| width = | alt = Structural formula, conjugate acid | image2 = Beta-Hydroxy beta-methylbutyrate 2.svg | width2 = | alt2 = Structural formula, conjugate base | caption = Top: β-Hydroxy β-methylbutyric acid
Bottom: β-Hydroxy β-methylbutyrate | pronounce = | Drugs.com = | MedlinePlus = | licence_EU = | licence_US = | pregnancy_AU = | pregnancy_AU_comment = | pregnancy_US = | pregnancy_US_comment = | pregnancy_category= | routes_of_administration = By mouth or nasogastric | legal_AU = | legal_AU_comment = | legal_CA = | legal_CA_comment = | legal_DE = | legal_DE_comment = | legal_NZ = | legal_NZ_comment = | legal_UK = | legal_UK_comment = | legal_US = OTC | legal_US_comment = | legal_UN = Unscheduled | legal_UN_comment = | legal_status = | bioavailability = | protein_bound = | metabolism = | metabolites = HMB-CoA, HMG-CoA, mevalonate, cholesterol, acetyl-CoA, acetoacetate, β-hydroxybutyrate | onset = HMB-FA: 30–60 minutes
HMB-Ca: 1–2 hours | elimination_half-life = HMB-FA: 3 hours
HMB-Ca: 2.5 hours | duration_of_action = | excretion = Renal (10–40% excreted) | CAS_number = 625-08-1 | CAS_supplemental = | CAS_number_Ref = | ATC_prefix = none | PubChem = 69362 | IUPHAR_ligand = | DrugBank = | DrugBank_Ref = | ChemSpiderID = 62571 | ChemSpiderID_Ref = | UNII = 3F752311CD | UNII_Ref = | KEGG = C20827 | KEGG_Ref = | ChEBI = 37084 | ChEBI_Ref = | ChEMBL = | NIAID_ChemDB = | synonyms = Conjugate acid form:
Conjugate base form:
hydroxymethylbutyrate | C=5 | H=10 | O=3 | SMILES = CC(C)(CC(=O)O)O | StdInChI_Ref = | StdInChI = 1S/C5H10O3/c1-5(2,8)3-4(6)7/h8H,3H2,1-2H3,(H,6,7) | StdInChIKey_Ref = | StdInChIKey = AXFYFNCPONWUHW-UHFFFAOYSA-N | density = ~1.1 | density_notes = at 20 °C | solubility = | melting_point = −80 | melting_high = | melting_notes = (glass) | boiling_point = 128 | boiling_notes = at 7 mmHg }}
β-Hydroxy β-methylbutyric acid[note 1] (HMB), otherwise known as its conjugate base, β-hydroxy β-methylbutyrate, is a naturally produced substance in humans that is used as a dietary supplement and as an ingredient in certain medical foods that are intended to promote wound healing and provide nutritional support for people with muscle wasting due to cancer or HIV/AIDS.[sources 1] In healthy adults, supplementation with HMB has been shown to increase exercise-induced gains in muscle size, muscle strength, and lean body mass, reduce skeletal muscle damage from exercise, improve aerobic exercise performance, and expedite recovery from exercise.[sources 2] Medical reviews and meta-analyses indicate that HMB supplementation also helps to preserve or increase lean body mass and muscle strength in individuals experiencing age-related muscle loss.[note 2] HMB produces these effects in part by stimulating the production of proteins and inhibiting the breakdown of proteins in muscle tissue. No adverse effects from long-term use as a dietary supplement in adults have been found.
HMB is a metabolite of L-leucine and is produced in the body through oxidation of the ketoacid of L-leucine (α-ketoisocaproic acid). Since only a small fraction of L-leucine is metabolized into HMB, pharmacologically active concentrations of the compound in blood plasma and muscle can only be achieved by supplementing HMB directly. A healthy adult produces approximately 0.3 grams of HMB per day, while supplemental HMB is usually taken in doses of 3–6 grams per day. HMB is sold as a dietary supplement at a cost of about US$30–50 per month when taking 3 grams per day. HMB is also contained in several nutritional products, including certain formulations of Ensure, Juven, and Myoplex. HMB is also present in insignificant quantities in certain foods, such as alfalfa, asparagus, avocados, cauliflower, grapefruit, and catfish.
The effects of HMB on human skeletal muscle were first discovered by Steven L. Nissen at Iowa State University in the mid-1990s. As of 2018,[update] HMB has not been banned by the National Collegiate Athletic Association, World Anti-Doping Agency, or any other prominent national or international athletic organization. In 2006, only about 2% of college student athletes in the United States used HMB as a dietary supplement. As of 2017, HMB has found widespread use as an ergogenic supplement among young athletes.
