Pizza for breakfast? You betchya! This recipe by All Day I Dream About Food slashes carbs by subbing in cauliflower for the standard wheat flour crust, and racks up plenty of fats and protein with toppings like cheese, sausage, eggs, and avocado. It’s as gooey and crispy as your favorite pizza pie, but costs you a slim 5.43 grams of net carbs a serving. Perfect for relaxing weekend mornings or keto-friendly brunch.
On the contrary, in the brain, as mentioned above, the increase of AMPK activity leads to higher food intakes. But the effect of AMPK in the brain is more complicated; mice lacking AMPKa2 in pro-opiomelanocortin neurons develop obesity, while the deficiency of AMPKa2 in agouti-related protein neurons results in an age-dependent phenotype. Thus, the conclusion is that even while AMPK is a regulator of hypothalamic functions, it does not act as a signal for energy deficit or excess (Claret et al., 2007). However, the picture is more complex than this (Figure (Figure3);3); BHB induces AgRP expression while increasing ATP and inhibiting AMPK phosphorylation (Cheng et al., 2008). Moreover, Laeger and colleagues have recently demonstrated that under physiological conditions BHB decreases AMPK phosphorylation and AgRP mRNA expression in GT1-7 hypothalamic cells (Laeger et al., 2012).
Broyles, S., Katzmarzyk, P. T., Srinivasan, S. R., Chen, W., Bouchard, C., Freedman, D. S., & Berenson, G. S. (2010, May). The pediatric obesity epidemic continues unabated in Bogalusa, Louisiana. Pediatrics, 125(5). Retrieved from http://pediatrics.aappublications.org/content/125/5/900?sso=1&sso_redirect_count=1&nfstatus=401&nftoken=00000000-0000-0000-0000-000000000000&nfstatusdescription=ERROR%3a+No+local+token
Maria – Love this recipe – took me 4 times before I got it how I wanted it and I add sesame seeds. Then I slice really really thin – about 1/2 cm then dry all the slices in the oven ready for toasting. However, right now I can only find baking powder with vanilla. Can I sub baking soda which together with the vinegar should work but how much? Can you help please?
This poses a real evolutionary dilemma. We need an enormous amount of energy just to not die, but the single most important organ in our body (also quite energy hungry in its own right) can’t access the most abundant source of energy in our body (i.e., fat) and is, instead, almost solely dependent on the one macronutrient we can’t store beyond a trivial amount (i.e., glucose). Obviously our species wouldn’t be here today if this were the end of the story. But, to understand how we survived requires one more trip down biochemistry memory lane. In the figure below (also included and described in the video) I gloss over a pretty important detail.
Ketone bodies synthesized in the body can be easily utilized for energy production by heart, muscle tissue, and the kidneys. Ketone bodies also can cross the blood-brain barrier to provide an alternative source of energy to the brain. RBCs and the liver do not utilize ketones due to lack of mitochondria and enzyme diaphorase respectively. Ketone body production depends on several factors such as resting basal metabolic rate (BMR), body mass index (BMI), and body fat percentage. Ketone bodies produce more adenosine triphosphate in comparison to glucose, sometimes aptly called a "super fuel." One hundred grams of acetoacetate generates 9400 grams of ATP, and 100 g of beta-hydroxybutyrate yields 10,500 grams of ATP; whereas, 100 grams of glucose produces only 8,700 grams of ATP. This allows the body to maintain efficient fuel production even during a caloric deficit. Ketone bodies also decrease free radical damage and enhance antioxidant capacity.
Fill half your plate with non-starchy vegetables. Split the other half in two between protein and whole-food carbs such as brown rice, quinoa, beans, legumes, or ancient grains such as amaranth, millet, or farro. These complex carbohydrates have more fiber and nutrients than processed carbs such as white rice, bread, and pasta, and the fiber helps control blood sugar levels.
