Month: June 2021

This morning, I posted on social media about the extreme heat wave that the Vancouver-area will be having over the weekend, with temperatures hitting as high as 40° C or higher, which is almost 105°F. One of the people that follows me on social media mentioned about the risk of leaving clear water bottles in a car on a hot sunny day, and which I had read about this in previous years, but never thought much about it, as I always parked in a garage.

Since my car was currently out on the street and I remembered that I had a partly filled water bottle in it,  I went out to remove it. On my way back inside I thought of writing a social media post about the risk of leaving a partially- or completely-filled water bottle in a vehicle, which results from sunshine passing through the windshield, and then through the water in the bottle — acting like a magnifying glass.

While there is a risk of burn marks to the interior of a vehicle and smoldering as a result of this type of light magnification through water bottles, reports of full-blown vehicle fires resulting from this are unheard of, although theoretically possible. What is well-established, however is that there are over 600 deaths per year in the US as a result of extremely hot weather [1].

Extreme heat are summer temperatures that are much hotter and/or humid than average [1] — such as the 40° C temperatures that are expected for the Vancouver-area this coming weekend. While extreme heat makes people of all ages more prone to getting dehydrated, infants under the age of 4 and adults over the age of 65 are especially at risk [1].

As people age, the amount of available water in their body decreases largely as a result of having decreased lean body mass (muscle), compared to younger people. I’ve mentioned decreased lean body mass as people age in previous articles about sarcopenia — which is the loss of muscle as people age. I’ve highlighted the importance of older adults being eating sufficient protein to reduce the risks of falls, and about how much protein older adults should eat but since muscle holds more water than fat, retaining muscle mass as people age also has the added benefit of helping older people to stay adequately hydrated.

[UPDATE (August 14, 2023) Here is the most recent article about protein intake in older adults and the importance of ensuring adequate intake of the amino acid leucine.]

Women are at higher risk of becoming dehydrated in the heat than men of the same age, because men at any age have a higher amount of muscle and therefore a higher percentage of body water than women. This means that older women (compared to older men) are often at greater risk of dehydration.

The following table lists the average percentage of water in the body, according to age and gender, as well as their ranges [2].

As can be seen from the above table, adult men and older men have, on average almost 10% more body water than women of the same age, so it can take a less time for a woman to get dehydrated in the heat, than for a man.

While we remind children and young adults to be sure to drink when they are thirsty, older adults also are less aware that they are dehydrated because the feeling of thirst decreases as people age [3]. For this reason, it is important that older adults drink more especially when they don’t feel thirsty.

Another reason that older people get dehydrated easier is that kidney function decreases with age, and the hormonal response to dehydration (which is handled in part by the kidney) may be impaired [4]. Other factors that contribute to older people becoming dehydrated easier include conditions such uncontrolled (or undiagnosed) diabetes which can cause more urination, or as the result of the effect of various medications that they may be taking, such as diuretics for high blood pressure. Older adults with osteoarthritis in the knees or hips may find it more difficult to go get water, while others may have some memory impairment that keeps them from remembering when they last drank some water.

A heat wave is an excellent time to check in more frequently on an aging parent, or even on elderly neighbours that you are friendly with.

But what to look for?

Symptoms of dehydration may include dry mouth, or feeling overly tired, but dry mouth is a common side-effect of many medications that older people may be taking, and feeling fatigued may not  be that unexpected. Finding out if they are feeling dizzy, or light-headed may be helpful and if is comfortable to ask, find out if the person is urinating less, or if their urine is darker in colour. The can provide helpful clues that they are already dehydrated.

Serious symptoms may include confusion or disorientation, feeling faint, or having diarrhea or vomiting, so be sure to seek medical treatment if these symptoms are present. Severe dehydration can result in the person going into hypovolemic shock as a result of low blood volume, or having seizures if they have lost too much sodium and potassium in the urine.

If you are checking on older parents or on elderly neighbours, consider bringing along a few bottles of sparkling water, or a non-sweetened flavoured soda such as Bubbly® which can encourage them to drink more when it’s hot outside, and seeing if they have a fan that is safely set up may also help them stay cooler. These are not “big” things to do, but to older adults can make a great deal of difference in extreme heat.

