Optimal Protein Intake Guide

Your optimal daily protein intake depends on your weight, goal, and level of physical activity: from 1.2–1.8 g/kg if you’re sedentary all the way up to 3.3 g/kg if you’re trying to minimize fat gain during a bulk. You can quickly and easily calculate your optimal daily intake with our protein intake calculator.

How much protein do you need per day?

As with most things in nutrition, there’s no simple answer. Your ideal intake of calories and protein depends on your health, body composition, main goal, and the type, intensity, duration, and frequency of your physical activity. And even taking all this into account, you’ll end up with a starting number, which you’ll need to adjust through self-experimentation.

Daily protein requirements are expressed in grams, either per kilogram of body weight (g/kg) or per pound of body weight (g/lb). Ranges in the table below reflect known individual variances.

Optimal daily protein intake for adults (g/kg *)

image

Maintenance: eucaloric diet | Muscle gain: eucaloric diet (if sedentary) or hypercaloric diet (if active) | Fat loss: hypocaloric diet | * Grams per kilogram of body weight

  • If you’re sedentary, aim for 1.2–1.8 g/kg (0.54–0.82 g/lb). Keep in mind that your body composition is more likely to improve if you add regular activity, especially resistance training, than if you merely hit a protein target.
  • If you’re of healthy weight and active and wish to keep your weight, aim for 1.4–2.0 g/kg (0.64–0.91 g/lb). People who are trying to keep the same weight but improve their body composition (more muscle, less fat) may benefit from the higher end of the range.
  • If you’re of healthy weight and active and wish to build muscle, aim for 1.6–2.4 g/kg (0.73–1.10 g/lb). Intakes as high as 3.3 g/kg may help experienced lifters minimize fat gain when bulking.
  • If you’re of healthy weight and active and wish to lose fat, aim for 1.6–2.4 g/kg (0.73–1.10 g/lb), skewing toward the higher end of this range as you become leaner or if you increase your caloric deficit (by eating less or exercising more). Intakes as high as 3.1 g/kg may enhance fat loss and minimize muscle loss in lean lifters.
  • If you’re overweight, aim for 1.2–1.5 g/kg (0.54–0.68 g/lb). This range, like all the others in this list, is based on your total body weight (most studies on people who are overweight report their findings based on total body weight, but you’ll find some calculators that determine your optimal protein intake based on your lean mass or your ideal body weight). If you’re overweight, fat loss should be your priority, but that doesn’t mean you cannot build some muscle over the same period. (Overweight includes obesity.)
  • If you’re pregnant, aim for 1.7–1.8 g/kg (0.77–0.82 g/lb).
  • If you’re lactating, aim for at least 1.5 g/kg (0.68 g/lb).
  • If you’re vegan or obtain most of your protein from plants, then your protein requirements may be higher because plant proteins are usually inferior to animal proteins with regard to both bioavailability and amino acid profile.

Also, note that …

How much protein you need depends on several factors, such as your weight, your goal (weight maintenance, muscle gain, or fat loss), your being physically active or not, and whether you’re pregnant or not.

Optimal daily protein intake for healthy, sedentary adults

For adults, the US Recommended Dietary Allowance (RDA) for protein is 0.8 g/kg.[2] However, a more appropriate statistical analysis of the data used to establish the RDA suggests this number should be higher: 1.0 g/kg.[3]

Note that, contrary to popular belief, the RDA doesn’t represent an ideal intake. Instead, it represents the minimum intake needed to prevent malnutrition. Unfortunately, the RDA for protein was determined from nitrogen balance studies, which require that people eat experimental diets for weeks before measurements are taken. This provides ample time for the body to adapt to low protein intakes by down-regulating processes that are not necessary for survival but are necessary for optimal health, such as protein turnover and immune function.[4]

An alternative method for determining protein requirements, called the Indicator Amino Acid Oxidation (IAAO) technique, overcomes many of the shortcomings of nitrogen balance studies.[5] Notably, it allows for the assessment of protein requirements within 24 hours, thereby not leaving the body enough time to adapt. Studies using the IAAO method have suggested that about 1.2 g/kg is a more appropriate RDA for healthy young men,[6] older men,[7] and older women.[8][9]

Further evidence that the current RDA for protein is not sufficient comes from a randomized controlled trial that confined healthy, sedentary adults to a metabolic ward for eight weeks.[10] The participants were randomized into three groups:

Three types of hypercaloric diets (40% above maintenance)

MacronutrientsLow proteinNormal proteinHigh protein
Protein (g/kg)
0.7
1.8
3.0
Protein (% of caloric intake)
5
15
25
Fat (% of caloric intake)
54
44
34
Carbohydrate (% of caloric intake)
41
41
41

Each diet was equally hypercaloric: each participant consumed 40% more calories than they needed to maintain their weight. Yet, as shown in the figure below, eating near the RDA for protein resulted in loss of lean mass, and while this loss is so small as to be nonsignificant, the higher protein intakes were associated with increases in lean mass.

image

Another takeaway from this study is that eating more than 1.8 g/kg doesn’t seem to meaningfully benefit body composition, which makes it a good higher end for your daily protein intake, provided that you aren’t physically active or trying to lose weight.

