Nie wieder dick – Hast du diese Interventionen schon auf dem Schirm?

Vorab: Kalorien zählen. Das ist Fakt. Wer an Esoterik und Lichtnahrung glaubt, der kann davon ausgehen, selbst bei einem Konsum von 20 Döner/Tag und einer Kilokalorienmenge von 10.000, niemals zuzunehmen.

Träume können schön sein.

Nein, ich rede hier von Möglichkeiten, die im physiologischen, also natürlichen, nicht-mensch-gemachten Bereich, außergewöhnliche Dinge leisten können hinsichtlich der Entwicklung der Körpersubstanz.

Um die Wirkweisen der folgenden Möglichkeiten zu verstehen, sollte man etwas über die eigene Physiologie, genauer: Biochemie, wissen.

Wo könnte man intervenieren? An welchen Stellen eingreifen?

• Die Fettzelle

Fettzellen können ggf. Kohlenhydrate in Fett umwandeln (das heißt Lipogenese), sie können sich vermehren (Hyperplasie) oder größer werden (Hypertrophie). Sie können aber auch einfach die gegessenen Fettsäuren aufnehmen.

Fettzellen kann man zwingen mehr von ihren gespeicherten Substraten zu oxidieren oder die Fettsäuren schneller in den Blutkreislauf abzugeben (Lipolyse).

Alle diese biochemischen Kaskaden können wir hemmen oder modulieren.

• Die Leber

Die Leber kann Fett speichern, synthetisieren oder oxidieren. Beim Menschen findet die Triglycerid- (also Fett-) Synthese hauptsächlich in der Leber statt. Das heißt: Kohlenhydrate, die nicht in der Peripherie gelagert oder oxidiert werden können, induzieren ab einer bestimmten Menge, die Fettsäuresynthese (Lipogenese) aus Kohlenhydraten. Als Folge sind die Plasma Triglyceride i. d. R. höher und es kann sich ggf. eine Fettleber entwickeln.

Auch dort kann man intervenieren, in dem man zum Beispiel die Fettsynthese hemmt, die Glukose – oder die Fettsäureoxidation steigert oder den Lipid-Transport in das Fettgewebe beschleunigt, damit keine Fettleber entstehen kann.

• Der Muskel

Der Muskel kann hoch-effizient verändert werden. Wir können die Glukoseaufnahme und – Verwertung steigern, wir können die Oxidationsraten steigern, wir können die Abnehmer der Substrate vermehren (mitochondriale Biogenese), den zellulären Fettstoffwechsel verbessern oder die Fläche der Muskulatur vergrößern, was mehr Masse bedeutet.

Nie wieder dick? Konkrete Modulation

1. Retinsäure, der Abkömmling (Derivat) des Retinols (Vitamin A1)

(a) We show here that adipocyte differentiation is accompanied by a shift in RA signaling which, in mature adipocytes, allows RA to activate both RARs and PPARβ/δ, thereby enhancing lipolysis and depleting lipid stores. In vivo studies using a dietary-induced mouse model of obesity indicated that onset of obesity is accompanied by downregulation of adipose PPARβ/δ expression and activity. RA treatment of obese mice induced expression of PPARβ/δ and RAR target genes involved in regulation of lipid homeostasis, leading to weight loss and improved insulin responsiveness. RA treatment also restored adipose PPARβ/δ expression. The data indicate that suppression of obesity and insulin resistance by RA is largely mediated by PPARβ/δ and is further enhanced by activation of RARs. By targeting two nuclear receptors, RA may be a uniquely efficacious agent in the therapy and prevention of the metabolic syndrome.

(b) ATRA treatment triggered a dose-dependent increase in the muscle mRNA expression levels of selected enzymes, transporters and transcription factors involved in fatty-acid oxidation, respiration, and thermogenesis namely: muscle-type carnitine palmitoyltransferase 1, acyl CoA oxidase 1, subunit II of cytochrome oxidase, uncoupling protein 3, peroxisome proliferator–activated receptor-γ co-activator −1α and peroxisome proliferator–activated receptor-δ (PPARδ). The treatment also resulted in the upregulation of the mRNA levels of acetyl-CoA carboxylase 2 (ACC2), a key regulatory enzyme for mitochondrial fatty-acid oxidation in muscle. Skeletal muscle protein levels of PPARδ and retinoid X receptor γ, a partner for many nuclear receptors involved in lipid metabolism, were increased after ATRA treatment. Muscle lipid content was decreased

(c) Treatment of wild-type mice with PPARdelta agonist elicits a similar type I fiber gene expression profile in muscle. Moreover, these genetically generated fibers confer resistance to obesity with improved metabolic profiles, even in the absence of exercise. These results demonstrate that complex physiologic properties such as fatigue, endurance, and running capacity can be molecularly analyzed and manipulated.