…and when you are out and about, remember not to leave partially- or completely-filled water bottles in your car, as sunlight passing through the windshield and then the water bottle can cause burn marks and even a smoldering fire.

To your good health!

Joy

You can follow me on:

Twitter: https://twitter.com/lchfRD
Facebook: https://www.facebook.com/BetterByDesignNutrition/

References

1. Centres for Disease Control and Prevention (CDC), About Extreme Heat, https://www.cdc.gov/disasters/extremeheat/heat_guide.html
2. National Academies Press, Dietary Reference Intakes for Water, Potassium, Sodium, Chloride and Sulfate, Chapter 6: Water, 2005. https://www.nap.edu/read/10925/chapter/6, pg 73
3. Picetti D, Foster S, Pangle AK, et al. Hydration health literacy in the elderly. Nutr Healthy Aging. 2017;4(3):227-237. Published 2017 Dec 7. doi:10.3233/NHA-170026
4. British Nutrition Foundation, Dehydration in the Elderly, https://www.nutrition.org.uk/nutritionscience/life/dehydrationelderly.html

Copyright ©2021 BetterByDesign Nutrition Ltd.

LEGAL NOTICE: The contents of this blog, including text, images and cited statistics as well as all other material contained here (the ”content”) are for information purposes only.  The content is not intended to be a substitute for professional advice, medical diagnosis and/or treatment and is not suitable for self-administration without the knowledge of your physician and regular monitoring by your physician. Do not disregard medical advice and always consult your physician with any questions you may have regarding a medical condition or before implementing anything  you have read or heard in our content.

 

This week, the weather forecast for the Vancouver area is for hot and hotter, so I thought it would good to revisit a wonderful summer drink that I enjoy to help cool off, and replace fluids.

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Most people know that when it’s hot out that they need to drink more but are concerned that caffeine-containing drinks such as iced coffee, tea, or matcha or various types of sodas such as cola which contain caffeine can cause dehydration. But is it true?

While caffeine is a mild diuretic (makes you urinate more), a 2014 study which compared the effect of drinking coffee with the effects of drinking the same amount of water (keeping other things constant) found no difference in hydration status between the two groups.  In the study [1], fifty men who usually drank 3-6 cups of coffee per day were asked to drink 4 x 200 ml cups of coffee containing 4 mg/kg caffeine per day for 3 days, while having their total body water calculated.  Then the men switched and drank 4 x 200 ml of water for 3 days, while having total body water calculated — and during both arms of the study, amounts of physical activity, food and other fluids were controlled for. The study found that there were no differences in several markers of hydration status between the groups — so no, caffeine won’t dehydrate you but for many, too much caffeine interferes with sleep, gives them headaches if they drink varying amounts on different days or causes them to feel agitated or nervous. As well, for those with Gastroesophageal Reflux Disease (GERD), caffeine can increase heartburn and other symptoms due to its effect on relaxing the lower esophageal sphincter (LES) — resulting in the contents of the stomach more easily backing up into the lower esophagus, resulting in discomfort.

But what’s the alternative? Plain water? It is a choice, but some find it boring.

Others enjoy bottled club soda or make their own using a Sodastream, or they drink one of the brands of commercial unsweetened bubbly drinks that are available in various flavours — but some people can’t tolerate carbonated drinks, so what’s left?

How about Limonana?

Limonana is a drink that I only learned about a few years ago (and wrote about here) and that I enjoyed so much yesterday that I put up a new pitcher at lunch time, and have it chilling in the fridge for later. Since I wrote about it in 2016, I have lost more than 50 pounds and put my type 2 diabetes and high blood pressure into remission, so no longer make that sugary version that I wrote about previously.  The recipe below is what I am making now.

“Limonana” is named for it’s two main ingredients, lemon and mint. In Arabic or Hebrew, “limon” means lemon, and “nana” means mint and this drink is lemonade with a twist. It is a wonderfully refreshing and cooling drink on the hottest of days, like today or this weekend.

I make Limonana using a sugar-free Monk Fruit and erythritol sweetener, so it is very low in carbohydrate and doesn’t spike insulin or blood glucose, and I use fresh mint that I grow on my counter — but any fresh mint will do. Dried mint is a very last resort.

There are two essentials (in addition to fresh mint) that are needed for Limonana, and the first is it must be made with fresh lemons and the pulp of the lemon (none of that bottled stuff!!). The second thing is it must be served over lots of ice cubes.

