Hostname: page-component-cd9895bd7-dk4vv Total loading time: 0 Render date: 2024-12-23T00:47:36.682Z Has data issue: false hasContentIssue false

Comparison of availability and plasma clearance rates of β-hydroxy-β-methylbutyrate delivery in the free acid and calcium salt forms

Published online by Cambridge University Press:  16 September 2015

John C. Fuller Jr
Affiliation:
Metabolic Technologies Inc., Iowa State University Research Park, Ames, IA 50010, USA
Rick L. Sharp
Affiliation:
Department of Kinesiology, Iowa State University, Ames, IA 50010, USA
Hector F. Angus
Affiliation:
Department of Kinesiology, Iowa State University, Ames, IA 50010, USA
Paul Y. Khoo
Affiliation:
Department of Kinesiology, Iowa State University, Ames, IA 50010, USA
John A. Rathmacher*
Affiliation:
Metabolic Technologies Inc., Iowa State University Research Park, Ames, IA 50010, USA Department of Animal Science, Iowa State University, Ames, IA 50010, USA
*
*Corresponding author: Dr J. A. Rathmacher, fax +1 515 296 0908, email [email protected]
Rights & Permissions [Opens in a new window]

Abstract

β-Hydroxy-β-methylbutyrate (HMB), a leucine metabolite, has long been supplemented as a Ca salt (Ca-HMB) to increase strength and performance gains with exercise and to reduce recovery time. 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. We also compared the pharmacokinetics of each form when administered mixed in water. Ten human subjects (five male and five female) were studied in a randomised crossover design. There was no significant sex by treatment interaction for any of the pharmacokinetic parameters measured. HMB-FA administered in capsules was more efficient than Ca-HMB capsule at HMB delivery with a 37 % increase in plasma clearance rate (74·8 (sem 4·0) v. 54·5 (sem 3·2) ml/min, P<0·0001) and a 76 % increase in peak plasma HMB concentration (270·2 (sem 17·8) v. 153·9 (sem 17·9) μmol/l, P<0·006), which was reached in one-third the time (P<0·009). When HMB-FA and Ca-HMB were administered in water, the differences still favoured HMB-FA, albeit to a lesser degree. Plasma HMB with HMB-FA administered in water was greater during the early phase of absorption (up to 45 min postadministration, P<0·05); this resulted in increased AUC during the first 60 min after administration, when compared with Ca-HMB mixed in water (P<0·03). In conclusion, HMB-FA in capsule form improves clearance rate and availability of HMB compared with Ca-HMB in capsule form.

Type
Full Papers
Copyright
Copyright © The Authors 2015 

The leucine metabolite β-hydroxy-β-methylbutyrate (HMB) has a long history of use as a nutritional supplement for enhancing recovery, and for increasing strength, power, aerobic performance and lean body mass with exercise( Reference Nissen, Sharp and Ray 1 Reference Wilson, Fitschen and Campbell 5 ). HMB improves muscle protein balance by decreasing muscle protein breakdown and by increasing muscle protein synthesis( Reference Eley, Russell and Tisdale 6 Reference Wilkinson, Hossain and Hill 11 ), resulting in reduced muscle damage and faster and improved recovery( Reference Knitter, Panton and Rathmacher 3 , Reference Wilson, Kim and Lee 12 , Reference Wilson, Lowery and Joy 13 ). These benefits with HMB to improve muscle performance with vigorous exercise have generally been achieved with the Ca salt of HMB (Ca-HMB) administered in capsule form. However, as shown in previous studies, and confirmed by the findings of the current study, peak plasma levels of HMB are not reached until approximately 120 min after ingestion of Ca-HMB, which makes it inconvenient for scheduling exercise sessions to coincide with peak plasma HMB levels( Reference Vukovich, Slater and Macchi 14 , Reference Fuller, Sharp and Angus 15 ). In this study, we show that the time to peak HMB level decreased by two-thirds when HMB was delivered as the free acid in capsule form (HMB-FA), thus making it more convenient to time peak HMB level with exercise.

The anabolic stimulus of exercise results in an increase in muscle protein synthesis in as little as 1 h postexercise( Reference Dreyer, Fujita and Cadenas 16 ), and it can persist for up to 48 h postexercise( Reference Phillips, Tipton and Aarsland 17 ). These anabolic events are also accompanied by depletion of muscle energy stores in the form of glycogen, resulting in decreased exercise intensity, and associated with increased muscle damage( Reference Kerksick, Harvey and Stout 18 Reference Coyle, Coggan and Hemmert 20 ). The changes have been attributed to increased skeletal muscle AMP-activated protein kinase activity and reduced phosphorylation of 4E-BP1 in the mTOR pathway, as occurs with resistance exercise( Reference Dreyer, Fujita and Cadenas 16 ). HMB supplementation has been shown to increase phosphorylation of 4E-BP1 in human muscle( Reference Wilkinson, Hossain and Hill 11 ), prompting us to hypothesise that HMB as HMB-FA would offer a more convenient delivery form resulting in an improved anabolic effect of HMB on muscle protein synthesis and diminishing protein breakdown.