Optimal daily protein intake for healthy, sedentary adults

Body weight (lb)Body weight (kg)Lower end (g)Higher end (g)
100
45
54
82
125
57
68
102
150
68
82
122
175
79
95
143
200
91
109
163
225
102
122
184
250
113
136
204
275
125
150
225
300
136
163
245

In summary, the RDA for protein (0.8 g/kg) underestimates the needs of healthy, sedentary adults, who should rather aim for 1.2–1.8 g/kg (0.54–0.82 g/lb).

Optimal daily protein intake for athletes

If you’re physically active regularly, you need more protein daily than if you were sedentary. The American College of Sports Medicine, the Academy of Nutrition and Dietetics, and the Dietitians of Canada recommend 1.2–2.0 g/kg to optimize recovery from training and to promote the growth and maintenance of lean mass when caloric intake is sufficient.[11] This recommendation is similar to that of the International Society of Sports Nutrition (ISSN): 1.4–2.0 g/kg.[12]

Importantly, it may be better to aim for the higher end of the above ranges. According to the most comprehensive meta-analysis to date on the effects of protein supplementation on muscle mass and strength, the average amount of protein required to maximize lean mass is about 1.6 g/kg, and some people need upwards of 2.2 g/kg.[13] Those of you interested in a comprehensive breakdown of this study will find one in NERD #34 (August 2017).

However, only 4 of the 49 included studies were conducted in people with resistance training experience (the other 45 were in newbies). IAAO studies in athletes found different numbers: on training days, female athletes required 1.4–1.7 g/kg;[14][15] the day following a regular training session, male endurance athletes required 2.1–2.7 g/kg;[16] two days after their last resistance-training session, amateur male bodybuilders required 1.7–2.2 g/kg.[17]

Since higher protein intakes seem to have no negative effects in healthy people, one may want to err toward the higher amounts. For most athletes (and similarly active adults), the ISSN range (1.4–2.0 g/kg) will work well:

Optimal daily protein intake for athletes

Body weight (lb)Body weight (kg)Lower end (g)Higher end (g)
100
45
64
91
125
57
79
113
150
68
95
136
175
79
111
159
200
91
127
181
225
102
143
204
250
113
159
227
275
125
175
249
300
136
191
272

In summary, athletes and similarly active adults can optimize body composition, performance, and recovery with a daily protein intake of 1.4–2.0 g/kg (0.64–0.91 g/lb) and a preference toward the upper end of this range.

Optimal daily protein intake for muscle gain

Resistance training, such as lifting weights, is of course required for muscle gain: you can’t just feed your muscles what they need to grow; you also need to give them a reason to grow.[18]

To gain muscle, most people should aim for 1.6[13]–2.4 g/kg.[19][20][21][22][23]

Assuming progressive resistance overload and a mildly hypercaloric diet (370–800 kcal above maintenance), a few studies suggest you’ll gain less fat if you eat more protein (3.3 g/kg rather than 1.6–2.4 g/kg),[24][20] although one did not.[21]

What’s important to understand is that a daily protein intake of 3.3 g/kg isn’t likely to help you build more muscle than a daily protein intake of 1.6–2.4 g/kg. What the higher number can do is help you minimize the fat gains you’ll most likely experience if you eat above maintenance in order to gain (muscle) weight.

Optimal daily protein intake for muscle gain

Body weight (lb)Body weight (kg)Lower end (g)Higher end (g)
100
45
73
109
125
57
91
136
150
68
109
163
175
79
127
191
200
91
145
218
225
102
163
245
250
113
181
272
275
125
200
299
300
136
218
327

Hypercaloric diet. Intakes as high as 3.3 g/kg may help experienced lifters minimize fat gain while bulking.

In summary, athletes and active adults can optimize muscle gain with a daily protein intake of 1.6–2.4 g/kg (0.73–1.10 g/lb). For experienced lifters on a bulk, up to 3.3 g/kg (1.50 g/lb) may help minimize fat gain.