Here is the recipe for one liter (~a quart) of Limonana. Enjoy!

Limonana

• 3 lemons
• 16-20 fresh mint leaves
• 4 Tbsps. Monk Fruit / erythritol sweetener (or to taste)
• 450 ml cold water
• a whole tray of ice cubes
• Sprig of mint to garnish (optional)

1. Dissolve the Monk Fruit / erythritol sweetener in a bit of hot water and set aside.
2. Using a knife, remove the peel from the lemon and be sure to cut off all the white pith as it is bitter. Separate the sections of lemon flesh from the membranes – like one does for orange suprí¨mes. Discard the membranes and any seeds, and put the flesh of the lemon into a blender.
3. Add the mint and Monk Fruit / erythritol sweetener and pulse a few times until the mint leaves are well chopped. Add the ice cold water and pulse again to mix. Taste the Limonana and add more sweetener, if necessary.
4. Allow to chill in the fridge for a bit, to let the flavour mature.
5. When ready to serve, put plenty of ice cubes into a tall glass and pour the Limonana over them. Drink as is, or garnish with the mint sprig and serve.

 

To your good health!

Joy

You can follow me on:

Twitter: https://twitter.com/JoyKiddie
Facebook: https://www.facebook.com/BetterByDesignNutrition/

References

1. Killer S.C, Blannin A.K., Jeukendrup A.E., No Evidence of Dehydration with Moderate Daily Coffee Intake: A Counterbalanced Cross-Over Study in a Free-Living Population, PLOS One, January 4, 2014, https://doi.org/10.1371/journal.pone.0084154

Copyright ©2021 BetterByDesign Nutrition Ltd.

LEGAL NOTICE: The contents of this blog, including text, images and cited statistics as well as all other material contained here (the ”content”) are for information purposes only.  The content is not intended to be a substitute for professional advice, medical diagnosis and/or treatment and is not suitable for self-administration without the knowledge of your physician and regular monitoring by your physician. Do not disregard medical advice and always consult your physician with any questions you may have regarding a medical condition or before implementing anything  you have read or heard in our content.

 

The human body is able to use carbohydrate, fat or protein to generate energy, however only carbohydrate and fat are major fuel sources.  Protein’s role in the diet is mainly to provide amino acids needed by the body to make its own proteins, for structure and function.

During digestion, carbohydrate, fat and protein from food are broken down into their basic components — carbohydrates are broken into simple sugar and turned into glucose, proteins are broken down into amino acids, and fat is broken down into fatty acids and glycerol.

Protein is not usually used for energy, although small amounts of amino acids from broken down protein are used by the body when we’re resting, and even smaller amounts are used when we’re doing moderate-intensity exercise[1].

During moderate-intensity exercise, our body will use half fatty acids as fuel and half glucose. During high-intensity exercise our body will rely on glucose as fuel — both from the carbohydrates we ate, as well as generated by breaking down fat stores. It is only if we are not getting enough calories in our food or from our fat stores that protein will be used for energy[2] and burned as fuel. If more protein is eaten than is needed by the body, the excess will be broken down and stored as fat [2].

Determining Individual Macros

In determining the amount of protein, fat and carbohydrate that each individual needs (i.e. “macros”), choosing the amount of protein we require comes first. The amount of carbohydrate and fat is chosen after that — based on the needs of the individual for blood sugar control and their metabolic health.

Since it is not a primary fuel source for the body, think of protein as the base of a balance scale — providing the body with building blocks for structure and function. The two arms of the balance are the two sources of fuel for energy: carbohydrate and fat. 

How do we choose the amount of protein we need?

We need to have enough protein for our needs, but not so much as to either store the excess as fat — or worse, to exceed the ability of our body to get rid of the excess nitrogen-by-product in the urine. Since 84% of the nitrogen waste produced from protein intake is excreted as urea in the urine[3], the safe upper limit of protein intake is based on the maximum rate of urea production which is 3.2 g protein per kg of ideal body weight [4] i.e. lean body mass.

NOTE: this calculation is based on lean body mass (also known as Ideal Body Weight or Ideal Body Mass (IBW), not total body weight. Lean body mass is essentially one’s total body weight minus the amount of fat they have.