Other metabolic effects of HMB have been demonstrated in animal models. Turkeys fed HMB during the last 15 weeks of rearing had increased bone density and strength and an increase in some plasma amino acids including the branched-chain amino acids( Reference Tatara 21 ). Tatara et al. ( Reference Tatara, Krupski and Tymczyna 22 ) also demonstrated increased growth and bone density, and increased growth hormone (GH) and insulin-like growth factor-1 (IGF-1), in offspring of sows fed HMB for the final 2 weeks of pregnancy; increased bone density and plasma amino acid concentrations in pigs with fundectomy-induced osteopaenia( Reference Tatara, Sliwa and Krupski 23 ); and improved somatotrophic axis and accelerated bone metabolism in lambs fed HMB for the first 21 d after birth( Reference Tatara 24 ). The improvement in somatotrophic axis function was further demonstrated in rats when chronic HMB administration was shown to stimulate the GH/IGF-1 axis( Reference Gerlinger-Romero, Guimaraes-Ferreira and Giannocco 25 ). Recently, HMB supplementation was shown to enhance the exercise-stimulated increase in GH and IGF-1 response in humans, similar to what the previous studies in animals had demonstrated( Reference Townsend, Hoffman and Gonzalez 26 ).

The pharmacokinetics of orally ingested Ca-HMB in capsules were originally described by Vukovich et al. ( Reference Vukovich, Slater and Macchi 14 ) and showed a time to peak plasma level of HMB of 2 h after a 1 g dosage. Recently, Fuller et al. ( Reference Fuller, Sharp and Angus 15 ) demonstrated that HMB-FA gel form increased plasma HMB concentrations in a shorter period of time (30–40 min) with a greater blood clearance rate of HMB compared with the Ca-HMB capsule. A recent 12-week exercise study by Wilson et al. ( Reference Wilson, Lowery and Joy 27 ) used these favourable advantages to test the efficacy of HMB-FA administered 30 min before exercise in a periodised training programme and showed increased strength, lean body mass gain and muscle power in a highly trained athlete population( Reference Wilson, Lowery and Joy 27 ), demonstrating the importance of dosage timing and peak levels of HMB for maximisation of exercise benefits. The current human study was thus designed to compare the pharmacokinetics of the current commercially available delivery form of Ca-HMB in a capsule and compared this with the newly designed delivery form of HMB-FA in a gelcap. Our results confirmed the previous findings of Fuller et al. ( Reference Fuller, Sharp and Angus 15 ) and showed that HMB-FA had superior bioavailability in humans as assessed by blood levels, and improved clearance.

Methods

Human subjects

We performed a randomised crossover study consisting of five men and five women (aged 21–32 years). The study was conducted according to the guidelines laid down in the Declaration of Helsinki, and all procedures involving human subjects were approved by the Iowa State University Institutional Review Board. Written informed consent was obtained from all subjects before participation. The study was listed on ClinicalTrials.gov (NCT01914952, https://clinicaltrials.gov). The subjects were not currently taking amino acid, protein or HMB supplements.

Treatments

The treatments were given to each subject in random order with at least a 48 h washout period between treatments. The treatments were as follows: (1) Ca-HMB in a commercial gelatin capsule (Optimum Nutrition); (2) HMB-FA capsule (gelcap) (Capsugel); (3) HMB-FA as a gel as previously described( Reference Fuller, Sharp and Angus 15 ); (4) Ca-HMB mixed in water or (5) HMB-FA mixed in water. All treatments delivered 0·8 g of HMB orally, confirmed by HPLC analysis, and were given with 355 ml of water. Although the pH of the free acid itself is <3, this is similar to the pH of the stomach. For the treatments used in this study, the free acid was given either in capsule form, a buffered gel form or as a dilute solution in water. In contrast, the Ca-HMB is neutral to slightly alkaline when in solution. None of the participants reported any oesophageal or gastrointestinal irritations with any of the treatment forms of HMB. For the capsule treatments, samples of the capsules were sent to an independent laboratory and tested for dissolution times (Eurofins). Because of the nature of the various treatments, the study could not be fully blinded.

