y, Wilson KL, Griggs DO, Danner OK et al. (2016) 'Vitamin D3 Suppresses Class II Invariant Chain Peptides Expression on Activated B Lymphocytes: A Plausible Mechanism for Down-Regulation of Acute Inflammatory Conditions"; Hindawi Publishing Corporation, Journal of Nutrition and Metabolism 2016:8. Link: https://goo.gl/f4p4Jy
- Matthews LR (2015) “Daily High Dose Vitamin D Supplementation Reduces the Incidence of Myocardial Infarctions in Surgical Intensive Care Unit Patients" Abstract accepted - October 2015, Oral Presentation at the "6th International Conference on Clinical and Experimental Cardiology". Link: https://goo.gl/XX5PDc
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