Lean body mass can be assessed using a DEXA scan, or estimated by using relative fat mass (RFM). The amount of fat someone has can be estimated from total body weight (taken on a scale), minus their estimated RFM as described in this article.

Once we know a person’s lean body mass, we can use the equation (3.21 g of protein / kg lean body mass) to determine the maximum amount of protein they can eat on an ongoing basis while being able to safely dispose of the ammonia via urea through urine.

Basic protein requirements are set in the Recommended Daily Allowance (RDA) for protein, which is the level that is sufficient to meet the needs of 97-98 % of healthy people and to prevent deficiency. The RDA for protein for healthy adults is calculated at 0.8 g protein / kg of reference body weight (i.e. IBM) [5]. Remember, this is the bare minimum to prevent deficiency in most people.

For those who are physically active, the Academy of Nutrition and Dietetics, Dietitians of Canada, and the American College of Sports Medicine[6] recommend a protein intake of 1.2—2.0 g protein / kg IBW per day to optimize recovery from training, and to promote the growth and maintenance of lean body mass.

Older people also need more protein in order to maintain muscle mass, and prevent sarcopenia (muscle loss associate with aging). There have been several position statements issued by those that work with an aging population indicating that protein intake between 1.0 and 1.5 g protein / kg IBW per day may best meet the needs of adults during aging [7,8].

Balancing Carbohydrate and Fat as Fuel

There are 3 ways that carbohydrate and fat as fuel can be balanced — and which one is best for a specific individual depends on their protein needs (outlined above), as well as their metabolic health.

Higher Carbohydrate than Fat

The standard American (and Canadian) diet recommended by national dietary guidelines aims for the majority of fuel (energy intake) to come from carbohydrate.

These diets are High Carb, Low Fat (HCLF) diets.

They are “high carb” because they provide >225g – 300 g carbohydrate / day, 45-65% of total energy intake.

They are “low fat” as they provide “not more than 30% of calories from fat [9].

For those who are metabolically healthy, a high carbohydrate diet where carbohydrate sources are unrefined whole grains (include the husk and the bran), as well as unprocessed starchy vegetables such as yam, peas and winter squash is certainly one option. The problem is that 88% of Americans are already metabolically unwell [10], with presumably a large percentage of Canadians as well.

People who are already showing indications that they are not tolerating carbohydrate well; manifest either as high HOMA-IR, pre-diabetes or type 2 diabetes might do better to select another option for their main fuel source  — especially given that the American Diabetes Association (ADA) consensus report on Diabetes and pre-diabetes published on April 2019 indicated that;

”Reducing overall carbohydrate intake for individuals with diabetes has demonstrated the most evidence for improving glycemia and may be applied in a variety of eating patterns that meet individual needs and preferences[11].”

Higher Fat than Carbohydrate

Low Carb, High Fat (LCHF) diets are one type of diet that provides more fuel (energy) from fat, than from carbohydrate. There is another type, outlined below.

These range from the popularized “keto diet” of Dr. Jason Fung and the Diet Doctor website which typically provide ~75% fat, 15% protein, ~10% carbohydrate — to the recommendations of Dr. Stephen Phinney and Dr. Jeff Volek from their book The Art and Science of Low Carbohydrate Living which recommends ~60-70% fat, 20%-up to 30% protein, and 10% carbohydrate [12].

These are considered “low carb” diets when they provide < 130g carbohydrate / day, < 26% of total energy intake and “very low carb” (ketogenic) diets when they provide 20—50g carbohydrate / day, < 10% total energy intake — based on the definition from Feinman et al [13] which defines very low carbohydrate, low carbohydrate, and moderate carbohydrate diets as follows:

1. very low carbohydrate diet: 20—50g carbohydrate /day, < 10% total energy intake

2. low carbohydrate diet: < 130g carbohydrate / day, < 26% of total energy intake

3. moderate carbohydrate diet: 130—225g carbohydrate / day, 26—45% of total energy intake

The same definitions of “low carbohydrate” and “very low carbohydrate” are also used in the clinical guidelines of the American Diabetes Association [11], as well as Diabetes Canada [15] where these are meal pattern options for those with diabetes and pre-diabetes to control blood sugar.