Vitamin A-Gaben erhöhen zwangsläufig die Plasma-Retinoide (Vitamin A Abkömmlinge) und somit die Retinsäure, die als PPARdelta Ligand, den Fettstoffwechsel reguliert. Wie wir sehen konnten, sowohl in der Fett – als auch in der Muskelzelle. Du kannst damit a) die Fettspeicher entleeren und verfügst dabei b) über erhöhte Oxidationskapazität im Muskel. Wichtig ist die Tatsache, dass Retinsäure PPARdelta aktiviert, was wohl einen Muskelfaser-Switch als Folge hat, der dadurch ausdauernder wird. PPARdelta reguliert wahrscheinlich als einziges nennenswertes Protein den Muskelfaser-Typ und die Ausdauer, aufgrund der Steigerung des Lipid-Katabolismus‘.

Dosis: Die höchste und langfristig anwendbare Dosis beträgt ca. 50.000 Internationale Einheiten pro Tag in Form von Retinylpalmitat oder Leber.

2. Calcium

(a) Accordingly, suppressing calcitriol levels by increasing dietary calcium is an attractive target for the prevention and management of obesity. In support of this concept, transgenic mice expressing the agouti gene specifically in adipocytes (a human-like pattern) respond to low calcium diets with accelerated weight gain and fat accretion, while high calcium diets markedly inhibit lipogenesis, accelerate lipolysis, increase thermogenesis and suppress fat accretion and weight gain in animals maintained at identical caloric intakes. Further, low calcium diets impede body fat loss, while high calcium diets markedly accelerate fat loss in transgenic mice subjected to caloric restriction. These findings are further supported by clinical and epidemiological data demonstrating a profound reduction in the odds of being obese associated with increasing dietary calcium intake. Notably, dairy sources of calcium exert a significantly greater anti-obesity effect than supplemental sources in each of these studies, possibly due to the effects of other bioactive compounds, such as the angiotensin converting enzyme inhibitor found in milk, on adipocyte metabolism, indicating an important role for dairy products in the control of obesity.

(b) Mice placed on diets suboptimal in calcium (0.4%), high in fat, and high in sucrose for 6 wk had marked increases in adipocyte lipogenesis, decreases in lipolysis, and accelerated increases in body weight and adipose tissue mass. In contrast, high-calcium (1.2%) diets reduced lipogenesis by 51% and stimulated lipolysis 3- to 5-fold, resulting in 26–39% reductions in body weight and adipose tissue accretion at identical ad libitum energy intakes […]

Consequently, although the animals that were refed low-calcium diets rapidly regained all of the weight and fat that had been lost, the animals fed high-calcium diets showed a shift in energy partitioning and a 50–85% reduction in weight and fat gain […]

Control subjects lost 6.4% of their body weight over the 24-wk study, and this loss was increased by 26% with the high-calcium diet and by 70% (to 10.9%) with the diet high in dairy products (P < 0.01). Fat loss (measured by dual-energy X-ray absorptiometry) followed a similar trend; the high-calcium diet and the diet high in dairy products augmented the fat loss that occurred with the low-calcium diet by 38% and 64%, respectively (P < 0.01). An unexpected finding was a marked change in the distribution of body fat loss (43). Fat loss from the trunk region represented 19% of the total fat lost with the low-calcium diet, and this loss increased to 50% of the fat lost with the high-calcium diet and to 66% of the fat lost with the diet high in dairy products (P < 0.001).

(c) Calcitriol decreased muscle cell fatty acid oxidation by 37% (P<0.001) and increased adipocyte FAS gene expression by threefold (P<0.05);

Wenn man kein Geld ausgeben möchte für Ergänzungsprodukte, die in den meisten Fällen sowieso nichts bringen, dann sollte man darauf achten, genug Calcium aufzunehmen.

Dies hat einen genauen biochemischen Hintergrund: Viel Calcium hemmt paradoxerweise den Eintritt von Calcium in die Fettzelle, was eine stark gesteigerte Lipolyse (siehe oben) und eine stark verminderte Lipogenese (siehe oben) als Folge hat. Das macht Calcium indem es die Plasma-Werte von Calcitriol (aktives VitD) senkt.

Die Resultate sind so beeindruckend, da sie direkt auf den Menschen übertragbar sind, wo bei Diäten 40 % bzw. 65 % mehr Gewicht verloren werden kann (siehe oben). Das erinnert mich an meinen Spruch: Man kann abnehmen oder man kann abnehmen.

