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Carnitine Increases Glucose Disposal in Humans

Consiglio Nazionale delle Ricerche, Centro Fisiopatologia Shock, Laboratorio di Biomatematica (A.D.G., M.C.), Rome, ITALY
Istituto di Clinica Medica, Universita' Cattolica del Sacro Cuore (G.M., M.C.), Rome, ITALY

Address reprint requests to: Andrea De Gaetano, MD, PhD(Math), Laboratorio di Biomatematica, CNR—Centro Fisiopatologia Shock, UCSC—L.go Gemelli, 8—00168 Roma—ITALY

	ABSTRACT

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS CONCLUSION REFERENCES

 
Objective: The goal of this work is to assess the effect of L-carnitine on glucose disposal, particularly on insulin sensitivity, in healthy volunteers.

Methods: Fourteen healthy human volunteers were subjected to the intravenous glucose tolerance test (analyzed by means of the minimal model technique), together with indirect calorimetry and measurement of serum free fatty acids, after a bolus of glucose plus carnitine (C) or a bolus of glucose plus saline (P).

Results: The minimal model demonstrated a significant increase in glucose disposal from plasma with carnitine: Glucose effectiveness passed from 2.7%/min to 3.8%/min. No significant changes were observed in the Insulin Sensitivity Index or in Insulin/C-Peptide secretion. Calorimetry showed a significant increase in respiratory quotient, resulting from a significant increase in carbohydrate oxidation rate during carnitine administration by an average of 0.0176±0.0118 g/min (p=0.015). Energy expenditure was not modified by treatment. A smaller decrease in plasma fatty acid concentrations was noted with carnitine plus glucose than after glucose alone.

Conclusions: From these data it appears that carnitine stimulates glucose disposal and oxidation in the healthy volunteer. Therefore, carnitine might be useful as an adjunct in the therapy of diabetes mellitus.

Key words: glucose kinetics, insulin kinetics, carnitine, minimal model, theoretical models, mathematics

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS CONCLUSION REFERENCES

 
The central role of carnitine (3-hydroxy-4N-trimethylammonio-butanoate) as an intramitochondrial carrier of acyl groups is well known. Acquired or congenital carnitine deficiency results, in fact, in impaired fat oxidation [10]. Less well understood is the role that carnitine plays in carbohydrate metabolism, either directly, or indirectly through its action on fatty acids. A specific short-chain carrier system, carnitine-acetyl-transferase (CAT), present on mitochondrial membranes, catalyzes the reversible formation of the acetyl-carnitine complex. Thus carnitine acts as a carrier of acetyl groups from mitochondria to cytosol [5,17]. As shown in human skeletal muscle in vitro [17], carnitine traps acetyl-CoA by lowering the intramitochondrial acetyl-CoA/CoA-SH ratio. This stimulates the activity of pyruvate-dehydrogenase (PDH). However, the importance of this cellular mechanism on whole body glucose utilization in humans is unclear. Reports in the literature are conflicting. Some suggest no action at all of carnitine on glucose utilization [1,4,16], some maintain that carnitine administration increases glucose oxidation [5], and some claim that carnitine improves non-oxidative glucose disposal [6,13]. These studies have been based upon either simple substrate concentration [1,16,22,25], on indirect calorimetry [13,27], or on the euglycemic hyperinsulinemic clamp technique [6,13].

In the present work we study the effect of increased circulating carnitine levels on glucose metabolism in healthy subjects. Whole-body glucose uptake was measured by the Frequently Sampled I.V. Glucose Tolerance Test (IVGTT), in which plasma C-peptide, glucose and insulin concentrations were measured. Data were analyzed using the minimal model of glucose and insulin kinetics according to Bergman, Cobelli et al. [2,8,26]. This model incorporates parameters that characterize the cellular glucose uptake, the sensitivity of pancreatic ß-cells to glucose and the kinetics of the delivered insulin. Substrate oxidation and energy expenditure before and during IVGTT were estimated by indirect calorimetry.

	MATERIALS AND METHODS

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Experimental Subjects
Fourteen healthy volunteers (seven males and seven females, aged 33.8±10.9 years, weighing 65.1±11.2 kg with a Body Mass Index of 23.6±2.7, data expressed as mean±SD) participated in the study. All subjects had negative family and personal histories for diabetes mellitus and other endocrine diseases, were on no medications, had no current illness and had maintained a constant body weight for the six months preceding the study. For the three days preceding the study and until conclusion of the study each subject followed a standard composition diet (55% carbohydrate, 30% fat, 15% protein) ad libitum with at least 250 g of carbohydrates per day.

Written informed consent was obtained in all cases; the study protocol was conducted according to the Declaration of Helsinki and along the guidelines of the institutional review board of the Catholic University School of Medicine, Rome, Italy.

Procedure
Each subject was studied twice: under carnitine (C) and under placebo (P), in randomized order, with an interval of about one week. Each study was performed at 8:00 AM, after an overnight fast, with the subject supine in a quiet room with a constant temperature of 22 to 24°C.

