A Systematic Comparison of Quantity and Composition Across Animal and Plant-Based Protein Isolates: A comparison of nine protein isolates shows pea, egg-white, whey, and soy have the most balanced amino acid profiles for muscle, skin, and overall health.

Krisha Tripathy, BSA; Anurag Tarmaster, BS; Ajay S. Dulai, MBBS, MSc; Anissa Gabrin, BS; Raja Sivamani, MD, MS, AP

doi:10.64550/joid.9a3e6s28

Original Research

06 Aug 2025

A Systematic Comparison of Quantity and Composition Across Animal and Plant-Based Protein Isolates

Krisha Tripathy, BSA, Anurag Tarmaster, BS, Ajay S. Dulai, MBBS, MSc, Anissa Gabrin, BS, Raja Sivamani, MD, MS, AP

Original Research

19 Dec 2025

A Systematic Comparison of Quantity and Composition Across Animal and Plant-Based Protein Isolates

Krisha Tripathy, BSA, Anurag Tarmaster, BS, Ajay S. Dulai, MBBS, MSc, Anissa Gabrin, BS, Raja Sivamani, MD, MS, AP

Article Info

DOI:
10.64550/joid.9a3e6s28

Reviewed by:
Apple Bodemer, MD, Negar Foolad, MD MAS

Abstract

# Relevance

Proteins, composed of amino acids, play a critical role in muscle synthesis, metabolism, and immune function. Protein isolates, derived from animal and plant sources, vary in their amino acid compositions and are frequently used to supplement dietary protein intake.
# Methods
This study aims to compare the amino acid profiles of nine protein isolates focusing on their relative deficiencies and abundances. We selected protein isolates from animal-based (whey, casein, beef, egg white) and plant-based (soy, pea, rice, pumpkin seed, hemp seed) sources for comparison. Data of the average quantities of amino acids from at least four brands per protein type were extracted. The amino acid compositions were compared relative to each other and against whey isolate. Z-scores and test statistics were used to quantify comparisons and assign ranks.

# Results
Egg-white, soy, and pea protein contained no relative amino acid deficiencies. Beef, rice, and hemp seed-based protein isolates were deficient in several amino acids. The leucine content was highest in whey and pea protein sources. High leucine content may inform dietary recommendations due to its association with muscle synthesis and activation of mTOR, linked to aging, insulin resistance, and inflammatory skin conditions. Arginine plays a role in nitric oxide and collagen production and was found to be more abundant in plant-based protein sources (pumpkin seed, pea, and hemp seed) compared to whey.

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Introduction

A protein is a polymer composed of amino acids in a chain of α-peptide bonds which are important in many processes in the body.¹ Proteins synthesized by amino acids are essential to skeletal muscle repair, the production of cell-specific metabolites, the formation of immune-supporting antibodies, replenishing enzymes, nourishing the gut microbiome, and a host of other physiological functions (Figure 1).^2–4 Sufficient dietary protein can help increase skeletal muscle mass and strength, normal function of enzymes, normal hair and nail growth, and aid in wound and skin repair mechanisms, while a deficiency in protein can cause anemia, growth stunting, impaired immunity and weakness (Table 2).² Furthermore, research has demonstrated that reduced dietary protein intake and muscle loss is associated with reduction in the functional decline of elderly individuals.⁵

317319 Table 1. Essential and non-essential amino acids.<sup class="article-superscript" onclick="javascript:openmodal('bibr', 'ref-518981')">6</sup>

Essential Amino Acids	Histidine^, Isoleucine^, Leucine^, Lysine^, Methionine^, Phenylalanine*^, Threonine^, Tryptophan*^, Valine^
Non-essential Amino Acids	Alanine, Arginine, Asparagine, Aspartate, Cysteine, Glutamate, Glutamine, Glycine, Proline, Serine, Taurine, Tyrosine

Key: The symbol ^* denotes an essential amino acid throughout the tables and manuscript

317320 Table 2. Amino Acid Functions<sup class="article-superscript" onclick="javascript:openmodal('bibr', 'ref-518982')">7</sup>