Optimal daily protein intake for fat loss

First, let it be clear that, though it is possible to lose fat on a eucaloric diet (aka maintenance diet — a diet that provides as many calories as you burn) by shifting your macronutrient ratios toward more protein, if you want to keep losing weight you’ll need to switch to a hypocaloric diet (i.e., you’ll need to start eating fewer calories than you burn).

High protein intakes help preserve lean mass in dieters, especially lean dieters. To optimize body composition, dieting athletes (i.e., athletes on a hypocaloric diet) should consume 1.6–2.4 g/kg,[25][26] skewing toward the higher end of this range as they become leaner or if they increase their caloric deficit (by eating less or exercising more).

Later studies have argued that, to minimize lean-mass loss, dieting lean resistance-trained athletes should consume 2.3–3.1 g/kg (closer to the higher end of the range as leanness and caloric deficit increase).[27] This latter recommendation has been upheld by the International Society of Sports Nutrition (ISSN)[28] and by a review article on bodybuilding contest preparation.[29]

Optimal daily protein intake for fat loss (if you’re an athlete)

Body weight (lb)Body weight (kg)Lower end (g)Higher end (g)
100
45
73
109
125
57
91
136
150
68
109
163
175
79
127
191
200
91
145
218
225
102
163
245
250
113
181
272
275
125
200
299
300
136
218
327

Hypocaloric diet. Intakes as high as 3.1 g/kg may enhance fat loss and minimize muscle loss in lean lifters.

Note that those recommendations are for people who are relatively lean already and trying to lose a little more fat while preserving their precious muscle mass. Several meta-analyses involving people with overweightness or obesity suggest that 1.2–1.5 g/kg is an appropriate daily protein intake range to maximize fat loss.[30][31][32] This range is supported by the European Association for the Study of Obesity, which recommends up to 1.5 g/kg for elderly adults with obesity.[33] It is important to realize that this range is based on actual body weight, not on lean mass or ideal body weight.

Considering the health risks associated with overweightness and obesity,[34][35] it is also noteworthy that eating a diet higher in protein (27% vs. 18% of calories) significantly reduces several cardiometabolic risk factors, including waist circumference, blood pressure, and triglycerides, while also increasing satiety.[36] These effects are small, however, and likely dependent on the amount of body fat one loses.

Optimal daily protein intake for fat loss (if you’re overweight)

Body weight (lb)Body weight (kg)Lower end (g)Higher end (g)
100
45
54
68
125
57
68
85
150
68
82
102
175
79
95
119
200
91
109
136
225
102
122
153
250
113
136
170
275
125
150
187
300
136
163
204

Hypocaloric diet. If you’re overweight or obese, fat loss should be your priority, but that doesn’t mean you cannot build some muscle over the same period.

In summary, dieting for fat loss, athletes and other active adults who are already lean may maximize fat loss and muscle retention with a daily protein intake of 1.6–2.4 g/kg (0.73–1.10 g/lb). People who are overweight or obese are best served by consuming 1.2–1.5 g/kg (0.54–0.68 g/lb).

Optimal daily protein intake for older adults

Sarcopenia is a muscle disorder. It is defined as an impairment of physical function (walking speed or grip strength) combined with a loss of muscle mass.[37][38] It is the primary age-related cause of frailty.

Frailty[39] is associated with a higher risk of disabilities that affect your ability to perform daily activities,[40] a higher risk of having to go to a nursing home,[41] and a higher risk of experiencing falls,[42] fractures,[43] and hospitalizations.[44]

The link between sarcopenia, frailty, and associated morbidities may explain why sarcopenia is associated with a greater risk of premature death and reduced quality of life.[45][46] This isn’t a rare issue, either: in the US, over 40% of men and nearly 60% of women over the age of 50 have sarcopenia, and more than 10% of people in their 20s.[47]

Prevalence of sarcopenia by age and sex in the US

image

Reference: Janssen et al. J Am Geriatr Soc. 2002.[47]

Fortunately, sarcopenia is neither inevitable nor irreversible — some seniors have built more muscle in their old age than they ever had in their youth. The older you get, though, the greater your muscles’ anabolic resistance (i.e., their resistance to growth),[48] and so the more protein you must eat to stimulate muscle protein synthesis.[49][50] (Ideally, this additional protein should complement a resistance-training program.[51][52])

The protein RDA for adults over 50 is currently the same as for younger adults: 0.8 g/kg.[2] Same as for younger adults, however, studies using the IAAO method have suggested that 1.2 g/kg would be a more appropriate RDA.[7][8][9] Moreover, since a low protein intake is associated with frailty and worse physical function than a higher protein intake,[53][54] several authorities now recommend that older adults consume 1.2–1.5 g/kg.[55][56][57] Finally, while all adults have similar daily protein requirements,[58] older adults have higher per-meal requirements.

