Carbohydrate
Surge has dextrose (synonymous with glucose) as its sole carbohydrate source, while chocolate milk has an even mix of sucrose (in the form of either sucrose or high-fructose corn syrup) and lactose. While it’s common to assume that dextrose is superior to sucrose for postexercise glycogen resynthesis, research doesn’t necessarily agree. A trial by Bowtell et al showed a glucose polymer to synthesize more glycogen by the 2-hr mark postworkout [14]. However, two other trials whose postexercise observation periods were 4 and 6 hours respectively saw no significant difference in glycogen storage between sucrose and glucose [15,16].
Perhaps the most overlooked advantage of a fructose-containing carbohydrate source (sucrose is 50% fructose) is that it supports liver glycogen better than a glucose-only source, as in the case of Surge. A little-known fact is that hepatic glycogenolysis (liver glycogen use) occurs to a significant degree during exercise, and the magnitude of glycogenolysis is intensity-dependent [17]. Illustrating the potential superiority of sucrose over glucose, Casey et al saw no difference in muscle glycogen resynthesis 4 hrs postexercise [15]. However, there was more liver glycogen resynthesis in the sucrose group, and this correlated with a slightly greater exercise capacity.
One of the potential concerns of consuming a large amount of sucrose instead of glucose is how the 50% fructose content in sucrose might be metabolized from a lipogenic standpoint. Answering this question directly, McDevitt saw no difference in de novo lipogenesis (conversion to fat) between the massive overfeeding of either glucose or sucrose at 135g above maintenance needs [18]. Another potential concern is the use of high-fructose corn syrup (HFCS) in chocolate milk. The common fear of HFCS being some sort of special agent that undermines health is simply not grounded in science. HFCS is virtually identical to sucrose both in chemical structure and metabolic effect [19]. Independent researcher John White eloquently clarified HFCS misconceptions in a recent review, which I’ll quote [20].
“Although examples of pure fructose causing metabolic upset at high concentrations abound, especially when fed as the sole carbohydrate source, there is no evidence that the common fructose-glucose sweeteners do the same. Thus, studies using extreme carbohydrate diets may be useful for probing biochemical pathways, but they have no relevance to the human diet or to current consumption. I conclude that the HFCS-obesity hypothesis is supported neither in the United States nor worldwide.”
It bears mentioning that lactose intolerance can prohibit regular milk use for certain susceptible individuals. However, this can be remedied by using Lactaid brand milk, or by using lactase pills or drops. Bottom line: For those who can digest lactose or are willing to take the extra step to make it digestible, chocolate milk wins. But since there are those who can’t or won’t do what’s required to tolerate lactose, I’m calling this a tie.
Fat
Coincidentally, Surge and chocolate milk have identical proportions of saturated fat. Lowfat chocolate milk has more fat than Surge, which would cause some folks to call a foul for postworkout purposes. However, a trial by Elliot et al found that postexercise ingestion of whole milk was superior for increasing net protein balance than fat-free milk [21]. The most striking aspect about this trial was that the calorie-matched dose of fat free milk contained 14.5g protein, versus 8.0 g in the whole milk. Apparently, postworkout fat intake (particularly milk fat) is nothing to fear, and may even be beneficial from the standpoint of synthesizing muscle protein. Bottom line: it’s a tie, since there is very little evidence favoring one fat profile/amount versus the other. On one hand, you can be saving fat calories by going with Surge. On the other hand, postworkout milk fat might potentially enhance protein synthesis. Things come out even.
MICRONUTRIENT COMPARISON (per 340 kcal serving)*
Surge Recovery Chocolate Milk
Calcium 180 mg 624 mg
Cholesterol 75 mg 16 mg
Leucine 4000 mg 1714 mg
Magnesium 20 mg 70 mg
Phenylalanine 2000 mg 844 mg
Phosphorous 120 mg 558 mg
Potassium 400 mg 920 mg
Sodium 200 mg 329 mg
*This comparison is limited to the micronutrients on the Surge label. And yes, I realize that not all of the above are technically micronutrients.
A quick glance at the above chart shows that chocolate milk is markedly more nutrient-dense, with the exception of a higher content of leucine and phenylalanine in Surge, whose significance (or lack of) I discussed earlier. As an interesting triviality, both have a low cholesterol content, but Surge has 4.6 times more. Chocolate milk has more sodium, but it also has a significantly higher potassium-to-sodium ratio. Bottom line: chocolate milk wins this one decisively.
