Milk Fat Globule Membranes Power Up Strength Gains by Improving the Wiring of Subjects' Muscles | Plus: Its Proven Health, EPO & Immune-Boosting Effects Won't Hurt Either

At the moment it is by no means clear which type of athlete / gymrat would benefit from milk fat globule membrane supplementation and which wouldn't. It's after all well possible that the effects Soga et al. observed in rookies wouldn't occur in adv. trainees or professional athletes.

After the study on nucleotide supplements the Satako Soga's latest paper on the dietary supplementation with milk fat globule membrane is #2 on the list of studies with promising new ergogenics in less than a month. In view of the fact that the last year has been devoid of any true innovations, this is a welcome diversion from writing about whey (or other protein powders), creatine, beta alanine and baking soda, as well as the occasional study on HMB for me.

In spite of the fact that this is a follow up on previous rodent studies from the same researchers, I must warn you not to to expect too much of MFGMs, yet. More data and studies with more realistic resistance training + supplementation protocols from independent labs are warranted before MFGMs may eventually appear next to the previously mentioned top dogs on a list of "SuppVersity Recommended Supplements".
But hey, let's keep the skepticism for the bottom line and take a look at what the scientists from the Kao Corporation did with their fourteen Japanese subjects. The men, who were aged 31–48 years and did not participate in regular strength training before the study, took 1 g of the  structural membranes of milk which are usually covering the triglyceride globules that are dispersed as emulsified bodies in milk or 1g of an identically looking whole milk powder as a placebo in tablet form for 4-weeks (composition see Table 1).

Table 1: Composition of MFGM and whole milk powder (Soga. 2015)

"On the exercise training enforcement days [i.e. the days on which the subjects were required to train], the subjects were instructed to take the tablet within 1 h before training. On the other days, the subjects were instructed to consume the tablet at the time of their choice during their daily routines.

The MFGM was prepared from buttermilk by filtering and centrifugation. The MFGM and whole milk powder compositions were analyzed at Japan Food Research Laboratories (Tokyo, Japan)" (Soga. 2015).

The exercise routine the subjects from both groups had to follow consisted of two workouts per week. The workouts had to be performed on nonconsecutive days for 4 weeks using StrengthErgo 240 stationary cycling exercise machines (Mitsubishi Electric Corporation, Tokyo, Japan). On these machines, the subjects completed 3 sets of 15 % maximal voluntary contraction (MVC) cycle exercises for 60 s and 7 sets of 20 % MVC cycle exercises for 40 s at 50 rpm.
Physical function tests and surface electromyography (EMG) were conducted at baseline and at the end of the study period. In addition, some hemotological parameters were tested of which - surprise - the data in Figure 1 tells you that MFGMs have a small, but statistically significant "EPO-effect" and are thus capable of raising both the red blood cell and hemoglobin content - an effect that has been observed in rodents too (Haramizu. 2014b) and may be ascribed to the incorporation of MFGM phospholipids into red blood cells which would in turn be less vulnerable to exercise-related or other stressors. Whatever the reason for these changes may be, they are certainly in line with the previously mentioned (see red box) increase in fatty acid oxidation during endurance exercise that may be facilitated by an RBC and hemoglogin related increase in oxygen transport.

Figure 1: The significant increase in red blood cell and hemoglogin content could explain the previously observed increases in endurance performance and fatty acid oxidation in Haramizu et al. (2014a). The buffered decrease in white blood cell may not be statistically significant, but may still indicate beneficial effects on the immune system (Soga. 2015).

Both the increase in RBC and hemoglobin, as well as the buffering of the albeit non-significant decline in white blood cells in the placebo group, which may be a response to the exercise-induced stress and evidence of an immune-boosting effect of MFGM supplementation during any potentially exercise induced immune suppression, do yet need further investigation before they can be explained mechanistically.

No further research is needed, though, to state that all other blood markers. These included AST + ALT (liver health), glucose and triglycerides + cholesterol, neither of which was affected by the supplement. The latter cannot be said of the increase in leg extension strength before and after the intervention and the EMG activity which showed highly significant inter-group differences.
In fact, the differences in Figure 2 are pronounced enough to ask the question: Were they induced by the supplementation alone or did the pathetic training regimen have an effect here, as well? As I am going to point out in the bottom line one paragraph below, we will need studies with more realistic training programs to answer this question in a way that's relevant for trainees like you and me. In the mean time, however, there is no debating "that the daily intake of 1 g MFGM combined with regular, twice weekly exercise improved skeletal muscle strength (leg extension) in middle-aged adults, despite a lack of change in muscle mass" (Soga. 2015).

Figure 2: The MFGM supplementation lead to significant increases in leg extension strength, of which the increase in EMG activity (likewise sign.) suggests that they were mediated by neuronal changes (Soga. 2015).

The same goes for the increase in RMS of surface EMG, which indicates that the dietary provision of MFGM increased the average (RMS = root mean square) motor unit activity during muscle contraction and may thus mechanistically explain why the subjects got stronger even though they didn't make substantial gains in muscle mass: The supplement helped them to "make the most" of the muscle they had. This hypothesis is in line with results from rodent studies which

"[...] revealed that dietary MFGM combined with regular exercise improved muscle strength in adult mice primarily by stimulating the pathway involving “nervous system development” in the skeletal muscle (Haramizu. 2014b). This pathway includes functional annotations such as formation of synapses, growth of neurites, or development of NMJ. Dietary MFGM combined with exercise increased skeletal muscle expression of docking protein-7 (Dok-7) and muscle-specific receptor tyrosine kinase in mice, both of which play a critical role in NMJ [neuromuscular junction] formation. Defects in NMJ function causes muscle weakness in neuromuscular disorders, and Dok-7 gene therapy improves NMJ formation and rescues the motor activity" (Soga. 2015).

And still, even at the risk that I may sound like a broken record, I have to repeat that without future research it is impossible to tell (a) whether the assumptions we've made about the increase in red blood cell count are accurate and, maybe even more importantly, (b) who, i.e. which type of athlete, will benefit most from using MFGM supplements.
References:

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• Haramizu, Satoshi, et al. "Habitual exercise plus dietary supplementation with milk fat globule membrane improves muscle function deficits via neuromuscular development in senescence-accelerated mice." SpringerPlus 3 (2014): 339.
• Kim, Hunkyung, et al. "Effects of Exercise and Milk Fat Globule Membrane (MFGM) Supplementation on Body Composition, Physical Function, and Hematological Parameters in Community-Dwelling Frail Japanese Women: A Randomized Double Blind, Placebo-Controlled, Follow-Up Trial." PloS one 6.10.2 (2015): e0116256.
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• Timby, Niklas, et al. "Cardiovascular risk markers until 12 mo of age in infants fed a formula supplemented with bovine milk fat globule membranes." Pediatric research 76.4 (2014b): 394-400.