Study design

All studies were conducted after a 10- to 12-h overnight fast. Subjects arrived at the laboratory in the morning, and an intravenous catheter was inserted into a forearm vein using sterile procedures. A preingestion blood sample, of approximately 7 ml, was drawn. The treatment was then consumed over approximately a 2 min period, and additional blood samples (7 ml) were taken at 2, 5, 10, 15, 25, 35, 45, 60, 90, 120, 180, 360 (6 h), 720 (12 h) and 1440 (24 h) min after the ingestion of the supplement; 24 h urine collection was also obtained. Plasma and urine samples were stored at −80°C until later analyses of HMB. Serum and blood samples at times 0 and 1440 min were analysed by a commercial laboratory (LabCorp.) for glucose, uric acid, blood urea nitrogen, creatinine, Na, K, Cl, Ca, CO2, P, protein, albumin, globulin, total bilirubin, alkaline phosphatase, estimated glomerular filtration rate (eGFR), creatine kinase, lactate dehydrogenase, aspartate aminotransferase, alanine aminotransferase, γ-glutamyl transpeptidase, Fe, TAG, HDL, LDL, VLDL and cholesterol; a complete blood count was also performed. Subjects completed a brief health questionnaire to report any physical symptoms (such as nausea, headache and so on) they may have experienced during the experiment.

After the 180 min blood sampling, each subject was provided with a standardised lunch (1673·6–2092 kJ (400–500 kcal)), which was consumed at approximately 240 min postingestion; the subjects returned to the laboratory for the 720 min blood sample. Each subject was then instructed to eat a normal evening meal before 22.00 hours. Subjects were also instructed to refrain from any strenuous physical activity or exercise during each testing period, and diet and activity patterns were to be replicated for each treatment testing period. Subjects reported back to the laboratory the following morning for the fasted 1440 min blood sample. Urine collection containers were provided, and subjects collected all urine produced during the 24 h experimental period. The urine was stored refrigerated when possible.

Plasma and urine β-hydroxy-β-methylbutyrate analysis

The plasma and urine HMB were analysed as previously described using GC/MS( Reference Nissen, Van Koevering and Webb 28 ). Briefly, HMB in the free acid form is quantified from standards using d6-HMB as an internal standard. This method has a CV of approximately 4·1 %.

Statistical analysis and calculations

The AUC was calculated for each subject using the trapezoidal method that sums the area above the baseline( Reference Urso, Blardi and Giorgi 29 ). The following equations were used in the calculation of the half-life of plasma HMB:

(1) $$K_{{_{{{\rm el}}} }} ={{\ln \left( {C_{{_{{{\rm peak}}} }} } \right){\minus}\ln \left( {C_{{_{{{\rm trough}}} }} } \right)} \over {T_{{_{{_{{{\rm interval}}} }} }} }},$$
(2) $$t_{{_{{{\rm 1/2}}} }} ={{0\! \cdot\! 693} \over {K_{{_{{{\rm el}}} }} }}.$$

The peak plasma concentration was the highest HMB concentration at a measured time point for each subject and was used for C peak. Trough concentrations, C trough, were the concentrations measured at 12 h, which were not significantly different from baseline concentrations. The T peak was the time at which C peak was measured for each subject and T interval was 12 h (time at C trough) minus T peak. The extracellular fluid compartment was assumed to be 20 % of body weight. V d was calculated using equation (3) below( Reference Guyton and Hall 30 ). The plasma clearance of HMB was calculated by multiplying the extracellular fluid compartment, V d , by the elimination constant, K el, as shown in equation (4)( Reference Thalhammer, Schenk and Burgmann 31 ).

(3) $$V_{{_{d} }} ={\rm Body}\,{\rm weight}\left( {0\! \cdot\! 20} \right),$$
(4) $${\rm Clearance}=V_{d} \left( {K_{{{\rm el}}} } \right).$$

The data for comparable treatments were analysed using a crossover design with the general linear models (GLM) procedure in SAS( 32 ). A priori power analysis (G*Power, version 3.1.7) was completed based on our previously published pharmacokinetic study( Reference Fuller, Sharp and Angus 15 ). Assuming a similar degree of variability, a power analysis indicated that ten subjects were required to detect a P value of 0·05 at a power of 0·90 in a crossover designed study. A repeated-measures polynomial model was used for the timed sampling of plasma HMB, and the model included subject, treatment order, treatment main effects and time by treatment interaction where appropriate. For other parameters, Proc GLM was used with subject, treatment order and treatment main effects included in the model, and the P values are reported for the treatment main effect. Although the study was neither designed nor powered to detect sex differences, sex by treatment interaction was determined by GLM. In addition, the main effects of Ca-HMB and HMB-FA when given in water and by capsule were determined using GLM and least square means, and these data are shown in online Supplementary Table S3. Statistical significance was determined for P<0·05.