HMB is sold as an over-the-counter dietary supplement in the free acid form, β-hydroxy β-methylbutyric acid (HMB-FA), and as a monohydrated calcium salt of the conjugate base, calcium β-hydroxy β-methylbutyrate monohydrate (HMB-Ca, CaHMB). Since only a small fraction of HMB's metabolic precursor, L-leucine, is metabolized into HMB, pharmacologically active concentrations of the compound in blood plasma and muscle can only be achieved by supplementing HMB directly. A healthy adult produces approximately 0.3 grams per day, while supplemental HMB is usually taken in doses of 3–6 grams per day. HMB is sold at a cost of about US$30–50 per month when taken in doses of 3 grams per day. HMB is also contained in several nutritional products and medical foods marketed by Abbott Laboratories (e.g., certain formulations of Ensure, Juven, and Myoplex), and is present in insignificant quantities in certain foods, such as alfalfa, asparagus, avocados, cauliflower, grapefruit, and catfish.
Supplemental HMB has been used in clinical trials as a treatment for preserving lean body mass in muscle wasting conditions, particularly sarcopenia, and has been studied in clinical trials as an adjunct therapy in conjunction with resistance exercise. Based upon two medical reviews and a meta-analysis of seven randomized controlled trials, HMB supplementation can preserve or increase lean muscle mass and muscle strength in sarcopenic older adults.[note 2] HMB does not appear to significantly affect fat mass in older adults. Preliminary clinical evidence suggests that HMB supplementation may also prevent muscle atrophy during bed rest. A growing body of evidence supports the efficacy of HMB in nutritional support for reducing, or even reversing, the loss of muscle mass, muscle function, and muscle strength that occurs in hypercatabolic disease states such as cancer cachexia; consequently, the authors of two 2016 reviews of the clinical evidence recommended that the prevention and treatment of sarcopenia and muscle wasting in general include supplementation with HMB, regular resistance exercise, and consumption of a high-protein diet.
Clinical trials that used HMB for the treatment of muscle wasting have involved the administration of 3 grams of HMB per day under different dosing regimens. According to one review, an optimal dosing regimen is to administer it in one 1 gram dose, three times a day, since this ensures elevated plasma concentrations of HMB throughout the day; however, as of June 2016[update] the best dosing regimen for muscle wasting conditions is still being investigated.
Some branded products that contain HMB (i.e., certain formulations of Ensure and Juven) are medical foods that are intended to be used to provide nutritional support under the care of a doctor in individuals with muscle wasting due to HIV/AIDS or cancer, to promote wound healing following surgery or injury, or when otherwise recommended by a medical professional.[sources 3] Juven, a nutrition product which contains 3 grams of HMB-Ca, 14 grams of L-arginine, and 14 grams of L-glutamine per two servings, has been shown to improve lean body mass during clinical trials in individuals with AIDS and cancer, but not rheumatoid cachexia. Further research involving the treatment of cancer cachexia with Juven over a period of several months is required to adequately determine treatment efficacy.
With an appropriate exercise program, dietary supplementation with 3 grams of HMB per day has been shown to increase exercise-induced gains in muscle size, muscle strength and power, and lean body mass, reduce exercise-induced skeletal muscle damage,[note 3] and expedite recovery from high-intensity exercise.[sources 2] Based upon limited clinical research, HMB supplementation may also improve aerobic exercise performance and increase gains in aerobic fitness when combined with high-intensity interval training. These effects of HMB are more pronounced in untrained individuals and athletes who perform high intensity resistance or aerobic exercise. HMB produces these effects in part by stimulating myofibrillar muscle protein synthesis and inhibiting muscle protein breakdown through various mechanisms, including the activation of mechanistic target of rapamycin complex 1 (mTORC1) and inhibition of proteasome-mediated proteolysis in skeletal muscles.
The efficacy of HMB supplementation for reducing skeletal muscle damage from prolonged or high-intensity exercise is affected by the time that it is used relative to exercise. The greatest reduction in skeletal muscle damage from a single bout of exercise has been shown to occur when HMB-Ca is ingested 1–2 hours prior to exercise or HMB-FA is ingested 30–60 minutes prior to exercise.
In 2006, only about 2% of college student athletes in the United States used HMB as a dietary supplement. As of 2017, HMB has found widespread use as an ergogenic supplement among athletes. As of 2018,[update] HMB has not been banned by the National Collegiate Athletic Association, World Anti-Doping Agency, or any other prominent national or international athletic organization.
The safety profile of HMB in adult humans is based upon evidence from clinical trials in humans and animal studies. In humans, no adverse effects in young adults or older adults have been reported when HMB is taken in doses of 3 grams per day for up to a year. Studies on young adults taking 6 grams of HMB per day for up to 2 months have also reported no adverse effects. Studies with supplemental HMB on young, growing rats and livestock have reported no adverse effects based upon clinical chemistry or observable characteristics; for humans younger than 18, there is limited data on the safety of supplemental HMB. The human equivalent dose of HMB for the no-observed-adverse-effect level (NOAEL) that was identified in a rat model is approximately 0.4 g/kg of body weight per day.[note 4]
Two animal studies have examined the effects of HMB supplementation in pregnant pigs on the offspring and reported no adverse effects on the fetus. No clinical testing with supplemental HMB has been conducted on pregnant women, and pregnant and lactating women are advised not to take HMB by Metabolic Technologies, Inc., the company that grants licenses to include HMB in dietary supplements, due to a lack of safety studies.