Notably, doubling protein intake from 0.8 to 1.6 g/kg has been shown to significantly increase lean body mass in elderly men.[59] Similar observations have been made in elderly women who increase their protein intake from 0.9 to 1.4 g/kg.[60] Even a small increase in protein intake from 1.0 to 1.3 g/kg has minor benefits towards lean mass and overall body composition.[61]

So how much protein should you get?

  • Sedentary but healthy seniors: 1.0–1.2 g/kg (0.45–0.54 g/lb)
  • Sick or injured seniors: 1.2–1.5 g/kg (0.54–0.68 g/lb)
  • Seniors wishing to lose weight: 1.5–2.2 g/kg (0.68–1.00 g/lb)
  • Seniors wishing to build muscle: 1.7–2.0 g/kg (0.77–0.91 g/lb)

Daily protein intake based on body weight (BW)

BWBW0.360.450.450.680.770.911.00g/lb
lbkg0.81.01.21.51.72.02.2g/kg
100
45
36
45
54
68
77
91
100
g
125
57
45
57
68
85
96
113
125
g
150
68
54
68
82
102
116
136
150
g
175
79
64
79
95
119
135
159
175
g
200
91
73
91
109
136
154
181
200
g
225
102
82
102
122
153
173
204
225
g
250
113
91
113
136
170
193
227
250
g
275
125
100
125
150
187
212
249
275
g
300
136
109
136
163
204
231
272
299
g

In summary, depending on their health statuses and goals, older adults (50+ years) should aim for a daily protein intake of 1.0–2.2 g/kg (0.45–1.00 g/lb).

Optimal daily protein intake for pregnant women

The protein RDA for pregnant women is 1.1 g/kg.[2] This value was estimated by adding three values:

  • The RDA for a healthy adult (0.8 g/kg)
  • The amount of additional body protein a pregnant woman accumulates
  • The amount of protein used by the developing fetus

However, as we saw previously with non-pregnant healthy adults, the RDA may not be sufficient, let alone optimal. There’s some IAAO evidence that the RDA for pregnant women should be about 1.66 g/kg during early gestation (weeks 11–20) and 1.77 g/kg during late gestation (weeks 32–38).[62][63] Moreover, a meta-analysis of 16 intervention studies reported that protein supplementation during pregnancy led to reduced risks for the baby:[64]

  • 34% lower risk of low gestational weight
  • 32% lower risk of low birth weight
  • 38% lower risk of stillbirth

This effect was more pronounced in undernourished women than in adequately nourished women. Importantly, these values were determined from sedentary women carrying one child, meaning that pregnant women who engage in regular physical activity or are supporting the growth of more than one child may need even higher amounts.

Also, keep in mind that we can only tell you what the studies reported; we can’t possibly know about your health and your pregnancy specifically. Please be sure to consult with your obstetrician/gynecologist (ob/gyn) before making any changes.

Optimal daily protein intake for pregnant women

Body weight (lb)Body weight (kg)Weeks 11–20 (g)Weeks 32–38 (g)
100
45
≥75
≥80
125
57
≥94
≥100
150
68
≥113
≥120
175
79
≥132
≥141
200
91
≥151
≥161
225
102
≥169
≥181
250
113
≥188
≥201
275
125
≥207
≥221
300
136
≥226
≥241

In summary, pregnant women may require a daily protein intake of at least 1.77 g/kg (0.8 g/lb) to support both the fetus and themselves. Protein supplementation during pregnancy appears to lower some risks for the baby — including the risk of stillbirth — especially in undernourished women.

Optimal daily protein intake for lactating women

As with pregnancy, there is little research investigating how lactation and breastfeeding affect protein requirements.[65] Women produce a wide range of breast milk volumes, regardless of their energy status (i.e., milk production is maintained even among underweight women — i.e., women with a BMI under 18.5).[66] The infant’s demands appear to be the primary regulator of milk production.[67][68]

Based simply on adult protein requirements plus the protein output in breast milk, the RDA for lactating women was set at 1.3 g/kg.[2] However, one study reported that half of the lactating women consuming 1.5 g/kg were in negative nitrogen balance,[69] while another study suggested that 1.0–1.5 g/kg leads to a rapid downregulation of protein turnover suggestive of an adaptive response to insufficient intake.[70]

Considering (1) the lack of data on the effects of a protein intake greater than 1.5 g/kg in lactating women and (2) that consuming 1.5 g/kg or less leads to adaptations suggestive of insufficient intake, lactating women should aim to consume at least 1.5 g/kg of protein daily.