Results

Subject characteristics

Subject characteristics of the five male and five female subjects are shown Table 1. The average age of the subjects was 25·1 (sem 1·0) years and the average weight and BMI were 69·1 (sem 3·1) kg and 23·0 (sem 0·8) kg, respectively. The male subjects had greater body weights (P<0·05) and BMI (P<0·05) than the female subjects; however, there were no significant sex by treatment interactions for any of the pharmacokinetic parameters measured, even though all subjects were administered the same HMB dose.

Table 1 Subject descriptors (Mean values with their standard errors)

Free acid form of β-hydroxy-β-methylbutyrate gel kinetics

The HMB-FA gel treatment in the present study showed similar pharmacokinetics as we had previously shown( Reference Fuller, Sharp and Angus 15 ). HMB-FA in a gel had no comparator in the current study. The C peak was 261·7 (sem 15·0) µmol/l at 35·5 (sem 4·0) min postadministration. The half-life of HMB delivered in the gel form was 2.24 (sem 0·10) h and the AUC was 54·1 (sem 3·1) µmol/l×1440 min. The clearance from plasma was 71·7 (sem 3·6) ml/min, and 24·6 (sem 4·4) % of the dosage was excreted in urine over the 24 h study.

Acute β-hydroxy-β-methylbutyrate kinetics for capsule and water administration

The 3 h plasma HMB pharmacokinetics for subjects administered the HMB-FA and Ca-HMB capsule treatments are shown in Fig. 1(a). Compared with Ca-HMB capsules, HMB-FA administration in capsules resulted in significantly greater plasma levels at all time points from 15 to 120 min after administration (P<0·001 at 15, 25, 35, 45, 60 and 90 min and P<0·05 at 120 min). The 180 min AUC was 75 % greater (P<0·001) for the HMB-FA in capsule form. In addition, administration of HMB-FA in capsule form resulted in 76 % greater peak levels (P<0·006) in one-third the time (P<0·009). The dissolution time of the capsules could not account for these results; it was 13 min for the HMB-FA capsules and 5 min for the Ca-HMB capsules, thus favouring the release of Ca-HMB from the capsules.

Fig. 1 (a) The 3 h plasma levels of β-hydroxy-β-methylbutyrate (HMB) after administration of either free acid form of HMB (HMB-FA) gelcaps (-●-) or Ca salt of HMB (Ca-HMB) capsule (- -○-). (b) The 3 h plasma levels of HMB after administration of either HMB-FA mixed in water (-●-) or Ca-HMB mixed in water (- -○-). All treatments contained 0·8 g of HMB. Values are means with their standard error of means for five men and five women. Significance between the treatments is indicated as follows: * P<0·05; ** P<0·004; and *** P<0·001. The inset table shows the peak concentration reached (C peak), time to reach peak concentration (T peak) and AUC. The P value indicated is for differences between the treatment means.

Fig. 1(b) shows the 3 h plasma HMB pharmacokinetics for the administration of HMB-FA and Ca-HMB when mixed in water. Administration of HMB-FA in water resulted in greater plasma HMB levels at 15, 25, 35 and 45 min (P<0·05, 0·001, 0·004, and P<0·05, respectively). The inset shows that HMB-FA administered in water had a significantly greater AUC during the first hour of administration (P<0·03). Compared with Ca-HMB administered in water, the C peak tended to be greater for HMB-FA in water, whereas the T peak level was not different between the HMB-FA and Ca-HMB treatments.

24 h β-hydroxy-β-methylbutyrate kinetics for capsule and water administration

Fig. 2(a) shows the 24 h plasma HMB levels in subjects given either Ca-HMB or HMB-FA in capsule form. As shown in the inset, the HMB-FA capsule administration resulted in a 37 % increased clearance of HMB from plasma (P<0·0001), resulting in a 29 % decrease in half-life (P<0·0003). The 24 h AUC for HMB and for urinary excretion rates were the same for both forms.

Fig. 2 (a) The 24 h plasma levels of β-hydroxy-β-methylbutyrate (HMB) after administration of either free acid form of HMB (HMB-FA) gelcaps (-●-) or Ca salt of HMB (Ca-HMB) capsule (- -○-). (b) The 24 h plasma levels of HMB after administration of either HMB-FA mixed in water (-●-) or Ca-HMB mixed in water (- -○-). All treatments contained 0·8 g of HMB. See Fig. 1 for significant differences in plasma HMB concentrations in the initial 3 h. Values are means with their standard error of means for five men and five women. The inset table shows the half-life, clearance, 24 h AUC and 24 h urinary excretion of HMB. The P value indicated is for differences between the treatment means.