Although the majority of links between energy sensing and antioxidant defense are manifested further downstream, there is some direct influence at the level of AMPK and sirtuins. AMPK is activated by oxidative stress [259, 260], likely through ATP depletion and a subsequent increase in the AMP to ATP ratio, or facilitation of tyrosine phosphorylation, which occurs independently of AMP and ATP concentrations . SIRT3 contributes more directly to antioxidant defense by deacetylating and activating SOD2 [261–263]. The overlapping effect of SIRT3 on antioxidant defense and bioenergetics is further supported by SIRT3 knockout increasing lipid peroxidation in conjunction with decreased O2 consumption in mouse skeletal muscle and also by SIRT3 knockdown increasing H2O2 production and decreasing O2 consumption in myoblasts .
I could go on for days about how a good diet can keep your blood sugar in control. To receive the most efficient information, set up a meeting with a dietician to look at your specific needs and you recent sugar readings. They can provide you with recipes and tools which make it easier for you to know exactly what you are putting into your body. 40 states in the United States require insurance companies to cover a meeting with a dietician for those with diabetes. Check with your insurance to see if this benefit is available for you.
The gastrointestinal tract (GIT) plays a central role in the control of energy balance. Many molecules produced by the GIT exert hunger or satiety effects on the brain. Ghrelin is a peptide produced mainly by the stomach's oxyntic cells that stimulates ghrelin secretion in the hypophysis and has some neuroendocrine activities. However, its orexigenic properties are the most relevant to us and ghrelin is the only known peripheral orexigenic hormone (Date, 2012). Cholecystokinin (CCK) is a peptide produced mainly in the duodenum and jejunum that acts on the vagus nerve and directly on the hypothalamic nuclei. CCK is an anorexigenic factor and it reduces food intake, meal size and duration (Murphy et al., 2006). Three other related hormones are pancreatic polypeptide (PP), amylin, and peptide YY (PYY). PP is a peptide produced by the endocrine pancreas in relation to the caloric content of meals, and it reduces food intake both in rodents and humans. Amylin is a peptide co-secreted with insulin; its main effect on food control is a reduction of meal sizes and food intake (Murphy et al., 2006). Peptide YY (PYY) is produced in the gut and is similar to PP. PYY is stored in intestinal cells and released into the circulation as PYY3−36, a truncated form of PYY. The release of PYY3−36 is dependent on a meal's caloric and fat content (Veldhorst et al., 2008). The glucagon-like peptide 1 (GLP-1) is produced by the cleavage of pro-glucagon gene in the intestine. It acts as incretin at a pancreatic level, promoting insulin secretion and as neuro hormone on hypothalamic nuclei, inducing satiety (Valassi et al., 2008).
You can find a mixed bag of studies in rodents; sometimes the ketogenic diet is amazing sometimes it’s terrible. The main reason why is because there are many kinds of ketogenic diets; what fats were used? how processed is the food and what was the method of processing? were these genetically manipulated mice or wild type? were they fed ad lib (to their hearts content), forced fed (hypercaloric) or had their calories restricted?
In sheep, ketosis, evidenced by hyperketonemia with beta-hydroxybutyrate in blood over 0.7 mmol/L, occurs in pregnancy toxemia. This may develop in late pregnancy in ewes bearing multiple fetuses, and is associated with the considerable glucose demands of the conceptuses. In ruminants, because most glucose in the digestive tract is metabolized by rumen organisms, glucose must be supplied by gluconeogenesis, for which propionate (produced by rumen bacteria and absorbed across the rumen wall) is normally the principal substrate in sheep, with other gluconeogenic substrates increasing in importance when glucose demand is high or propionate is limited. Pregnancy toxemia is most likely to occur in late pregnancy because most fetal growth (and hence most glucose demand) occurs in the final weeks of gestation; it may be triggered by insufficient feed energy intake (anorexia due to weather conditions, stress or other causes), necessitating reliance on hydrolysis of stored triglyceride, with the glycerol moiety being used in gluconeogenesis and the fatty acid moieties being subject to oxidation, producing ketone bodies. Among ewes with pregnancy toxemia, beta-hydroxybutyrate in blood tends to be higher in those that die than in survivors. Prompt recovery may occur with natural parturition, Caesarean section or induced abortion. Prevention (through appropriate feeding and other management) is more effective than treatment of advanced stages of ovine ketosis.