Several components of the signaling cascade that mediates the HMB-induced increase in human skeletal muscle protein synthesis have been identified in vivo. Similar to HMB's metabolic precursor, L-leucine, HMB has been shown to increase protein synthesis in human skeletal muscle via phosphorylation of the mechanistic target of rapamycin (mTOR) and subsequent activation of mTORC1, which leads to protein biosynthesis in cellular ribosomes via phosphorylation of mTORC1's immediate targets (i.e., the p70S6 kinase and the translation repressor protein 4EBP1).[note 5] Supplementation with HMB in several non-human animal species has been shown to increase the serum concentration of growth hormone and insulin-like growth factor 1 (IGF-1) via an unknown mechanism, in turn promoting protein synthesis through increased mTOR phosphorylation. Based upon limited clinical evidence in humans, supplemental HMB appears to increase the secretion of growth hormone and IGF-1 in response to resistance exercise.
As of May 2016[update], the signaling cascade that mediates the HMB-induced reduction in muscle protein breakdown has not been identified in living humans, although it is well-established that it attenuates proteolysis in humans in vivo. Unlike L-leucine, HMB attenuates muscle protein breakdown in an insulin-independent manner in humans.[note 6] HMB is believed to reduce muscle protein breakdown in humans by inhibiting the 19S and 20S subunits of the ubiquitin–proteasome system in skeletal muscle and by inhibiting apoptosis of skeletal muscle nuclei via unidentified mechanisms.
Based upon animal studies, HMB appears to be metabolized within skeletal muscle into cholesterol, which may then be incorporated into the muscle cell membrane, thereby enhancing membrane integrity and function. The effects of HMB on muscle protein metabolism may help stabilize muscle cell structure. One review suggested that the observed HMB-induced reduction in the plasma concentration of muscle damage biomarkers (i.e., muscle enzymes such as creatine kinase and lactate dehydrogenase) in humans following intense exercise may be due to a cholesterol-mediated improvement in muscle cell membrane function.[note 3]
HMB has been shown to stimulate the proliferation, differentiation, and fusion of human myosatellite cells in vitro, which potentially increases the regenerative capacity of skeletal muscle, by increasing the protein expression of certain myogenic regulatory factors (e.g., myoD and myogenin) and gene transcription factors (e.g., MEF2). HMB-induced human myosatellite cell proliferation in vitro is mediated through the phosphorylation of the mitogen-activated protein kinases ERK1 and ERK2. HMB-induced human myosatellite differentiation and accelerated fusion of myosatellite cells into muscle tissue in vitro is mediated through the phosphorylation of Akt, a serine/threonine-specific protein kinase.
The free acid (HMB-FA) and monohydrated calcium salt (HMB-Ca) forms of HMB have different pharmacokinetics. HMB-FA is more readily absorbed into the bloodstream and has a longer elimination half-life (3 hours) relative to HMB-Ca (2.5 hours). Tissue uptake and utilization of HMB-FA is 25–40% higher than for HMB-Ca. The fraction of an ingested dose that is excreted in urine does not differ between the two forms.
After ingestion, HMB-Ca is converted to β-hydroxy β-methylbutyrate following dissociation of the calcium moiety in the gut. When the HMB-Ca dosage form is ingested, the magnitude and time at which the peak plasma concentration of HMB occurs depends on the dose and concurrent food intake. Higher HMB-Ca doses increase the rate of absorption, resulting in a peak plasma HMB level (Cmax) that is disproportionately greater than expected of a linear dose-response relationship and which occurs sooner relative to lower doses.[note 7] Consumption of HMB-Ca with sugary substances slows the rate of HMB absorption, resulting in a lower peak plasma HMB level that occurs later.[note 7]
HMB is eliminated via the kidneys, with roughly 10–40% of an ingested dose being excreted unchanged in urine. The remaining 60–90% of the dose is retained in tissues or excreted as HMB metabolites. The fraction of a given dose of HMB that is excreted unchanged in urine increases with the dose.[note 8]
Biosynthesis and metabolism of β-hydroxy β-methylbutyrate in humans
The metabolism of HMB is catalyzed by an uncharacterized enzyme which converts it to β-hydroxy β-methylbutyryl-CoA (HMB-CoA). HMB-CoA is metabolized by either enoyl-CoA hydratase or another uncharacterized enzyme, producing β-methylcrotonyl-CoA (MC-CoA) or hydroxymethylglutaryl-CoA (HMG-CoA) respectively. MC-CoA is then converted by the enzyme methylcrotonyl-CoA carboxylase to methylglutaconyl-CoA (MG-CoA), which is subsequently converted to HMG-CoA by methylglutaconyl-CoA hydratase. HMG-CoA is then cleaved into acetyl-CoA and acetoacetate by HMG-CoA lyase or used in the production of cholesterol via the mevalonate pathway.