Similarly, Fig. 2(b) shows the 24 h plasma HMB levels in subjects given either Ca-HMB or HMB-FA mixed in water. We noted significant differences in plasma HMB levels during the first hour, with no further observed differences during the 24 h measurement period. As seen in the inset, there were also no differences observed for plasma HMB half-life, clearance rates or AUC over the 24 h measurement period. In addition, 24 h urinary excretion as a percentage of the initial dose was the same for both treatments.

Blood chemistry and haematology

There were no untoward effects of the treatments on blood chemistries or haematology and the data are presented in online Supplementary Tables S1 and S2.

Discussion

In this study, we tested the human pharmacokinetics of the two commercially available forms of HMB, used for the promotion of muscular strength and mass. Our results demonstrate that, irrespective of the capsule delivery form used, HMB-FA is more readily available and has a higher clearance rate than Ca-HMB (Fig. 2(a)), indicative of higher efficiency and faster utilisation. All human studies to date have consistently demonstrated the superiority of the HMB-FA form to reach a higher HMB plasma peak in a much shorter time than the Ca-HMB form, with similar urinary excretion of HMB( Reference Vukovich, Slater and Macchi 14 , Reference Fuller, Sharp and Angus 15 ). When Ca-HMB was administered, peak plasma HMB levels were 115( Reference Vukovich, Slater and Macchi 14 ), 131( Reference Fuller, Sharp and Angus 15 ) and 131 µmol/l( Reference Fuller, Sharp and Angus 15 ), which were comparable to the 154 µmol/l determined in the current study. Previous studies with HMB-FA found the peak plasma HMB levels to be 259( Reference Fuller, Sharp and Angus 15 ) and 239 µmol/l( Reference Fuller, Sharp and Angus 15 ) for the gel form, which was equivalent to the levels, 262 and 270 µmol/l for the gel and gelcap, respectively, in the current study. Similarly, the times to peak HMB level previously determined for Ca-HMB administration were 120( Reference Vukovich, Slater and Macchi 14 ), 122( Reference Fuller, Sharp and Angus 15 ) and 135 min( Reference Fuller, Sharp and Angus 15 ), which are comparable to the 134 min in the current study. When HMB-FA was administered in a gel, the times to peak levels were 33( Reference Fuller, Sharp and Angus 15 ) and 42 min( Reference Fuller, Sharp and Angus 15 ), and in the current study the times to peak level for HMB-FA as a gel and gelcap were 36 and 45 min, respectively. Urinary losses were similar across all studies and dosage forms, and including our present study were between 14 and 25 % of the dosage( Reference Vukovich, Slater and Macchi 14 , Reference Fuller, Sharp and Angus 15 ). The findings have several practical implications for the average athlete. Although both forms of HMB are equally effective on muscle function and are equally retained by the body over a 24 h period, the use of HMB-FA allows for more predictive timing of intake of HMB in relation to the planned exercise, thus achieving better outcomes, as was recently confirmed by Wilson et al. ( Reference Wilson, Lowery and Joy 27 ).

Our human data differ considerably from the recently published data in rodents( Reference Shreeram, Johns and Subramaniam 33 ), which reported that Ca-HMB had better availability as measured by peak blood levels when compared with HMB-FA. In that study, the investigators compared Ca-HMB with HMB-FA administration both orally in a liquid suspension and by intravenous injection,( Reference Shreeram, Johns and Subramaniam 33 ) and showed that similar amounts of HMB given as either Ca-HMB or HMB-FA resulted in the Ca-HMB having greater peak blood HMB concentrations. There are several concerns with comparison with the rodent study; the most notable is the concern related to species differences. For example, the half-life of HMB in blood after Ca-HMB dosing is reported as approximately 1, 2 and 3 h for the rat, pig and sheep, respectively( Reference Shreeram, Johns and Subramaniam 33 Reference Van Koevering and Nissen 35 ), compared with humans, with a half-life of 2·4 to 3·2 h for a 1 g dosage of Ca-HMB( Reference Vukovich, Slater and Macchi 14 , Reference Fuller, Sharp and Angus 15 ). Other concerns relate to the experimental design, and the analytical methods used, as well as methodological differences related to the accuracy of HMB intake. For example, in the rodent study, there is no mention of the methodology for the administration of the oral forms in the methods section of the paper; hence, the method and accuracy of the amount given is in question. In addition, both forms of HMB were dissolved in solutions containing carboxymethylcellulose and Tween 80 with the pH adjusted to 4·5. This type of solution is likely to affect the bioavailability of the Ca-HMB by increasing its ionisation, dissociation and absorption, thus leading to overestimates of the true pharmacokinetic parameters measured. Last, but not least, there is concern related to the accuracy of the measured plasma HMB levels. The authors used warfarin, which is structurally different from the natural HMB form, as an internal standard for the LC-MS/MS measurements, in contrast to our use of a similar HMB compound, namely d6-HMB, as an internal standard( Reference Nissen, Van Koevering and Webb 36 ).

