200 g
BCAA 2 : 1 : 1
BCAA 2 : 1 : 1
BCAA 2 : 1 : 1
Branched-chain amino acids (BCAAs) consist of leucine, isoleucine, and valine in a 2:1:1 ratio, the most researched and balanced formulation for optimal metabolic function.
Leucine acts as a primary activator of the mTOR pathway, signaling protein synthesis, while isoleucine enhances glucose uptake and energy production within muscle cells. Valine serves as a secondary fuel source during prolonged exertion, helping to maintain nitrogen balance and prevent amino acid catabolism.
Branched-chain amino acids (BCAAs) consist of leucine, isoleucine, and valine in a 2:1:1 ratio, the most researched and balanced formulation for optimal metabolic function.
Leucine acts as a primary activator of the mTOR pathway, signaling protein synthesis, while isoleucine enhances glucose uptake and energy production within muscle cells. Valine serves as a secondary fuel source during prolonged exertion, helping to maintain nitrogen balance and prevent amino acid catabolism.
Branched-chain amino acids (BCAAs) consist of leucine, isoleucine, and valine in a 2:1:1 ratio, the most researched and balanced formulation for optimal metabolic function.
Leucine acts as a primary activator of the mTOR pathway, signaling protein synthesis, while isoleucine enhances glucose uptake and energy production within muscle cells. Valine serves as a secondary fuel source during prolonged exertion, helping to maintain nitrogen balance and prevent amino acid catabolism.
01
//benefits
200 g
//benefits
200 g
01
//benefits
200 g
BCAA 2 : 1 : 1
Leucine-Driven mTOR Activation
Leucine is the primary activator of the mechanistic target of rapamycin (mTOR) pathway, which regulates protein synthesis at the cellular level. This pathway is critical for muscle protein translation, increasing anabolic signaling and minimizing muscle protein breakdown. The 2:1:1 ratio ensures an optimal leucine threshold for sustained activation while maintaining balance with isoleucine and valine.
Leucine-Driven mTOR Activation
Leucine is the primary activator of the mechanistic target of rapamycin (mTOR) pathway, which regulates protein synthesis at the cellular level. This pathway is critical for muscle protein translation, increasing anabolic signaling and minimizing muscle protein breakdown. The 2:1:1 ratio ensures an optimal leucine threshold for sustained activation while maintaining balance with isoleucine and valine.
Leucine-Driven mTOR Activation
Leucine is the primary activator of the mechanistic target of rapamycin (mTOR) pathway, which regulates protein synthesis at the cellular level. This pathway is critical for muscle protein translation, increasing anabolic signaling and minimizing muscle protein breakdown. The 2:1:1 ratio ensures an optimal leucine threshold for sustained activation while maintaining balance with isoleucine and valine.
Glucose Uptake & Energy Regulation
Isoleucine plays a significant role in glucose metabolism by increasing glucose uptake into skeletal muscle cells via the GLUT4 transporter. This facilitates steady energy availability during prolonged exercise and reduces dependence on hepatic glycogen stores. The insulinogenic properties of isoleucine further support glycogen resynthesis post-exercise.
Glucose Uptake & Energy Regulation
Isoleucine plays a significant role in glucose metabolism by increasing glucose uptake into skeletal muscle cells via the GLUT4 transporter. This facilitates steady energy availability during prolonged exercise and reduces dependence on hepatic glycogen stores. The insulinogenic properties of isoleucine further support glycogen resynthesis post-exercise.
Glucose Uptake & Energy Regulation
Isoleucine plays a significant role in glucose metabolism by increasing glucose uptake into skeletal muscle cells via the GLUT4 transporter. This facilitates steady energy availability during prolonged exercise and reduces dependence on hepatic glycogen stores. The insulinogenic properties of isoleucine further support glycogen resynthesis post-exercise.
Nitrogen Balance & Anti-Catabolic Effects
Valine contributes to nitrogen balance, a key factor in maintaining muscle integrity during periods of high energy demand or caloric restriction. By supplying nitrogen for the synthesis of other amino acids, it helps reduce muscle catabolism under stress conditions. Additionally, valine competes with tryptophan for uptake into the brain, potentially reducing central fatigue by limiting serotonin production.
Nitrogen Balance & Anti-Catabolic Effects
Valine contributes to nitrogen balance, a key factor in maintaining muscle integrity during periods of high energy demand or caloric restriction. By supplying nitrogen for the synthesis of other amino acids, it helps reduce muscle catabolism under stress conditions. Additionally, valine competes with tryptophan for uptake into the brain, potentially reducing central fatigue by limiting serotonin production.
Nitrogen Balance & Anti-Catabolic Effects
Valine contributes to nitrogen balance, a key factor in maintaining muscle integrity during periods of high energy demand or caloric restriction. By supplying nitrogen for the synthesis of other amino acids, it helps reduce muscle catabolism under stress conditions. Additionally, valine competes with tryptophan for uptake into the brain, potentially reducing central fatigue by limiting serotonin production.
Branched-Chain Amino Acid Oxidation & Mitochondrial Function
BCAAs serve as direct substrates for oxidation in mitochondria, providing an alternative energy source during exercise. This oxidation process helps spare glycogen and lipids while supporting ATP production. The efficient metabolism of BCAAs contributes to enhanced endurance capacity and recovery.
Branched-Chain Amino Acid Oxidation & Mitochondrial Function
BCAAs serve as direct substrates for oxidation in mitochondria, providing an alternative energy source during exercise. This oxidation process helps spare glycogen and lipids while supporting ATP production. The efficient metabolism of BCAAs contributes to enhanced endurance capacity and recovery.
Branched-Chain Amino Acid Oxidation & Mitochondrial Function
BCAAs serve as direct substrates for oxidation in mitochondria, providing an alternative energy source during exercise. This oxidation process helps spare glycogen and lipids while supporting ATP production. The efficient metabolism of BCAAs contributes to enhanced endurance capacity and recovery.
Wieght
200 g
InGRIEDIENTS
BCAA 2 : 1 : 1
Category
Amnio acids
DOSAGE
5 g daily
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Concerns
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Asked Questions
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Where can I find ATP supplements?
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What's under the lid?
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Why do you only use single-ingredient formulations?
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Are ATP supplements independently tested?
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What is the shelf life of ATP supplements?
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03
//FAQ
Concerns
Frequently
Asked Questions
01
Where can I find ATP supplements?
02
What's under the lid?
03
Why do you only use single-ingredient formulations?
04
Are ATP supplements independently tested?
05
What is the shelf life of ATP supplements?
06
Are your supplements suitable for all athletes?
//FAQ
Concerns
Frequently
Asked Question
Where can I find ATP supplements?
What's under the lid?
Why do you only use single-ingredient formulations?
Are ATP supplements independently tested?
What is the shelf life of ATP supplements?
Are your supplements suitable for all athletes?
03
//FAQ
Concerns
Frequently
Asked Questions
01
Where can I find ATP supplements?
02
What's under the lid?
03
Why do you only use single-ingredient formulations?
04
Are ATP supplements independently tested?
05
What is the shelf life of ATP supplements?
06