HMB is synthesized in the human body through the metabolism of L-leucine, a branched-chain amino acid. In healthy individuals, approximately 60% of dietary L-leucine is metabolized after several hours, with roughly 5% (2–10% range) of dietary L-leucine being converted to HMB.
The vast majority of L-leucine metabolism is initially catalyzed by the branched-chain amino acid aminotransferase enzyme, producing α-ketoisocaproate (α-KIC). α-KIC is mostly metabolized by the mitochondrial enzyme branched-chain α-ketoacid dehydrogenase, which converts it to isovaleryl-CoA. Isovaleryl-CoA is subsequently metabolized by isovaleryl-CoA dehydrogenase and converted to MC-CoA, which is used in the synthesis of acetyl-CoA and other compounds. During biotin deficiency, HMB can be synthesized from MC-CoA via enoyl-CoA hydratase and an unknown thioesterase enzyme, which convert MC-CoA into HMB-CoA and HMB-CoA into HMB respectively. A relatively small amount of α-KIC is metabolized in the liver by the cytosolic enzyme 4-hydroxyphenylpyruvate dioxygenase (KIC dioxygenase), which converts α-KIC to HMB. In healthy individuals, this minor pathway – which involves the conversion of L-leucine to α-KIC and then HMB – is the predominant route of HMB synthesis.
β-Hydroxy β-methylbutyric acid is a monocarboxylic β-hydroxy acid and natural product with the molecular formula C5H10O3. At room temperature, pure β-hydroxy β-methylbutyric acid occurs as a transparent, colorless to light yellow liquid which is soluble in water. β-Hydroxy β-methylbutyric acid is a weak acid with a pKa of 4.4. Its refractive index () is 1.42.
β-Hydroxy β-methylbutyric acid is a member of the carboxylic acid family of organic compounds. It is a structural analog of butyric acid with a hydroxyl functional group and a methyl substituent located on its beta carbon. By extension, other structural analogs include β-hydroxybutyric acid and β-methylbutyric acid.
Depending on the experimental conditions, cycloaddition of acetone and ketene produces either β-isovalerolactone or 4,4-dimethyloxetan-2-one, both of which hydrolyze under basic conditions to yield the conjugate base of HMB. The haloform reaction provides another pathway to HMB involving the exhaustive halogenation of the methyl-ketone region of diacetone alcohol with sodium hypobromite or sodium hypochlorite; Diacetone alcohol is readily available from the aldol condensation of acetone. An organometallic approach to HMB involves the carboxylation of tert-butyl alcohol with carbon monoxide and Fenton's reagent (hydrogen peroxide and ferrous iron). Alternatively, HMB can be prepared through microbial oxidation of β-methylbutyric acid by the fungus Galactomyces reessii.
|Blood plasma||Adults (18+)||4.0||0–10.0||μM|||
|Breast milk||Adults (18+)||–||42–164||μg/L|||
|Urine||Adults (18+)||–||3.2–25.0||μmol/mmol creatinine|||
|Urine||Children (1–18)||–||0–68||μmol/mmol creatinine|||
The concentration of naturally produced HMB has been measured in several human body fluids using nuclear magnetic resonance spectroscopy, liquid chromatography–mass spectrometry, and gas chromatography–mass spectrometry methods. In the blood plasma and cerebrospinal fluid (CSF) of healthy adults, the average molar concentration of HMB has been measured at 4.0 micromolar (μM). The average concentration of HMB in the intramuscular fluid of healthy men of ages 21–23 has been measured at 7.0 μM. In the urine of healthy individuals of any age, the excreted urinary concentration of HMB has been measured in a range of 0–68 micromoles per millimole (μmol/mmol) of creatinine. In the breast milk of healthy lactating women, HMB and L-leucine have been measured in ranges of 42–164 μg/L and 2.1–88.5 mg/L. In comparison, HMB has been detected and measured in the milk of healthy cows at a concentration of <20–29 μg/L. This concentration is far too low to be an adequate dietary source of HMB for obtaining pharmacologically active concentrations of the compound in blood plasma.
In a study where participants consumed 2.42 grams of pure HMB-FA while fasting, the average plasma HMB concentration increased from a basal level of 5.1 μM to 408 μM after 30 minutes. At 150 minutes post-ingestion, the average plasma HMB concentration among participants was 275 μM.