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As with PGC-1α, nutritional ketosis may activate FOXO3a by increasing activity of AMPK and sirtuins or by decreasing insulin. Expression of FOXO3a is increased by fasting, caloric restriction, and BHB [103, 105], all of which are or can be components of a ketogenic diet. Furthermore, BHB treatment has extended lifespan in C. elegans in a manner dependent on FOXO3a , and a ketogenic diet (% energy: 89 fat, <1 carbohydrate, and 10 protein) has increased median lifespan and decreased tumors and age-associated losses of physical and cognitive performance, all in conjunction with increased hepatic content of FOXO3a .
There is one exception to exercising with diabetes. If your blood sugar is too high (such as over 240) and you are spilling ketones into your urine, then exercise is only going to increase your blood sugar. You can buy a dipstick urine test to check for ketones, but the best thing to do would be to talk to your doctor about what is safe for you to do.
194. Ruth M. R., Port A. M., Shah M., et al. Consuming a hypocaloric high fat low carbohydrate diet for 12 weeks lowers C-reactive protein, and raises serum adiponectin and high density lipoprotein-cholesterol in obese subjects. Metabolism. 2013;62(12):1779–1787. doi: 10.1016/j.metabol.2013.07.006. [PMC free article] [PubMed] [CrossRef] [Google Scholar]
Bread is one of the foods that people miss most on keto – at least I know I did – and a loaf of almond flour bread is a great alternative. But, for a lot of folks, it’s quite a task to make, because you have to separate eggs, and whisk the whites to stiff peaks and so on. So, for those folks on the go, or those without ovens and those simply without the time or inclination to cook, this 90-second keto bread made in the microwave is the perfect solution. It’s literally as simple as mixing a few ingredients in a mug and popping it in the microwave. And in less than two minutes you have a keto friendly bread, almost as easy as putting bread in the toaster.
It has recently been proposed that the ARC is required for the coordination of homeostatic circadian systems including temperature and activity. Authors tested this hypothesis by injecting saporin toxin conjugated to leptin into the ARC of rats. Wiater et al. showed that the leptin-sensitive network is required for entrainment of activity by photic cues and entrainment of temperature by food but is not required for entrainment of activity by food or temperature by photic cues (Wiater et al., 2013).
The hypothalamus is the brain's main center responsible for hunger/satiety (H/S) control. In the theory that Mayer proposed more than 60 years ago, he assigned a central role to glucose levels in the H/S control: the so-called “glucostatic theory” (Mayer, 1955). Mayer suggested that depletion of carbohydrate availability leads to hunger, and the hypothalamic centers with receptors sensitive to glucose levels might be involved in the short-term regulation of energy intake (Mayer, 1955). The “feeding center” in the lateral hypothalamic area (LHA), according to the glucostatic theory, reacts to the between-meal fall of blood glucose and stimulates food intake. The LHA contains glucose-inhibited neurons that are stimulated by hypoglycemia, a process crucial to mediating the hyperphagia normally induced by hypoglycemia. The subsequent post-prandial hyperglycemia activates the “satiety center” in the ventromedial hypothalamus (VMH), which contains glucose-excited neurons and inhibits both “feeding center” and food intake.
Lipodystrophic disorders in general are associated with metabolic syndrome. Both genetic (e.g., Berardinelli-Seip congenital lipodystrophy, Dunnigan familial partial lipodystrophy) and acquired (e.g., HIV-related lipodystrophy in patients treated with highly active antiretroviral therapy) forms of lipodystrophy may give rise to severe insulin resistance and many of metabolic syndrome's components.