Bilateral polyethylene IV cannulas were inserted into antecubital veins. Indirect calorimetry was started using a portable Deltatrac (Datex Instrumentarium, Helsinki, Finland) metabolic cart and continued for 40' (T-40 to T0) to establish a baseline. Calorimetric monitoring was then continued for two and one-half more hours (T0 through T150).

The standard IVGTT was performed, without the addition of Tolbutamide in order to be able to use the recorded data for pancreatic secretion evaluation: at T0 a 33% glucose solution (0.33 g Glucose/kg Body Weight) additioned with L-Carnitine (Sigma Tau, Rome, Italy; 80 mg carnitine/g Glucose administered; C study) or with an equal amount of saline (P study) was rapidly injected (less than 3 minutes) through one arm line. Blood samples (three mL each, in lithium heparin) were obtained at T-30, T-15, T0, T2, T4, T6, T8, T10, T12, T15, T20, T25, T30, T35, T40, T50, T60, T80, T100, T120, T140, T160 and T180 through the contra lateral arm vein. Each sample was immediately centrifuged and plasma was separated. Plasma glucose was measured by the glucose oxidase method (Beckman Glucose Analyzer II, Beckman Instruments, Fullerton, CA, USA). Plasma insulin and C-peptide were assayed by standard radio immunoassay technique. Plasma free fatty acids (NEFA) were measured by enzymatic spectrophotometric method (Boehringer-Mannheim Yamanouchi K.K., Tokyo, Japan) on plasma samples at 0, 6, 12, 25, 50, 100, 180 minutes. Urine was collected for each subject and urinary nitrogen measured by the Kejedahl method.

Data Analysis
Plasma glucose, insulin and C-peptide curves were fitted to the three appropriate minimal models [2,8,26] by non-linear least squares, using a Variable Metric minimization algorithm and a Runge-Kutta technique to reconstruct the predicted curve from the unsolved system of differential equations [9,23]. For C-peptide, the more robust one-compartment model was used for all subjects. For each model, the effect of carnitine on each parameter was evaluated using a backward stepwise approach as follows: The full model was specified, including both the four structural parameters G₀ through b₃ and the relative difference parameters G_0d through b_3d, the difference parameters expressing the difference between the carnitine and the placebo treatments. With the stepwise procedure, the model was fitted iteratively, and after each iteration the difference parameter with the highest relative standard error was removed until all remaining difference parameters were simultaneously significant by one-sample t test (testing the departure of the difference parameter from zero). Table 1 shows the model equations. Notice that the parameter b₁ (K₁ with the carnitine effect added in) is also referred to as S_G (Glucose Effectiveness) and expresses the tendency of glucose per se to increase its own disposal or decrease liver glucose output, while the insulin sensitivity index S_i, expressing the effect of insulin in increasing tissue glucose disposal, is computed as b₃/b₂ (or K₃/K₂). Similarly, while for notational convenience in the present work the parameters of the pancreatic secretion model referring to Insulin have been given names different from those referring to C-peptide, these parameters are often referred to in the literature as (b₄, b₇), h (b₅, b₈) and n (b₆, b₉). The areas under the insulin (AUC_Insulin) and C-peptide (AUC_Cpeptide) time-secretion curves were computed and subtracted in order to determine the overall percentage of hepatic insulin extraction during the time T0 to T180. While fitting the C-peptide model, the b₈ (K₈) parameter (target glycemia) was kept fixed to the corresponding b₅ (K₅) parameter of the Insulin model, previously fitted on the same subject.

	RESULTS

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Glucose Disposal
Table 2 (MM1) reports the estimates of the parameters of the tissue glucose disposal part of the Minimal Model, together with their standard errors. One positive difference parameter (b_1d), expressing the increase of glucose effectiveness (S_G=b₁) associated with carnitine administration, was shown to be significant (p=0.0401) and is reported in the table. The other difference parameters were set to zero, following the backward stepwise procedure. Fitting was good to excellent for all subjects examined, as shown by the high R-squared values.

Fig. 1, Fig. 2 and Fig. 3 show the sampled time courses and the model-derived curves for glucose, insulin and C-peptide respectively in a typical experimental subject.

View larger version (18K): [in this window] [in a new window]   Fig. 1. Time/concentration data points and fitted model curves for blood glucose in experimental subject #9. Lines are predicted concentrations; points are observed values.

View larger version (16K): [in this window] [in a new window]   Fig. 2. Time/concentration data points and fitted model curves for blood insulin in experimental subject #9.

View larger version (16K): [in this window] [in a new window]   Fig. 3. Time/concentration data points and fitted model curves for blood C-peptide in experimental subject #9.

View larger version (62K): [in this window] [in a new window]   Fig. 4. Group averages and standard errors (I-bars) for RQ during successive time periods. Shaded: placebo; hollow: carnitine. Significant differences between placebo and carnitine at (0–30') and at (30–60').

View larger version (64K): [in this window] [in a new window]   Fig. 5. Group averages and standard errors (I-bars) for EE during successive time periods. Shaded: placebo; hollow: carnitine. No significant differences between placebo and carnitine.