Abnormal HMB concentrations in urine and blood plasma have been noted in several disease states where it may serve as a diagnostic biomarker, particularly in the case of metabolic disorders. The following table lists some of these disorders along with the associated HMB concentrations detected in urine or blood plasma.
|Medical condition||Biofluid||Age group||Concentration||Sources|
|Biotinidase deficiency†||Blood||Adults (18+)||9.5||0–19.0||μM|||
|Biotinidase deficiency†||Blood||Children (1–13)||88.0||10.0–166.0||μM|||
|Biotinidase deficiency†||Urine||Children (1–13)||275.0||50.0–500.0||μmol/mmol creatinine|||
|3-Methylglutaconic aciduria (Type I)†||Urine||Children (1–13)||200.0||150.0–250.0||μmol/mmol creatinine|||
|Eosinophilic esophagitis||Urine||Children (1–13)||247.4||0–699.4||μmol/mmol creatinine|||
|Gastroesophageal reflux disease||Urine||Children (1–13)||119.8||5.5–234.0||μmol/mmol creatinine|||
|HMG-CoA lyase deficiency†||Urine||Children (1–13)||2030.0||60.0–4000.0||μmol/mmol creatinine|||
|MC-CoA carboxylase deficiency†||Urine||Children (1–13)||30350.0||1700.0–59000.0||μmol/mmol creatinine|||
|A † indicates that the medical condition is a metabolic disorder.|
The first reported chemical synthesis of HMB was published in 1877 by the Russian chemists Michael and Alexander Zaytsev. HMB was isolated from the bark of Erythrophleum couminga (a Madagascan tree) in 1941 by Leopold Ružička. The earliest reported isolation of HMB as a human metabolite was by Tanaka and coworkers in 1968 from a patient with isovaleric acidemia.
The effects of HMB on human skeletal muscle were first discovered by Steven L. Nissen at Iowa State University in the mid-1990s. Nissen founded a company called Metabolic Technologies, Inc. (MTI) around the time of his discovery, which later acquired six HMB-related patents that the company has used to license the right to manufacture and incorporate HMB into dietary supplements. When it first became available commercially in the late 1990s, HMB was marketed solely as an exercise supplement to help athletes and bodybuilders build muscle. MTI subsequently developed two HMB-containing products, Juven and Revigor, to which Abbott Nutrition obtained the market rights in 2003 and 2008 respectively. Since then, Abbott has marketed Juven as a medical food and the Revigor brand of HMB as an active ingredient in food products for athletes (e.g., certain formulations of Myoplex) and other medical foods (e.g., certain formulations of Ensure).
The [International Society of Sports Nutrition] has concluded the following. 1. HMB can be used to enhance recovery by attenuating exercise induced skeletal muscle damage in trained and untrained populations. ... 4. Thirty-eight mg·kg·BM−1 daily of HMB has been demonstrated to enhance skeletal muscle hypertrophy, strength, and power in untrained and trained populations when the appropriate exercise prescription is utilized. ... 8. HMB’s mechanisms of action include an inhibition and increase of proteolysis and protein synthesis, respectively. 9. Chronic consumption of HMB is safe in both young and old populations.
• Use under medical supervision.
• HMB + protein for muscle health.
• Administer orally or as a modular via feeding tube ...
• Use under medical supervision.
• Nutravigor® (CaHMB, calcium β-hydroxy-β-methylbutyrate)
Experimental Boiling Point: ... 128 °C / 7 mm ...Unknown parameter
Soluble in water
Chemical Names: Beta-Hydroxyisovaleric acid; 3-Hydroxy-3-methylbutanoic acid; ... 3-Hydroxyisovaleric acid; 3-Hydroxy-3-methylbutyric acidUnknown parameter
Dr. Nissen and his collaborator Dr. Naji N. Abumrad, Professor and Chair, Department of Surgery, Vanderbilt University, discovered beta-hydroxy-beta-methylbutyrate (HMB) and its beneficial effects on human health and performance. HMB is currently marketed nationally by Abbott Laboratories as Revigor™, which is a component of Ensure® Muscle Health, and Juven®, which is a nutritional beverage that is clinically shown to promote healing after injury or surgery.Unknown parameter
The questions about what defines a medical food will likely grow as the market does—and that market now extends far beyond PKU and other inherited metabolic disorders. ... Abbott Nutrition's Juven provides nutrients to people with HIV or AIDS experiencing excessive weight loss due to diseaseUnknown parameter
Overall, this meta-analysis indicates that HMB can prevent lean body mass loss in older adults. But the effects of HMB on muscle strength and physical function appears to vary in different populations. Additional well-designed clinical studies are necessary to confirm the effectiveness of HMB in the prevention of loss of muscle strength and physical function. ... Mechanisms underlying the role of HMB in muscle regeneration have also been explored: results indicated that HMB enhances protein synthesis via upregulation of anabolic signaling pathways and attenuate proteolysis via downregulation of catabolic signaling pathways (Wilkinson et al., 2013).