To reconcile any potential differences attributed to the delivery forms, we carried out a head-to-head comparison of an oral dose of HMB-FA and Ca-HMB given mixed in water instead of in capsule form. The data from the current study confirm our previous findings( Reference Fuller, Sharp and Angus 15 ) and demonstrate that even when delivered mixed in water HMB-FA is still superior to Ca-HMB in delivering HMB, albeit to lesser degree than when both forms are delivered in capsules. This was quite evident within the first hour of the absorptive period (Fig. 1(b)). In addition, we noted no difference in 24 h urinary excretion of HMB (Fig. 2(b)), suggesting an earlier and greater tissue availability of HMB when given in the free acid form.

Our study has few limitations, albeit minor in nature. The first limitation relates to the few number of subjects studied (n 10); this limitation, however, is countered by the use of the subjects as their own control in a crossover design. Another theoretical limitation may relate to our calculation of the amount of HMB available for tissue utilisation, as the difference between the amount consumed minus the amount excreted in the urine. This assumption would be accurate with additional measurement of HMB oxidation rates, which were not examined in this study. Wilkinson et al. ( Reference Wilkinson, Hossain and Hill 11 ) recently demonstrated that after an oral dosage of HMB-FA intramuscular HMB concentrations increased almost 14-fold from baseline at 150 min after the dose, suggestive of enhanced utilisation of HMB by human muscle following intake of HMB-FA.

In conclusion, the use of the commercially available forms of HMB as either the HMB-FA or Ca-HMB resulted in earlier and increased plasma concentrations, with increased clearance rates, when the HMB was given as HMB-FA. This finding can be used favourably by athletes to gauge their intake of HMB before an exercise bout, as recently observed by Wilson et al. ( Reference Wilson, Lowery and Joy 27 ).

Acknowledgements

The present study was funded by Metabolic Technologies, Inc., Ames, IA.

The authors’ contributions were as follows: J. A. R. designed the research. J. A. R., H. F. A., P. Y. K. and R. L. S. conducted the research including sample analysis. J. C. F. Jr analysed the data and wrote the paper. J. A. R. had primary responsibility for final content. All authors read and approved the final manuscript.

J. C. F. Jr and J. A. R. are employed by Metabolic Technologies Inc., Ames, IA. R. L. S. received funds from Metabolic Technologies to conduct the study. H. F. A. and P. Y. K. had no conflicts of interest to declare.

Supplementary Material

For supplementary material/s referred to in this article, please visit http://dx.doi.org/10.1017/S0007114515003050