Balanced Fat and Carbs

This type of diet is a High Protein, Low Fat (HPLF) diet and the best-known is the P:E Diet of Dr. Ted Naiman.

The P:E Diet is “high protein” diet – recommending 40% protein with equal amounts of fat (30%) and carbohydrate (30%) — as generated by the P:E ratio Macro Calculator  (located at the bottom of www.p2eq.com);

The P:E diet is “low fat” as it provides “not more than 30% of calories from fat [9].

For the most part, the P:E diet is “moderate carb” — providing ~130—225g carbohydrate per day — although for some weights and heights, the carbohydrate content is slightly below the 130 g carbs / day cut-off for “low carb” (see examples from the P to E Macro Calculator, above).

While a high protein intake makes sense for those seeking to build and sculpt muscle, setting the recommendation for protein at 40% of dietary intake (instead of as “g protein per kg body weight”) can result in protein sometimes coming close to exceeding the excretion rate for urea of 3.2 g protein per kg reference body weight. 

This could be avoided if the P:E Macro Calculator was set a maximum limit of protein of 3.0 g protein / per kg body weight.

Low Carbohydrate High Protein

A Low Carb High Protein (LCHP) diet provides ~25-30% protein, which is significantly higher than the 10-20% protein of the standard American (or Canadian diet), yet without the possibility of exceeding the urea excretion capacity of the kidney as protein intake is set to up to 2.5 grams protein per kg body weight (which is well below the maximum of 3.2 g protein / kg ideal body weight).

Having high protein, it offers more satiety at less than half the calories of fat [16] — which makes much more sense for someone seeking weight loss.

Like the Low Carb, High Fat diets of Dr. Jason Fung and Diet Doctor (~75% fat, 15% protein, ~10% carbohydrate) this diet is “high fat”, and provides 65-70% fat. In a sense, a Low Carb High Protein meal pattern reflects the higher end of the range of Dr. Stephen Phinney and Dr. Jeff Volek’s approach of ~60-70% fat, 20%-up to 30% protein, and 10% carbohydrate.

This meal patterns provides a wide range of fats from olive oil and avocado oil to (depending on the lipid profile of the person) butter and coconut oil. Most of the fat provided in the diet is not from added fat, but from fat that comes along with protein — such as the fat in meat, cheese, nuts or yogurt.

Most significantly, this meal pattern is “low carb” (< 130g carbohydrate / day) or “very low carb” / ketogenic — providing ~20—50g carbohydrate / day and as a low carb diet “has demonstrated the most evidence for improving glycemia” [11].

For those seeking fat loss but already having difficulty handling carbohydrate, a Low Carb High Protein (LCHP) meal pattern offers the “best of both worlds”.

It offers the benefits of being able to build new muscle, as well as lower the risk of muscle loss.

It also offers the higher satiety of high protein — without the possibility of exceeding the body’s ability to excrete ammonia in the urine.

…and it is “low carb” — providing the improved blood sugar control that “low carb” is known for.

Final Thoughts…

Humans only have two primary fuel sources, so meal patterns such as Low Carb High Fat, Low Carb High Protein and P:E (High Protein Low Fat) always come down to a choice between “low carb” or “low fat”.

Whether low carb or low fat is the most suitable for someone depends on their protein needs and metabolic health.

For those seeking to improve blood sugar or put type 2 diabetes into remission, either one of the low carb options work, however it has been my experience that peri- and post-menopausal women often do much better on the higher protein version of a low carb diet when it comes to weight loss. 

Over the last few months, I have also been asked to provide metabolically healthy people with a High Protein Meal Plan — which I do, although I set an upper limit on protein intake to a maximum of 2.0 g protein per kg ideal body weight.

Different people have different goals and health needs, which is why I offer more than one type of meal pattern. While a P:E diet is just on the edge of “low carb” — it is very much “low carb” when compared with the Standard American (and Canadian) diet.

Nutrition is BetterByDesign!

More Info?

If you are interested in having me design a Meal Plan for you, then please have a look at the Complete Assessment Package under the Services tab (for those in Canada).

If you are outside of Canada and would like me to provide you with Nutrition Education for either low carb high fat or low carb high protein, then please have a look the Meal Plan Package under the Services tab.

To your good health!