Optimal daily protein intake for lactating women

Body weight (lb)Body weight (kg)Protein intake (g)
100
45
≥68
125
57
≥85
150
68
≥102
175
79
≥119
200
91
≥136
225
102
≥153
250
113
≥170
275
125
≥187
300
136
≥204

In summary, lactating women should aim for a daily protein intake of at least 1.5 g/kg.

Optimal daily protein intake for infants and children

Optimal daily protein intake for infants and children
in grams per kilogram of body weight (g/kg)

Infants
(preterm)
Infants
(0–6 months)
Infants
(7–12 months)
Toddlers
(1–3 years)
Children
(4–13 years)
Sedentary
3.0–4.0
≥1.5
≈3.0
3.0–4.0
≥1.5 g/kg
Active
n/a
n/a
n/a
n/a
unknown

Optimal daily protein intake for infants

Healthy infants

The adequate protein intake of healthy infants aged 0–6 months, based on their average weight and milk intake, is 1.52 g/kg.[71]

The average protein intake of healthy infants aged 7–12 months is estimated at 1.6 g/kg,[72] assuming that half their protein comes from breast milk and half from complementary foods. Yet the RDA is set at 1.2 g/kg for this age group based entirely on studies conducted in toddlers and children.[73]

Preterm infants

Preterm infants need to be fed enough protein to promote growth rates similar to those observed in healthy fetuses growing in utero. The following daily intakes have been recommended based on gestational age:[74]

  • 3.5–4.0 g/kg (less than 30 weeks)
  • 2.5–3.5 g/kg (30–36 weeks)
  • 2.5 g/kg (more than 36 weeks)

Moreover, a systematic review by the Cochrane Collaboration reported greater weight gain and higher nitrogen accretion in preterm infants whose protein intake was 3.0–4.0 g/kg, compared to lower daily intakes.[75] These findings were echoed by another systematic review of 24 clinical trials.[76]

Since breast milk doesn’t contain enough protein to meet these requirements, complementary supplementation is standard practice.[77][78]

Formulas

Breast milk is considered the optimal source of nutrition for infants (0–12 months old) and is recommended as the exclusive source of nutrition for non-preterm infants aged 0–6 months. However, not all infants can breastfeed. Infant formulas provide an alternative, but there are considerable differences in composition from breast milk.[79] One such difference is the protein content, which tends to be higher in formula.

Compared to exclusive breastfeeding, formula feeding is associated with greater increases in fat-free mass throughout the first year of life. Fat mass and body fat percentage tend to be lower during the first six months, but play catch-up afterward and ultimately end up higher with formula feeding than with breastfeeding.[80]

An association was found between formula feeding, faster growth during infancy, and obesity in childhood, adolescence, and young adulthood.[81] Some researchers suggested that the higher protein content of infant formulas was responsible,[82] but others have argued that there are too many contributing factors (e.g., breastfeeding helps infants learn to better regulate their energy intake) to single one out.[83]

Moreover, if the higher protein content of formulas were responsible for the infants’ accelerated growth, then how could we explain the similar growth of infants fed formulas containing 1.2 or 1.7 grams of protein per 100 milliliters,[84] or formulas containing 1.0, 1.3, or 1.5 grams of protein per 100 milliliters?[85] (For reference, breast milk contains about 1 gram of protein per 100 milliliters.)

Still, even if consuming more protein from formulas than would be obtained from breast milk is not necessarily detrimental, it doesn’t appear to confer a benefit. There is no good reason to stray from the nutrient composition of mother’s milk during infancy, unless dealing with a preterm infant.

Meat

When complementary foods are introduced to infants during the latter half of infancy (7–12 months), there may be a benefit to more protein from meat.[86] Compared to feeding cereal grains alongside breast milk (total protein: 1.4 g/kg/day), feeding pureed meats alongside breast milk (total protein: 2.9 g/kg/day) was shown to lead to better growth without excess fat gain.[87]

Another study demonstrated that, as a complementary food, meat led to more favorable growth patterns than dairy (higher length-for-age and lower weight-for-length) by 12 months of age[88] — differences that persisted at the age of 2 years.[89] Both the meat group and the dairy group consumed the same total protein (3.0 g/kg).