References

1. Nissen, S, Sharp, R, Ray, M, et al. (1996) Effect of the leucine metabolite β-hydroxy β-methylbutyrate on muscle metabolism during resistance-exercise training. J Appl Physiol 81, 20952104.Google Scholar
2. Panton, LB, Rathmacher, JA, Baier, S, et al. (2000) Nutritional supplementation of the leucine metabolite β-hydroxy β-methylbutyrate (HMB) during resistance training. Nutr 16, 734739.Google Scholar
3. Knitter, AE, Panton, L, Rathmacher, JA, et al. (2000) Effects of β-hydroxy-β-methylbutyrate on muscle damage following a prolonged run. J Appl Physiol 89, 13401344.Google Scholar
4. Wilson, GJ, Wilson, JM & Manninen, AH (2008) Effects of beta-hydroxy-beta-methylbutyrate (HMB) on exercise performance and body composition across varying levels of age, sex, and training experience: a review. Nutr Metab (Lond) 5, 1.Google Scholar
5. Wilson, JM, Fitschen, PJ, Campbell, B, et al. (2013) International Society of Sports Nutrition Position Stand: beta-hydroxy-beta-methylbutyrate (HMB). J Int Soc Sports Nutr 10, 6.Google Scholar
6. Eley, HL, Russell, ST & Tisdale, MJ (2008) Mechanism of attenuation of muscle protein degradation induced by tumor necrosis factor alpha and angiotensin II by beta-hydroxy-beta-methylbutyrate. Am J Physiol Endocrinol Metab 295, E1417E1426.CrossRefGoogle ScholarPubMed
7. Smith, HJ, Wyke, SM & Tisdale, MJ (2004) Mechanism of the attenuation of proteolysis-inducing factor stimulated protein degradation in muscle by beta-hydroxy-beta-methylbutyrate. Cancer Res 64, 87318735.Google Scholar
8. Smith, HJ, Mukerji, P & Tisdale, MJ (2005) Attenuation of proteasome-induced proteolysis in skeletal muscle by β-hydroxy-β-methylbutyrate in cancer-induced muscle loss. Cancer Res 65, 277283.Google Scholar
9. Eley, HL, Russell, ST, Baxter, JH, et al. (2007) Signaling pathways initiated by β-hydroxy-β-methylbutyrate to attenuate the depression of protein synthesis in skeletal muscle in response to cachectic stimuli. Am J Physiol Endocrinol Metab 293, E923E931.Google Scholar
10. Eley, HL, Russell, ST & Tisdale, MJ (2008) Attenuation of depression of muscle protein synthesis induced by lipopolysaccharide, tumor necrosis factor and angiotensin II by β-hydroxy-β-methylbutyrate. Am J Physiol Endocrinol Metab 295, E1409E1416.CrossRefGoogle ScholarPubMed
11. Wilkinson, DJ, Hossain, T, Hill, DS, et al. (2013) Effects of leucine and its metabolite beta-hydroxy-beta-methylbutyrate on human skeletal muscle protein metabolism. J Physiol 591, 29112923.Google Scholar
12. Wilson, JM, Kim, JS, Lee, SR, et al. (2009) Acute and timing effects of beta-hydroxy-beta-methylbutyrate (HMB) on indirect markers of skeletal muscle damage. Nutr Metab (Lond) 6, 6.Google Scholar
13. Wilson, JM, Lowery, RP, Joy, JM, et al. (2013) ) β-Hydroxy-β-methylbutyrate free acid reduces markers of exercise-induced muscle damage and improves recovery in resistance-trained men. Br J Nutr 110, 538544.Google Scholar
14. Vukovich, MD, Slater, G, Macchi, MB, et al. (2001) ) β-Hydroxy-β-methylbutyrate (HMB) kinetics and the influence of glucose ingestion in humans. J Nutr Biochem 12, 631639.CrossRefGoogle ScholarPubMed
15. Fuller, JC Jr, Sharp, RL, Angus, HF, et al. (2011) Free acid gel form of β-hydroxy-β-methylbutyrate (HMB) improves HMB clearance from plasma in humans compared to the calcium HMB salt. Br J Nutr 105, 367372.CrossRefGoogle Scholar
16. Dreyer, HC, Fujita, S, Cadenas, JG, et al. (2006) Resistance exercise increases AMPK activity and reduces 4E-BP1 phosphorylation and protein synthesis in human skeletal muscle. J Physiol 576, 613624.CrossRefGoogle ScholarPubMed
17. Phillips, SM, Tipton, KD, Aarsland, A, et al. (1997) Mixed muscle protein synthesis and breakdown after resistance exercise in humans. Am J Physiol 273, E99E107.Google ScholarPubMed
18. Kerksick, C, Harvey, T, Stout, J, et al. (2008) International Society of Sports Nutrition Position Stand: nutrient timing. J Int Soc Sports Nutr 5, 17.CrossRefGoogle ScholarPubMed
19. American College of Sports Medicine, American Dietetic Association & Dieticians of Canada (2000) Joint position statement: nutrition and athletic performance. Med Sci Sports Exerc 32, 21302145.Google Scholar
20. Coyle, EF, Coggan, AR, Hemmert, MK, et al. (1985) Substrate usage during prolonged exercise following a preexercise meal. J Appl Physiol (1985) 59, 429433.Google Scholar
21. Tatara, MR (2009) Effect of beta-hydroxy-beta-methylbutyrate (HMB) administration on volumetric bone mineral density, and morphometric and mechanical properties of tibia in male turkeys. J Anim Physiol Anim Nutr (Berl) 93, 669677.Google Scholar
22. Tatara, MR, Krupski, W, Tymczyna, B, et al. (2012) Effects of combined maternal administration with alpha-ketoglutarate (AKG) and beta-hydroxy-beta-methylbutyrate (HMB) on prenatal programming of skeletal properties in the offspring. Nutr Metab (Lond) 9, 39.Google Scholar
23. Tatara, MR, Sliwa, E, Krupski, W, et al. (2008) 3-Hydroxy-3-methylbutyrate administration diminishes fundectomy-induced osteopenia of the lumbar spine in pigs. Nutr 24, 753760.Google Scholar
24. Tatara, MR (2008) Neonatal programming of skeletal development in sheep is mediated by somatotrophic axis function. Exp Physiol 93, 763772.CrossRefGoogle ScholarPubMed
25. Gerlinger-Romero, F, Guimaraes-Ferreira, L, Giannocco, G, et al. (2011) Chronic supplementation of beta-hydroxy-beta methylbutyrate (HMβ) increases the activity of the GH/IGF-I axis and induces hyperinsulinemia in rats. Growth Horm IGF Res 21, 5762.Google Scholar
26. Townsend, JR, Hoffman, JR, Gonzalez, AM, et al. (2015) Effects of beta-hydroxy-beta-methylbutyrate free acid ingestion and resistance exercise on the acute endocrine response. Int J Endocrinol 2015, article ID 856708.CrossRefGoogle ScholarPubMed
27. Wilson, JM, Lowery, RP, Joy, JM, et al. (2014) The effects of 12 weeks of beta-hydroxy-beta-methylbutyrate free acid supplementation on muscle mass, strength, and power in resistance trained individuals: a randomized, double-blind, placebo-controlled study. Eur J Appl Physiol 114, 12171227.Google Scholar
28. Nissen, S, Van Koevering, M & Webb, D (1990) Analysis of β-hydroxy-β-methyl butyrate in plasma by gas chromatography and mass spectrometry. Anal Biochem 188, 1719.Google Scholar
29. Urso, R, Blardi, P & Giorgi, G (2002) A short introduction to pharmacokinetics. Eur Rev Med Pharmacol Sci 6, 3344.Google Scholar
30. Guyton, AC & Hall, JE (2006) The body fluid compartments: extracellular and intracellular fluids: interstitial fluid and edema. In Textbook of Medical Physiology, pp. 291306. Philadelphia, PA: W B Saunders Company.Google Scholar
31. Thalhammer, F, Schenk, P, Burgmann, H, et al. (1998) Single-dose pharmacokinetics of meropenem during continuous venovenous hemofiltration. Antimicrob Agents Chemother 42, 24172420.Google Scholar
32. SAS Institute Inc. (1985) SAS User’s Guide: Statistics, 5th ed. Cary, NC: SAS Institute Inc.Google Scholar
33. Shreeram, S, Johns, PW, Subramaniam, S, et al. (2014) The relative bioavailability of the calcium salt of beta-hydroxy-beta-methylbutyrate is greater than that of the free fatty acid form in rats. J Nutr 144, 15491555.CrossRefGoogle ScholarPubMed
34. Nissen, SL & Abumrad, NN (1997) Nutritional role of the leucine metabolite β-hydroxy-β-methylbutyrate (HMB). J Nutr Biochem 8, 300311.Google Scholar
35. Van Koevering, M & Nissen, S (1992) Oxidation of leucine and α-ketoisocaproate to β-hydroxy-β-methylbutyrate in vivo . Am J Physiol (Endocrinol Metab) 262, E27E31.CrossRefGoogle ScholarPubMed
36. Nissen, S, Van Koevering, M & Webb, D (1990) Analysis of β-hydroxy-β-methyl butyrate in plasma by gas chromatography and mass spectrometry. Anal Biochem 188, 1719.CrossRefGoogle ScholarPubMed
Figure 0