Calcium hemmt auch den Einstrom von Calcium in die Muskelzelle (via Calcitriol, siehe oben). Im Umkehrschluss heißt ein erhöhter Eintritt von Calcium (viel Calcitriol), weniger Fettoxidation (- 40 %) und eine erhöhte Fett-Synthese im Muskel (+ 300 %).

Dosis: Man könnte 1-2 g zusätzlich nehmen, schön wäre in Form eines Milchproduktes (halt, nein, sind ja Kohlenhydrate) oder in Form eines Proteins auf Milchpulver-Basis.

3. L-Carnitin

(a) In conclusion, this is the first study to demonstrate that increasing skeletal muscle carnitine content in healthy humans can modulate energy metabolism over a prolonged period, as reflected by a prevention of an increase in adiposity in abdominal and leg regions, an increase in energy expenditure during low-intensity exercise, and a robust increase in the expression of metabolic genes regulating muscle fuel selection in response to 12 weeks of carbohydrate overfeeding. In line with the role of carnitine in the translocation of long-chain acyl-groups via CPT1, these important findings are most likely due to an increase in the rate of fat oxidation compared with Control at rest and during low-intensity exercise. This is consistent with animal models of increased CPT1 flux, in which a sustained increase in fatty acid oxidation and energy expenditure occur along with reduced fat mass and improved insulin sensitivity (Minnich et al. 2001; Choi et al.2007; Bruce et al. 2009; Glund et al. 2012). These findings have clear health implications and warrant further investigation, particularly in obese individuals who have a reduced reliance on IMCL oxidation at rest and during low-intensity exercise (van Loon, 2004;Perreault et al. 2010), as well as abdominal adipose tissue accumulation, which predisposes to the development of insulin resistance and type 2 diabetes.

(b) Compared with baseline, the decrease of total cholesterol was not significant in the placebo group, whereas in the L-carnitine group it decreased significantly after 12 wk of treatment. Furthermore, in the L-carnitine group, we observed a significant decrease in triglyceride (Anm. von mir: 30%), apo A1, apo B-100, and LDL cholesterol concentrations and a significant increase in HDL cholesterol concentrations (Anm. von mir: 7%) after 12 wk of treatment compared with baseline. A significant decrease in LDL cholesterol, triglycerides, apo A1, and apo B-100 concentrations in the L-carnitine group compared with the placebo group was observed after 12 wk of treatment. The analysis of covariance showed that these differences were independent of variations in BMI and Hb A1c.

(c) The release of glycerol and free fatty acid into the medium was significantly increased by 1.5- and 1.7- fold, respectively, by the addition of 100 nM L-carnitine compared with the control (P < .05). The mRNA levels of hormone-sensitive lipase, carnitine palmitoyltransferase I-a, and acyl-coenzyme A oxidase, all of which participate in lipid catabolism, were increased in the presence of 100 nM L-carnitine by 2.8-, 2.2-, and 1.6-fold, respectively (P < .05). However, the expression of peroxisome proliferator-activated receptor-gamma and adipose-specific fatty acid-binding protein, which are involved in adipogenesis, were down-regulated by L-carnitine in 3T3-L1 adipocytes (P < .05). These results suggest an anti-obesity action of L-carnitine. L-carnitine may modulate lipid metabolism by stimulation of lipolysis and beta-oxidation accompanied by corresponding changes in gene expression and suppression of adipogenic gene expression.

(d) Fructose-fed animals (60 g/100 g diet) displayed decreased glucose/insulin (G/I) ratio and insulin sensitivity index (ISI(0,120)) indicating the development of insulin resistance. Rats showed alterations in the levels of triglycerides, free fatty acids, cholesterol, and phospholipids in skeletal muscle. The condition was associated with oxidative stress as evidenced by the accumulation of lipid peroxidation products, protein carbonyls, and aldehydes along with depletion of both enzymic and nonenzymic antioxidants. Simultaneous intraperitoneal administration of CAR (300 mg/kg/day) to fructose-fed rats alleviated the effects of fructose. These rats showed near-normal levels of the parameters studied. The effects of CAR in this model suggest that CAR supplementation may have some benefits in patients suffering from insulin resistance.

(e) The abnormalities associated with fructose feeding such as increased gluconeogenesis, reduced glycogen content and other parameters were brought back to near normal levels by CA. Hepatocytes from these animals showed significant inhibition of glucose production from pyruvate (74.3%), lactate (65.4%), glycerol (69.6%), fructose (56.2%) and alanine (63.6%) as compared to CA untreated fructose-fed animals.

(f) OGTT at 2 hours improved in both groups. Only in the L-carnitine-supplemented group did plasma insulin levels and HOMA-IR significantly decrease when compared to baseline values.