View larger version (31K): [in this window] [in a new window]   Fig. 6. Group averages and standard errors (I-bars) for NEFA (as % of baseline level) during successive time periods. Shaded: placebo; hollow: carnitine. Significant differences between placebo and carnitine at 6', 25' and 100'.

	DISCUSSION

Glucose oxidation rate, calculated through indirect calorimetry, was significantly increased after carnitine intravenous bolus. This is consistent with the hypothesis that carnitine-induced glucose oxidation, therefore, increased glucose disposal is at least partially responsible for the glucose mass action, even though the results obtained from the calorimetric analysis of a transient response have to be interpreted with caution.

Finally, from the NEFA data it appears that the decrease of plasma NEFA levels after glucose administration is possibly quicker but clearly smaller after carnitine than after saline; this suggests a higher amount of glucose utilization for oxidation in place of NEFA. This is in accord with Randle’s classical glucose-fatty acid cycle hypothesis [18,24], which maintains that the rates of glucose oxidation and free fatty acid oxidation vary in opposite directions compensating for the cellular choice of metabolic substrates. This has been shown to happen in humans [11,15] and is likely due to the fact that both substrates converge for final utilization into the Krebs cycle.

Few studies are available in the literature on the action of carnitine on glucose disposition, and these few trace a rather controversial picture of it.

In two series of surgical patients [1,16], no statistically significant difference was found between carnitine and placebo on the post-traumatic glycemic response, even if one of the authors [16] suggested a likely reduction of insulin resistance after carnitine administration. During strenuous exercise in humans, both with normal oxygenation and under hypoxic conditions, the administration of carnitine was observed to be associated with a reduction of the respiratory quotient [27], from which the author inferred lower rates of carbohydrate oxidation. This observation seems to be in contrast with other experiments [5,6,13,28] where carnitine was observed to induce a significant increase in glucose disposition, even under hypoxic conditions (although with a very different experimental setting: myocardial homogenates) [28]. Furthermore, it has been observed that carnitine administration has a hypoglycemic effect on diabetic rats [21,25].

There are differences in interpretation, however, on how carnitine would produce an increase in glucose disposal. Using the euglycemic hyperinsulinemic clamp technique in humans Ferrannini [13] arrived at the conclusion that while glucose oxidation is unaffected by carnitine, nonoxidative glucose disposal increases by as much as 50 percent. It is possible that, in these experimental conditions, the effect of carnitine on glucose oxidation was more difficult to observe, due to the insulinization which, by itself, substantially stimulates glucose uptake. The clamp technique was also used by Capaldo et al. [6], who showed a carnitine-induced increase in whole-body glucose utilization in NIDDM patients and ascribed it to improved insulin sensitivity. It is difficult, however, to discriminate between enhanced insulin sensitivity and insulin-independent glucose disposal during a clamp at fixed insulinization levels. Moreover, these authors did not use indirect calorimetry and were therefore unable to discriminate between non-oxidative glucose disposal and glucose oxidation. Data of Broderick et al. [5], in an isolated perfused rat heart preparation, showed that increased myocardial carnitine levels induced an increase in glucose oxidation and a corresponding decrease in FFA oxidation, resulting in no changes in the overall ATP production.

Our data in healthy humans agree with the in vitro data of Broderick et al., both as regards increased carbohydrate oxidation and decreased FFA utilization. The cellular mechanisms whereby carnitine effects its action on carbohydrate metabolism are still to be clarified. In particular, carnitine could act at the insulin receptor level, it could act by increasing transmembrane glucose transport (either insulin-dependent or insulin-independent), or it could act at a post-receptor level.

Insulin resistance is a common finding in Type 1 as well as in Type 2 diabetes. In some of these individuals, insulin resistance appears to be correlated with a functional deficiency of the receptors and can be corrected by increasing plasma insulin levels [7,14]. In most other individuals, although they show a relatively low number of receptors, increasing the insulin level does not correct the resistance, suggesting that insulin resistance is often due to a post-receptor defect: in fact, increasing insulin levels in these patients may well increase insulin resistance through receptor down-regulation [19,20]. An additional support to the post-receptor defect theory in causing insulin resistance has been furnished by the recent study of Berliner et al. [3]. These authors show that increasing the cholesterol content in cellular membranes of cultured bovine aortic endothelial cells, results in resistance to the action of insulin. This resistance is not due to a decrease in the number of insulin receptors, nor to a decrease in receptor affinity for insulin, but rather to a post-receptor defect either at the membrane level or intracellularly. Since we have evidenced its insulin-independent effect, carnitine might play a role in the therapy of diabetes mellitus by improving insulin resistance with a post-receptor mechanism.

	CONCLUSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS CONCLUSION REFERENCES

 
Carnitine seems to increase overall glucose elimination from plasma and glucose oxidation. Carnitine could thus play a role as a regulator of glucose oxidation in addition to its well-known action in fatty acid oxidation. As already indicated by animal experiments, this molecule could therefore have a role in the therapy of diabetes.

Received November 1, 1998. Accepted March 1, 1999.

	REFERENCES

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS CONCLUSION REFERENCES

 

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