As described throughout the previous sections, there are many instances of codependencies and feed-forward loops in bioenergetic and antioxidant signal transduction, which supports the well-known potential for metabolic stimuli, such as diet or exercise, to have a profound physiological influence. Given the central role of mitochondria in oxidative phosphorylation and ROS production, the overlap between bioenergetic and antioxidant signaling is not surprising and is possibly an outcome of evolution favoring efficiency. PGC-1α is at the center of this overlapping and complex network of codependencies. The likely role of PGC-1α as a coactivator of FOXO3a indicates a possible dependence of FOXO3a transcriptional activity on PGC-1α , indicating FOXO3a as a central mediator as well. Furthermore, FOXO3a induces transcription of PGC-1α [287, 322, 367], and formation and antioxidant transcriptional activity of the PGC-1α-FOXO3a complex are partly dependent on interaction with SIRT1 . In muscle, expression of many of the bioenergetic and antioxidant proteins previously discussed is dependent on PGC-1α . Upstream, activation of PGC-1α is dependent on AMPK  and SIRT1 [242, 269] and partly dependent on SIRT3 . Furthermore, activation of SIRT1 is dependent on AMPK , which may also be the case for SIRT3. AMPK and PGC-1α are therefore two key factors, with critical supporting roles of the sirtuins, in the signal transduction linking bioenergetics to antioxidant defense. Further supporting the relevance of this linkage to nutritional ketosis, expression of AMPK, SIRT1, FOXO3a, and NFE2L2 is required for extension of lifespan in C. elegans by exogenous BHB , and expression of AMPK, p38 MAPK, and NFE2L2 is required for the extension of lifespan, also in C. elegans, by mitohormesis induced through inhibition of glucose metabolism . The induction of AMPK [259, 260], SIRT3 [263, 329], p38 MAPK [310–313], PGC-1α [76, 77, 260, 282, 283], FOXO3a [324, 331, 333], and NFE2L2 [358–360] activity by oxidative stress also makes this signaling highly relevant to mitohormesis [263, 282, 360], especially given that activation of these proteins has been shown to decrease mitochondrial or cellular ROS [76, 263, 282, 289, 323, 332, 334, 356, 359, 367]. Furthermore, mitochondrial biogenesis  and the activities of AMPK [259, 260], SIRT3 , p38 MAPK [311, 312], PGC-1α [76, 77, 260, 283], FOXO3a , and NFE2L2  are increased by H2O2, more specifically associating this signaling with mitohormesis. Given that AMPK and sirtuins are upstream of the majority of this signaling and that AMPK and sirtuin activities are stimulated by both bioenergetic and oxidative stressors, these stressors are likely the primary signals through which nutritional ketosis may induce the mitochondrial and antioxidant adaptations characteristic of mitohormesis (Figure 2).
It just needed a bit more structure, so for trial number three I split the difference, using half coconut flour and half almond flour. There’s a reason they say the third time’s a charm. This was the perfect blend. The bread was moist but firm enough to hold its shape, and it didn’t taste like coconut. After that, I began experimenting: hazelnut flour worked great, and cheese and scallions added great flavor.
A giant, late-night dinner is your blood sugar’s worst enemy. That’s because our bodies become more insulin resistant as the day goes on—so a meal that you eat in the evening will cause a greater spike in blood sugar than a meal you eat in the morning. Because of this, many nutrition experts advise front-loading your meals, or eating bigger meals earlier in the day and having a smaller dinner at least three hours before bed.
Ana, We like using a combination of almond flour and coconut flour for this bread to achieve the best flavor and texture. We haven’t tried this bread using only coconut flour, but it may work. Coconut flour absorbs liquid differently, so you’ll want to use about 1/4 the amount of coconut flour as almond flour (since the recipe calls for 2 cups almond flour, that would be 1/2 cup coconut flour in addition to the 3/4 cup coconut flour that the recipe already calls for). However, the flavor and texture of this bread will likely be different with that substitution. Please let us know how it goes if you give it a try!