The reports summarized here indicate that HMB provides a number of benefits to subjects involved in strength-power and endurance sports. The effects on muscle mass and strength, particularly during resistance training, are likely related to the suppression of proteolysis and a positive effect on protein synthesis. Its benefits in aerobic performance are probably more associated with improved mitochondrial biogenesis and fat oxidation. Favourable effects on the recovery from exercise-induced damage may be related to the role of HMB as a precursor of cholesterol, which modulates membrane fluidity and affects ion channels, and membrane excitability. ... Studies have demonstrated that HMB can prevent the development of sarcopenia in elderly subjects and that the optimal action of HMB on muscle growth and strength occurs when it is combined with exercise.Unknown parameter
Clinical trials performed in older adults confirm that HMB can attenuate the progression of sarcopenia in elderly subjects. HMB supplementation results in an increase in skeletal muscle mass and strength in the elderly and its effect is even greater when combined with physical exercise.
HMB's mechanisms of action are generally considered to relate to its effect on both muscle protein synthesis and muscle protein breakdown (Figure 1) [2, 3]. HMB appears to stimulate muscle protein synthesis through an up-regulation of the mammalian/mechanistic target of rapamycin complex 1 (mTORC1), a signaling cascade involved in coordination of translation initiation of muscle protein synthesis [2, 4]. Additionally, HMB may have antagonistic effects on the ubiquitin–proteasome pathway, a system that degrades intracellular proteins [5, 6]. Evidence also suggests that HMB promotes myogenic proliferation, differentiation, and cell fusion . ... Exogenous HMB-FA administration has shown to increase intramuscular anabolic signaling, stimulate muscle protein synthesis, and attenuate muscle protein breakdown in humans .
The stimulation of MPS through mTORc1-signalling following HMB exposure is in agreement with pre-clinical studies (Eley et al. 2008). ... Furthermore, there was clear divergence in the amplitude of phosphorylation for 4EBP1 (at Thr37/46 and Ser65/Thr70) and p70S6K (Thr389) in response to both Leu and HMB, with the latter showing more pronounced and sustained phosphorylation. ... Nonetheless, as the overall MPS response was similar, this cellular signalling distinction did not translate into statistically distinguishable anabolic effects in our primary outcome measure of MPS. ... Interestingly, although orally supplied HMB produced no increase in plasma insulin, it caused a depression in MPB (−57%). Normally, postprandial decreases in MPB (of ~50%) are attributed to the nitrogen-sparing effects of insulin since clamping insulin at post-absorptive concentrations (5 μU ml−1) while continuously infusing AAs (18 g h−1) did not suppress MPB (Greenhaff et al. 2008), which is why we chose not to measure MPB in the Leu group, due to an anticipated hyperinsulinaemia (Fig. 3C). Thus, HMB reduces MPB in a fashion similar to, but independent of, insulin. These findings are in-line with reports of the anti-catabolic effects of HMB suppressing MPB in pre-clinical models, via attenuating proteasomal-mediated proteolysis in response to LPS (Eley et al. 2008).
In conclusion, HMB treatment clearly appears to be a safe potent strategy against sarcopenia, and more generally against muscle wasting, because HMB improves muscle mass, muscle strength, and physical performance. It seems that HMB is able to act on three of the four major mechanisms involved in muscle deconditioning (protein turnover, apoptosis, and the regenerative process), whereas it is hypothesized to strongly affect the fourth (mitochondrial dynamics and functions). Moreover, HMB is inexpensive (~30– 50 US dollars per month at 3 g per day) and may prevent osteopenia (Bruckbauer and Zemel, 2013; Tatara, 2009; Tatara et al., 2007, 2008, 2012) and decrease cardiovascular risks (Nissen et al., 2000). For all these reasons, HMB should be routinely used in muscle-wasting conditions especially in aged people. ... 3 g of CaHMB taken three times a day (1 g each time) is the optimal posology, which allows for continual bioavailability of HMB in the body (Wilson et al., 2013)
Normally, an individual metabolizes 60 g of L-LEU to obtain 3 g of HMB but a 70 kg person produces 0.2–0.4 g of HMB per day, depending on the dose of LEU in the diet (Van Koevering and Nissen 1992). ... The usual dose of 3 g/day may be routinely recommended to maintain or improve muscle mass and function in health and disease. The safety profile of HMB is unequivocal. ... These results show that HMB/ARG/GLN can be safely used to treat AIDS- and cancer-related muscle wasting
One study tested the safety of HMB for long-term use in rats. Fuller et al. (50) conducted a 91-d study with the use of Sprague-Dawley rats that tested the safety of β-hydroxy-β-methylbutyric free acid (HMBFA). This new form of HMB results in higher HMB serum concentrations than CaHMB. In this study, rats were administered an HMBFA intervention of 0%, 0.8%, 1.6%, or 4% of the diet by body weight. The highest dose is the equivalent of ~400 mg ⋅ kg−1 ⋅ d−1 for humans. No adverse advents were observed for any treatment group. Similarly, blood and urine analyses were within the normal range in all groups, with no group differences. The authors concluded that HMBFA was safe for consumption in a rat model. ... No serious side effects have been reported with leucine, EAA, or HMB supplementation; and the health risks associated with these supplements are few and predictable.