Joy

You can follow me on:

Twitter: https://twitter.com/JoyKiddie
Facebook: https://www.facebook.com/BetterByDesignNutrition/

References

1. Fuel Sources. (2020, August 13). Retrieved May 24, 2021, from https://med.libretexts.org/@go/page/7071
2. Youdim A, Merck Manual, Carbohydrates, Proteins and Fats, https://www.merckmanuals.com/en-ca/home/disorders-of-nutrition/overview-of-nutrition/carbohydrates-proteins-and-fats
3. Tomé D, Bos C, Dietary Protein and Nitrogen Utilization, The Journal of Nutrition, Volume 130, Issue 7, July 2000, Pages 1868S—1873S, https://doi.org/10.1093/jn/130.7.1868S
4. Rudman D, DiFulco TJ, Galambos JT, Smith RB 3rd, Salam AA, Warren WD. Maximal rates of excretion and synthesis of urea in normal and cirrhotic subjects. J Clin Invest. 1973;52(9):2241-2249. doi:10.1172/JCI107410
5. National Academies Press, Dietary Reference Intakes for Energy, Carbohydrate, Fiber, Fat, Fatty Acids, Cholesterol, Protein and Amino Acids (2005)
6. Thomas DT, Erdman KA, Burke LM. American College of Sports Medicine Joint Position Statement. Nutrition and Athletic Performance [published correction appears in Med Sci Sports Exerc. 2017
7. Fielding RA, Vellas B, Evans WJ, Bhasin S, et al, Sarcopenia: an undiagnosed condition in older adults. Current consensus definition: prevalence, etiology, and consequences. International working group on sarcopenia. J Am Med Dir Assoc. 2011 May;12(4):249-56
8. Bauer J1, Biolo G, Cederholm T, Cesari M, et al. Evidence-based recommendations for optimal dietary protein intake in older people: a position paper from the PROT-AGE Study Group. J Am Med Dir Assoc. 2013 Aug;14(8):542-59
9. Institute of Medicine (US) Committee on Examination of Front-of-Package Nutrition Rating Systems and Symbols; Wartella EA, Lichtenstein AH, Boon CS, editors. Front-of-Package Nutrition Rating Systems and Symbols: Phase I Report. Washington (DC): National Academies Press (US); 2010. Appendix B, FDA Regulatory Requirements for Nutrient Content Claims. Available from: https://www.ncbi.nlm.nih.gov/books/NBK209851/
10. Araíºjo J, Cai J, Stevens J. Prevalence of Optimal Metabolic Health in American Adults: National Health and Nutrition Examination Survey 2009—2016. Metabolic Syndrome and Related Disorders Vol 20, No. 20, pg 1-7, DOI: 10.1089/met.2018.0105
11. Evert, AB, Dennison M, Gardner CD, et al, Nutrition Therapy for Adults With Diabetes or Prediabetes: A Consensus Report, Diabetes Care, Ahead of Print, published online April 18, 2019, https://doi.org/10.2337/dci19-0014
12. Volek JS, Phinney SD, The Art and Science of Low Carbohydrate Living: An Expert Guide, Beyond Obesity, 2011
13. Feinman RD, Pogozelski WK, Astrup A, Bernstein RK, Fine EJ,Westman EC, et al. Dietary Carbohydrate Restriction as the First Approach in Diabetes Management: critical review and evidence base. Nutrition. 2015;31(1):1—13
14. Diabetes Canada, Diabetes Canada Position Statement on Low Carbohydrate
    Diets for Adults with Diabetes: A Rapid Review Canadian Journal of Diabetes (2020), doi: https://doi.org/10.1016/j.jcjd.2020.04.001
15. Stubbs J, Ferres S, Horgan G, Energy Density of Foods: Effects on Energy Intake, Critical Reviews in Food Science and Nutrition, 40:6, 481-515, 2010

 

Copyright ©2021 BetterByDesign Nutrition Ltd.

LEGAL NOTICE: The contents of this blog, including text, images and cited statistics as well as all other material contained here (the ”content”) are for information purposes only.  The content is not intended to be a substitute for professional advice, medical diagnosis and/or treatment and is not suitable for self-administration without the knowledge of your physician and regular monitoring by your physician. Do not disregard medical advice and always consult your physician with any questions you may have regarding a medical condition or before implementing anything  you have read or heard in our content.