In summary, during their first six months, healthy infants should consume at least 1.5 grams of protein per kilogram of body weight per day (≥1.5 g/kg/day). This intake can be achieved exclusively through breastfeeding. From age 6 to 12 months, they should consume around 3.0 g/kg/day (and could especially benefit from using meat as complementary food). Preterm infants require 3.0–4.0 g/kg/day to facilitate catch-up growth.

Optimal daily protein intake for toddlers

The same data used to establish the RDA for infants aged 7–12 months (1.2 g/kg) was used to determine the RDA for toddlers aged 1–3 years (1.05 g/kg).[2] The average daily protein intake of US toddlers is 4.0 g/kg, with 90% of US toddlers consuming over 3.0 g/kg.[90]

There is a dearth of data for this age group. However, in toddlers aged 2 years with a total daily protein intake of 4.0 g/kg, complementary protein from meat led to better growth (higher length-for-age) than the same amount of complementary protein from dairy.[89]

In summary, there is little research on what is optimal, but the average daily protein intake of US toddlers is 4 g/kg — nearly four times the RDA. Meat appears to be a better complementary food than milk.

Optimal daily protein intake for children

The protein RDA is slightly higher for children (4–13 years) than for adults: 0.95 versus 0.8 g/kg.[2] This difference makes sense considering that children are still growing and need more protein to facilitate the process. As with adults, however, the RDA may underestimate true requirements.

Use of the IAAO technique in children aged 6–11 years has suggested that around 1.5 g/kg would make for a more appropriate RDA.[91] Protein requirements are likely higher in children involved in sports and other athletic activities.[92]

There are no long-term studies on optimal protein intake since it would be unethical to deprive children of the protein they need for their development and various physiologic and metabolic functions.

In summary, children require at least 1.5 grams of protein per kilogram of body weight per day (1.5 g/kg/day). An unknown amount of additional protein is likely required by children who are involved in sports or otherwise regularly active.

Optimal daily protein intake for vegetarians and vegans

The protein requirements discussed so far were based on studies conducted mostly in omnivores, including trials that used animal-protein supplements (whey protein powders, notably). People whose diet is mostly or entirely plant-based may need higher protein intakes,[93] due to the lower quality of plant proteins.

Protein quality

A dietary protein’s quality is determined by this protein’s bioavailability and amino acid profile.

BIOAVAILABILITY

Plants contain trypsin inhibitors, phytates, tannins, and other antinutrients that prevent some of the protein you ingest from being digested.[94] Antinutrients can be reduced, but not entirely removed, by cooking. Plant-protein powders, being mostly free of antinutrients, are about as digestible (as bioavailable) as animal protein.[95]

Digestibility of various plant and animal proteins

image

Reference: FAO. Protein Quality Evaluation in Human Nutrition. 2013[96]

AMINO-ACID PROFILE

All proteins, including the protein you eat and the protein in your body, are made from some combination of 20 amino acids (AAs). Your body can produce 11 of these AAs, making them nonessential amino acids (NEAAs). Your body cannot produce the other 9, which are therefore essential amino acids (EAAs) you must get through food.

Building muscle requires that, cumulatively, muscle protein synthesis (MPS) exceeds muscle protein breakdown (MPB), resulting in a net accumulation of muscle protein. All 20 AAs are required to build muscle tissue,[97] but MPS is stimulated primarily by the EAAs in your food.[98] Unfortunately, plant proteins are lower in EAAs (and therefore higher in NEAAs) than animal proteins.

EAA content of plant and animal proteins

image

Reference: FAO. Protein Quality Evaluation in Human Nutrition. 2013[96]

In particular, plant proteins are lower in leucine. This EAA is believed to act as a signal to “turn on” anabolic signaling pathways and thereby MPS,[99][100] although all EAAs are required for the effect to persist.[101]

Leucine content of plant and animal proteins

image

Reference: van Vliet et al. J Nutr. 2015[102]

Plant proteins being lower in leucine and other EAAs helps explain why several studies have reported lower MPS from soy protein powders and beverages than from whey protein,[103][104][105] skim milk,[106] whole milk with cheese,[107] and lean beef.[50]

In summary, the quality of a protein depends on its bioavailability and EAA content. Based on both criteria, the quality of plant proteins is lower than the quality of animal proteins.

How to compensate for the lower quality of plant proteins

When the scarcity of a given EAA in a given protein bottlenecks protein synthesis, this EAA is called a limiting amino acid (LAA) for this protein.[108] Cereal grains, such as wheat and rice, are low in lysine, as are most nuts and seeds. Beans and legumes, on the other hand, are poor in sulfurous amino acids, such as methionine and cysteine.