Studies suggest dietary protein and leucine or its metabolite β-hydroxy β-methylbutyrate (HMB) can improve muscle function, in turn improving functional performance. ... These have identified the leucine metabolite β-hydroxy β-methylbutyrate (HMB) as a potent stimulator of protein synthesis as well as an inhibitor of protein breakdown in the extreme case of cachexia. ... A growing body of evidence suggests HMB may help slow, or even reverse, the muscle loss experienced in sarcopenia and improve measures of muscle strength. ... However, dietary leucine does not provide a large amount of HMB: only a small portion, as little as 5%, of catabolized leucine is metabolized into HMB. ... Thus, although dietary leucine itself can lead to a modest stimulation of protein synthesis by producing a small amount of HMB, direct ingestion of HMB more potently affects such signaling, resulting in demonstrable muscle mass accretion. ... Indeed, a vast number of studies have found that supplementation of HMB to the diet may reverse some of the muscle loss seen in sarcopenia and in hypercatabolic disease. ... The overall treatment of muscle atrophy should include dietary supplementation with HMB, although the optimal dosage for each condition is still under investigation. ...
Figure 4: Treatments for sarcopenia. It is currently recommended that patients at risk of or suffering from sarcopenia consume a diet high in protein, engage in resistance exercise, and take supplements of the leucine metabolite HMB.
HMB is an active leucine metabolite which activates the mTOR signaling pathway in muscle. Following its absorption, dietary leucine is converted into α-ketoisocaproate (KIC), which is further metabolized into either isovaleryl-CoA or HMB. Under normal conditions, the majority of KIC is converted into isovaleryl-CoA, while only approximately 5% of leucine is metabolized to HMB. This implies that, in order to reach pharmacological levels of HMB, this compound needs to be administered directly, rather than via increasing leucine dosage. ... HMB exerts its effects through protective, anticatabolic mechanisms and directly influences protein synthesis. HMB has also been shown to stabilize the muscle cell membrane, to modulate protein degradation and to up-regulate protein synthesis .
Currently, HMB is available as an over-the-counter supplement. The drug is not tested for nor banned by any sporting organization. ... Wilson et al.  demonstrated that when non-resistance trained males received HMB pre-exercise, the rise of lactate dehydrogenase (LDH) levels reduced, and HMB tended to decrease soreness. Knitter et al.  showed a decrease in LDH and creatine phosphokinase (CPK), a byproduct of muscle breakdown, by HMB after a prolonged run. ... The utility of HMB does seem to be affected by timing of intake prior to workouts and dosage . Further, chronic consumption of HMB appears safe . ... No serious adverse effects from HMB consumption have been reported.
Recently, the free acid form of HMB (HMB-FA) has become commercially available in capsule form (gelcap). The current study was conducted to compare the bioavailability of HMB using the two commercially available capsule forms of HMB-FA and Ca-HMB. ... In conclusion, HMB-FA in capsule form improves clearance rate and availability of HMB compared with Ca-HMB in capsule form.
Cholesterol is a major component of the cell membrane, and sarcolemma is the one that relies mainly on de novo synthesis of cholesterol. This is important under stressful conditions when muscle cells may lack the capacity to produce adequate amounts of the cholesterol that is essential to proper functioning of cell membranes. Many biochemical studies have shown that HMB may be a precursor of cholesterol synthesis (Bachhawat et al., 1955; Bloch et al., 1954; Coon et al., 1955; Adamson and Greenberg, 1955; Gey et al., 1957). According to pertinent literature, HMB carbon is incorporated into cholesterol. Therefore, increased intramuscular HMB concentrations may provide readily available substrate for the cholesterol synthesis that is needed to form and stabilize the sarcolemma. ... It is known that HMB supplementation decreases post-exercise levels of enzymes, indicating muscle damage, such as creatinine phosphokinase (CK) and lactate dehydrogenase (LDH), which suggests an enhancement of the muscle cell membrane function. This was shown in numerous studies in humans undergoing both resistance and endurance training (Wilson et al., 2013) ... In theory, HMB use as a precursor to cholesterol could aid in stabilizing muscle cell membranes; however, this has not been confirmed by research studies. The effect of HMB on protein metabolism may in fact help stabilize muscle structure more than any effect HMB may have on cholesterol metabolism in the cell.
HMB was discovered in the mid-1990s by Steve Nissen, a researcher at Iowa State UniversityUnknown parameter
HMB is widely used as an ergogenic supplement by young athletes. ... This study shows that in healthy older adult, HMB supplementation may preserve muscle mass during 10 days of bed rest. These results are encouraging, but need to be confirmed by other groups.