OTHER CONSIDERATIONS
Price
Chocolate milk by the half gallon (64oz, or about 2000 ml) is approximately $3.00 USD. Sticking with our 340 kcal figure, this yields 3.7 servings, which boils down to $0.81 per serving. A tub of Surge costs $36.00 and yields 16 servings (3 scoops, 340 kcals per serving). This boils down to $2.25 per serving. That’s 277% more expensive than chocolate milk. Even on a protein-matched basis, Surge is still roughly double the price. Bottom line: chocolate milk is many times easier on your wallet.
Convenience & taste
Convenience is the single area where Surge wins. Being a powder, it’s non-perishable, requiring no refrigeration. This makes it more easily portable. Taste will always be, well, a matter of taste. I highly doubt that in a blinded test that Surge would win over chocolate milk. Bottom line: Surge is more convenient, but I’ll go out on a limb and guess that chocolate milk would taste better to most people.
CONCLUSION
I have no vested interest in glorifying chocolate milk, nor do I stand to benefit by vilifying Surge. My goal was to objectively examine the facts. Using research as the judge, chocolate milk was superior or equal to Surge in all categories. The single exception was a win for Surge in the convenience department. So, if the consumer were forced to choose between the two products, the decision would boil down to quality at the expense of convenience, or vice versa. I personally would go for the higher quality, lower price, and strength of the scientific evidence. Chocolate milk it is.
REFERENCES CITED:
1. Berardi JM, et al. Postexercise muscle glycogen recovery enhanced with a carbohydrate-protein supplement. Med Sci Sports Exerc. 2006 Jun;38(6):1106-13.
2. Roy BD. Milk: the new sports drink? a review. J Int Soc Sports Nutr. 2008 Oct 2;5:15.
3. McDonald L. (Review of) Milk the new sports drink? a review. Bodyrecomposition.com, 2008.
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5. Tang JE, et al. Minimal whey protein with carbohydrate stimulates muscle protein synthesis following resistance exercise in trained young men. Appl Physiol Nutr Metab. 2007 Dec;32(6):1132-8.
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8. Rennie MJ, et al. Branched-chain amino acids as fuels and anabolic signals in human muscle. J Nutr. 2006 Jan;136(1 Suppl):264S-8S.
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11. Lands LC, et al. Effect of supplementation with a cystein donor on muscular performance. J Appl Physiol 1999;87:1381-5.
12. Cribb PJ, et al. The effect of whey isolate and resistance training on strength, body composition, and plasma glutamine. Int J Sport Nutr Exerc Metab. 2006 Oct;16(5):494-509.
13. LaCroix M, et al. Compared with casein or total milk protein, digestion of milk soluble proteins is too rapid to sustain the anabolic postprandial amino acid requirement. Am J Clin Nutr. 2006 Nov;84(5):1070-9.
14. Bowtell JL, et al. Effect of different carbohydrate drinks on whole body carbohydrate storage after exhaustive exercise. J Appl Physiol 2000; 88 (5): 1529-36.
15. Casey A, et al. Effect of carbohydrate ingestion on glycogen resynthesis in human liver and skeletal muscle, measured by (13)C MRS. Am J Physiol Endocrinol Metab. 2000 Jan;278(1):E65-75.
16. Blom PC, et al. Effect of different post-exercise sugar diets on the rate of muscle glycogen synthesis. Med Sci Sports Exerc. 1987 Oct;19(5):491-6.
17. Suh SH, et al. Regulation of blood glucose homeostasis during prolonged exercise. Mol Cells. 2007 Jun 30;23(3):272-9.
18. McDevitt et al. De novo lipogenesis during controlled overfeeding with sucrose or glucose in lean and obese women. Am J Clin Nutr. 2001 Dec;74(6):737-46.
19. Melanson KJ, et al. High-fructose corn syrup, energy intake, and appetite regulation. Am J Clin Nutr. 2008 Dec;88(6):1738S-1744S.
20. White JS. Straight talk about high-fructose corn syrup: what it is and what it ain’t. Am J Clin Nutr. 2008 Dec;88(6):1716S-1721S.
21. Elliot TA, et al. Milk ingestion stimulates net muscle protein synthesis following resistance exercise. Med Sci Sports Exerc. 2006 Apr;38(4):667-74