Conversely, as this table shows, pea and soy have a lot of lysine, and rice a lot of methionine and cysteine; and as the graphic above shows, corn (maize) has a lot of leucine. The solution to the LAA problem is therefore obvious: we can combine different plant proteins to make up for their respective deficits.[109] Historic examples of such combinations include beans with corn in the Americas and rice with soybean in Asia. These grain-legume combos work because legumes supply the lysine missing in grains whereas grains supply the methionine and cysteine missing in legumes.

Combining incomplete proteins

image

Adapted from: Woolf et al. PLoS One. 2011[109]

You can also supplement with individual EAAs, notably leucine. MPS was increased similarly by 25 grams of whey protein (providing 3 grams of leucine) and by a combination of 6.25 grams of whey protein and 4.25 grams of supplemental leucine (5 grams of leucine in total).[110] A rodent study using plant proteins reported similar results.[111]

Finally, you can compensate for the lower quality of plant proteins simply by eating more. In a 2016 randomized controlled trial (RCT) in healthy older men, when equated for leucine content (4.4 g), whey protein (35 g) increased peak plasma leucine more than did wheat protein (60 g), but the two proteins increased MPS rates similarly (wheat a little more, but the difference wasn’t statistically significant).[112] Similarly, in a 2020 RCT, when equated for leucine content (2.5 g), mycoprotein (70 grams; 31.5 grams as protein) increased resting and postexercise MPS rates more than did milk protein (31 grams; 26.2 grams as protein).[113]

But if you can increase your gains by increasing your intake of plant proteins, can’t you increase them even more by increasing your intake of animal proteins?

Yes, you certainly can … up to a certain point. While differences in MPS from animal and plant proteins do appear to translate to differences in lean mass when modest supplemental doses are used (≈20 g/day),[114][115] when higher doses are used (33–50 g/day), animal-based (whey) and plant-based (soy, rice) supplemental proteins appear to affect lean mass similarly.[116][117][118][119] In other words, if your protein intake is high enough, it no longer matters if the protein comes from an animal or a plant. This would explain why, in another 2020 RCT, older adults on a high-protein diet (1.8 g/kg/day) saw similar increases in MPS whether the protein was mostly from animal sources or entirely from plant sources (57% mycoprotein).[120]

In summary, the EAA deficits of plant proteins can be overcome by eating more, combining complementary proteins, and/or supplementing with leucine.

How much protein per meal?

Muscle protein synthesis (MPS) is the process of building new skeletal muscle tissue. When MPS chronically exceeds muscle protein breakdown (MPB), resulting in a positive net protein balance, we can expect muscle growth over the long term.[121][122] Each time you eat represents an opportunity to promote muscle growth through the stimulation of MPS.

Protein-feeding studies using various doses of whey protein suggest that 0.24 g/kg/meal will maximize the MPS of the average young adult,[49] whereas 0.40 g/kg/meal will maximize the MPS of most young adults.[123] For older adults, these two values jump to 0.40 and 0.60 g/kg/meal.[49]

Desirable minimal protein intake range per meal and age

Body weight (lb)Body weight (kg)20s30s, 40s, 50s≥60
100
45
11–18
13–24
18–27
125
57
14–23
16–30
23–34
150
68
16–27
20–36
27–41
175
79
19–32
23–42
32–48
200
91
22–36
26–48
36–54
225
102
24–41
30–54
41–61
250
113
27–45
33–60
45–68
275
125
30–50
36–66
50–75
300
136
33–54
39–72
54–82

The ranges in this table represent individual variations. The minimum protein requirements increase as you age, but to what degree is uncertain because of the age gap left by the studies: most subjects were in their 20s (0.24–0.40 g/kg) or 60s/70s (0.40–0.60 g/kg). For people in their 30s, 40s, or 50s, the 0.29–0.53 g/kg range reflected in this table is an educated guess.
References: Schoenfeld and Aragon. J Int Soc Sports Nutr. 2018. [124] Rafii et al. J Nutr. 2016. [7] Morton et al. Front Physiol. 2015. [123] Moore et al. J Gerontol A Biol Sci Med Sci. 2015. [49] Rafii et al. J Nutr. 2015. [8]

Your mileage may vary. The ranges above are not ideal ranges. Instead, they cover the known extent of interindividual variations among healthy adults. In other words, if you’re in your 20s, you don’t need to calculate your protein intake per meal so that it falls precisely within the 0.40–0.60 g/kg range. Rather, your minimum protein intake per meal (to maximize MPS) is likely to fall within that range.