There are a number of nutrition products on the market that are touted to improve sports performance. HMB appears to be the most promising and to have clinical applications to improve muscle mass and function. Continued research using this nutraceutical to prevent and/or improve malnutrition in the setting of muscle wasting is warranted.
Looking at studies with proteins and other dietary supplements the combination of HMB, arginine, and glutamine showed interesting results ... In one study, 32 patients gained an average of about 2 kg of body weight. This study was one of three studies confirming the positive effects of this combination in a variety of diagnoses/conditions such as HIV/AIDS patients and healthy adults. Another study, on a far larger sample base of around 470 cancer patients, found no significant difference with regard to LBM after 8 weeks however a strong trend in the direction of an increase in LBM as measured by both bio-impedance and skin-fold measurements. In summary, the effect of the combination of HMB, arginine, and glutamine on weight gain should be investigated in further studies on cancer patients investigating time periods of several months.
More than 20 publications in humans have demonstrated benefit with HMB supplementation associated with increased lean body mass without fat gain, improved markers of muscle strength, and decreased onset of muscle soreness with training and reduced markers of muscle damage. ... One proposed cellular mechanism for HMB is principally through stabilization of the cholesterol membrane in muscle cells. HMB is metabolized to β-hydroxy-β-methylglutaryl-coenzyme A (HMG-CoA) in the cytosol of muscle cells, which in turn is converted to cholesterol. ... Muscle produces its own cholesterol to maintain the integrity of the cell membrane, typically from HMG-CoA, because it cannot supply its cholesterol needs via absorption from the circulation.
HMB, a derivative of leucine, prevents muscle damage and increases muscle strength by reducing exercise-induced proteolysis in muscles and also helps in increasing lean body mass. ... HMB is converted to HMB-CoA which is then used for the synthesis of cholesterol in muscle cells (Nissen and Abumrad, 1997). Cholesterol is needed for the growth, repair, and stabilization of cellular membranes during exercise (Chen, 1984). ... The meta analysis studies and the individual studies conducted support the use of HMB as an effective aid to increase body strength, body composition, and to prevent muscle damage during resistance training.
Pregnant or lactating women are advised against taking HMB because safety studies have not yet been conducted for these populations.Unknown parameter
The mechanisms underlying the anabolic effects of food intake involve both the stimulation of MPS (Rennie et al. 1982) and suppression of MPB (Wilkes et al. 2009). The potent increase in MPS is driven almost entirely by essential amino acids (EAAs) (Smith et al. 1992), with the branched chain AA (BCAA: leucine, isoleucine and valine), in particular leucine [and its metabolite(s), e.g. β‐hydroxy β‐methylbutyric acid (HMB) (Van Koevering & Nissen 1992)] being central to these effects (Wilkinson et al. 2013). Although the mechanisms underlying the unique anabolic properties of leucine are incompletely defined, recent work in yeast and cultured mammalians cells has demonstrated that leucyl tRNA synthetase is upstream of activating the hitherto ‘cellular AA sensor’, the mechanistic target of rapamycin complex 1 (mTORC1) in response to leucine (Bonfils et al. 2012, Han et al. 2012). This was reaffirmed by experiments showing that of all the EAAs, leucine is the most effective EAA in increasing the activity (i.e. phosphorylation) of mTORC1 (Atherton et al. 2010b) and its substrates.
Reduced activity of MCC impairs catalysis of an essential step in the mitochondrial catabolism of the BCAA leucine. Metabolic impairment diverts methylcrotonyl CoA to 3-hydroxyisovaleryl CoA in a reaction catalyzed by enoyl-CoA hydratase (22, 23). 3-Hydroxyisovaleryl CoA accumulation can inhibit cellular respiration either directly or via effects on the ratios of acyl CoA:free CoA if further metabolism and detoxification of 3-hydroxyisovaleryl CoA does not occur (22). The transfer to carnitine by 4 carnitine acyl-CoA transferases distributed in subcellular compartments likely serves as an important reservoir for acyl moieties (39–41). 3-Hydroxyisovaleryl CoA is likely detoxified by carnitine acetyltransferase producing 3HIA-carnitine, which is transported across the inner mitochondrial membrane (and hence effectively out of the mitochondria) via carnitine-acylcarnitine translocase (39). 3HIA-carnitine is thought to be either directly deacylated by a hydrolase to 3HIA or to undergo a second CoA exchange to again form 3-hydroxyisovaleryl CoA followed by release of 3HIA and free CoA by a thioesterase.
Energy fuel: Eventually, most Leu is broken down, providing about 6.0kcal/g. About 60% of ingested Leu is oxidized within a few hours ... Ketogenesis: A significant proportion (40% of an ingested dose) is converted into acetyl-CoA and thereby contributes to the synthesis of ketones, steroids, fatty acids, and other compoundsUnknown parameter
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