Table 1 Subject descriptors (Mean values with their standard errors)

Figure 1

Fig. 1 (a) The 3 h plasma levels of β-hydroxy-β-methylbutyrate (HMB) after administration of either free acid form of HMB (HMB-FA) gelcaps (-●-) or Ca salt of HMB (Ca-HMB) capsule (- -○-). (b) The 3 h plasma levels of HMB after administration of either HMB-FA mixed in water (-●-) or Ca-HMB mixed in water (- -○-). All treatments contained 0·8 g of HMB. Values are means with their standard error of means for five men and five women. Significance between the treatments is indicated as follows: * P<0·05; ** P<0·004; and *** P<0·001. The inset table shows the peak concentration reached (Cpeak), time to reach peak concentration (Tpeak) and AUC. The P value indicated is for differences between the treatment means.

Figure 2

Fig. 2 (a) The 24 h plasma levels of β-hydroxy-β-methylbutyrate (HMB) after administration of either free acid form of HMB (HMB-FA) gelcaps (-●-) or Ca salt of HMB (Ca-HMB) capsule (- -○-). (b) The 24 h plasma levels of HMB after administration of either HMB-FA mixed in water (-●-) or Ca-HMB mixed in water (- -○-). All treatments contained 0·8 g of HMB. See Fig. 1 for significant differences in plasma HMB concentrations in the initial 3 h. Values are means with their standard error of means for five men and five women. The inset table shows the half-life, clearance, 24 h AUC and 24 h urinary excretion of HMB. The P value indicated is for differences between the treatment means.

Supplementary material: File

Fuller supplementary material

Tables S1-S3

Download Fuller supplementary material(File)
File 60.7 KB