Further, there are at least three good arguments in favor of eating toward or even above the higher end of your range:

First, the ranges we listed are derived from studies using whey protein in isolation. Whey protein is highly bioavailable, rich in essential amino acids (EAAs), and quickly digested. When eating lower-quality or slower-digesting proteins (as would occur when eating a meal, #daily-protein-intake-vegetarians), higher protein intakes are probably required.

Second, while these values suggest a protein-intake threshold for maximally stimulating MPS, there is no known threshold for whole-body protein balance.[125] For example, a study using meals with lean beef found that 40 and 70 grams of protein (0.5 and 0.8 g/kg) led to similar increases in MPS, but that 70 grams led to greater increases in whole-body protein synthesis and greater decreases in whole-body protein breakdown.[126] In other words, eating more protein may not necessarily translate to greater muscle-protein turnover and growth, but since muscle tissue accounts for only 25–30% of whole-body protein turnover,[127] the additional protein is not “wasted” (a common myth).

Third, as shown above in the Prevalence of sarcopenia by age and sex in the US graphic, even people in their twenties can suffer from sarcopenia — in which case they would benefit from a protein intake closer to the one recommended in this table for adults over sixty.

You may have heard that if you eat more than 30 grams of protein in one sitting, the “excess” will pass undigested, but that’s just a myth. It is however true that spreading your protein intake over a few meals, making sure that you meet your desirable minimal protein intake per meal with each meal, will generally result in greater lean mass and strength. A pragmatic review article suggests that, to maximize their lean mass, active adults should consume 1.6–2.2 g/kg/day spread across four meals (0.40–0.55 g/kg/meal).[124]

In summary, for maximal stimulation of muscle protein synthesis, aim for a per-meal dose of quality protein (such as can be found in meat, eggs, and dairy) of 0.4–0.6 g/kg. Higher doses will not be wasted and are probably necessary when eating mixed meals that contain a variety of protein sources.

How much protein after exercise?

After exercising, when your muscles are more sensitive to the anabolic effect of protein, take a dose in the range of your desirable minimal protein intake per meal. If you’ve been exercising on an empty stomach, you’ll be in negative protein balance, so take this dose as soon as possible. Otherwise, try to take it within a couple of hours — the exact size of your “window of opportunity” depends on how much protein you’re still digesting.[133]

How to get enough protein

You’ve used our table or calculator to determine how much protein you need in a day, but the numbers don’t look right. Let’s say you’re 125 pounds, of healthy weight, physically active, and trying to get even leaner. You discover that your optimal intake starts at 102 grams of protein. Isn’t that too much for someone so light?

So it may seem at first blush. But let’s take a step back. Let’s say you’re 125 pounds, of healthy weight, sedentary, and just trying to keep the same body composition. Your optimal intake starts at 68 grams of protein — so 272 kcal (less than 16% of the maintenance daily calories of a sedentary 40-year-old, 125-pound, 5’4” female). Not so daunting, now, is it?

Next, you decide to add physical exercise, in order to get even leaner. If you are 125 pounds and run at 7.5 mph (8 minutes/mile) for just ½ hour, you burn 375 kcal, compared to 41 for computer work. In other words, you burn 334 kcal more than when sitting and typing — just about the least physically demanding activity.

If you took those added kilocalories solely as protein, that would make 84 grams of protein. Add 84 grams to your optimal protein intake when you don’t exercise, and you get 152 grams of protein — way more than your 102 grams starting target. (Since protein isn’t the best source of energy, you could instead choose to get 102 grams of protein and 50 grams of carbs and/or fat.)

We can also calculate from the other direction. You’re 125 pounds and of healthy weight, going from sedentary to active in order to get even leaner: how will your protein intake change?

At least 102 grams of protein (active)
At least 68 grams of protein (sedentary)
At least 34 grams of additional protein
At least 136 additional kcal

In other words, to make optimal use of protein to lose fat and preserve muscle when you’re 125 pounds and already of healthy weight, you need to exercise so as to burn, on average, for just 136 Calories of extra protein. If you run at 7.5 mph (8 minutes/mile) for just ½ hour and take 34 grams of extra protein but don’t otherwise eat more than when you were sedentary and your body composition was stable, you’ll end the day on a deficit of 198 kcal.

Even a small caloric deficit will lead to weight loss, though your body actually plays by more complicated mathematics than the ones we’ve just used. In practice, you might want to increase your caloric deficit a little, either by reducing your intake of carbs and/or fat or simply by exercising a little more.

One last thing: how can you get 34 grams of extra protein without much extra carbs or fat? You can either take one heaping scoop of protein powder, probably at the end of your workout, or modify your diet so as to eat more protein (and less fat and/or carbs) over the whole day, by including more protein-rich foods in your meals.

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