Amino Acid	Essential vs. Non-essential	BCCA or Not	Antioxidant Effects	Skin related effects	Gut related effects	Brain related effects	Other effects	Notes
Alanine	Non-essential	No	Minimal	None	Supports glucose metabolism	Supports cognitive function by influencing glucose metabolism	Energy metabolism, muscle function	May be useful in athletes or low-carb diets
Arginine	Non-essential	No	Precursor to nitric oxide, can reduce oxidative stress	May support hair growth, collagen production, and wound healing	Important for gut blood flow	Precursor to neurotransmitters like nitric oxide	Immune function, vasodilation	May cause gastrointestinal discomfort or low blood pressure in some
Aspartic Acid	Non-essential	No	None	None	None	Neurotransmitter, supports brain function	Energy production in cells	Supplementation is rarely needed as it is abundant in most proteins
Cystine	Non-essential	No	Antioxidant (precursor to glutathione)	Protects skin from oxidative stress	Supports gut cell health	Helps brain function via antioxidant properties	Detoxification, cell health	Can contribute to kidney stones in high doses in susceptible individuals
Glutamic Acid	Non-essential	No	None	Supports collagen production	Key in gut function, promotes healing	Major neurotransmitter, excitatory in the brain	Protein synthesis, energy production	High MSG levels may cause headaches in sensitive individuals
Glycine	Non-essential	No	Antioxidant (precursor to glutathione)	Supports collagen synthesis, skin elasticity	Supports gut integrity	Supports neurotransmitter functions (inhibitory)	Detoxification, collagen synthesis	High doses may cause gastrointestinal discomfort
Histidine ^*	Essential	No	None	Supports skin barrier function	Supports gut health (acid-base balance)	Precursor to histamine, which influences brain function	Myelin sheath, anemia prevention	Avoid in histamine-sensitive individuals
Isoleucine*	Essential	Yes	None	None	Supports gut barrier function	Enhances brain function by stabilizing blood glucose	Muscle repair, immune function	May cause gastrointestinal issues at high doses of BCAAs
Leucine ^*	Essential	Yes	None	Supports muscle repair, some collagen support	Supports gut barrier function	Enhances muscle recovery and cognitive performance	Stimulates muscle protein synthesis	Activates mTOR pathway for muscle protein synthesis
Lysine*	Essential	No	None	Supports collagen, wound healing	Supports gut health (intestinal permeability)	Supports neurotransmitter synthesis (serotonin)	Immune function, calcium absorption	Commonly used for cold sore prevention. May cause mild gastrointestinal discomfort
Methionine ^*	Essential	No	Antioxidant (precursor to cysteine and glutathione)	Supports skin health	Helps in detoxification processes	Important for brain health, mood regulation	Methylation, detoxification	Key methyl donor in detoxification and gene expression. High intake can raise homocysteine levels, increasing cardiovascular risk
Phenylalanine ^*	Essential	No	None	Supports production of pigment	Supports gut motility	Precursor to neurotransmitters (dopamine, norepinephrine)	Mood and cognitive support	Should be avoided by individuals with PKU
Proline	Non-essential	No	None	Important for collagen production, supports skin elasticity	Supports gut integrity	Enhances brain function through collagen-related processes	Wound healing, connective tissue	Can cause digestive issues at high doses
Serine	Non-essential	No	None	Supports skin hydration and barrier function	Supports gut health (intestinal lining)	Crucial for neurotransmitter function (serotonin precursor)	Cell membrane structure, immune function	Excessive levels can disrupt neurotransmitter balance
Threonine ^*	Essential	No	None	Supports collagen, skin health	Supports gut lining integrity	Involved in brain function, especially in memory processes	Immune support, gut barrier	High doses may cause digestive upset
Tryptophan ^*	Essential	No	Antioxidant (precursor to serotonin, melatonin)	Supports mood regulation, sleep quality	Affects gut-brain axis	Precursor to serotonin, influencing mood and sleep	Sleep regulation, mood balance	High doses can cause serotonin syndrome when combined with serotonergic drugs
Tyrosine	Non-essential	No	Antioxidant (precursor to dopamine)	Some indirect effects via dopamine regulation	Can affect gut-brain signaling	Important for mental performance under stress	Cognitive function, mood regulation	High doses can cause headaches or jitteriness
Valine ^*	Essential	Yes	None	None	Supports gut barrier function	Enhances brain function via blood glucose regulation	Muscle function, energy metabolism	High doses can lead to amino acid imbalances, causing fatigue or cramps

Table 2 describes each amino acid, whether they are essential or non-essential, are branched-chain, and their antioxidant effects, skin-related effects, gut-related effects, brain-related effects, other effects, and any additional comments of interest related to the amino acid.

Key: The symbol ^* denotes an essential amino acid throughout the tables and manuscript

Figure 1.

Description: Protein Intake, Breakdown, and Downstream Effects

Protein is found in foods such as meat, beans, dairy, and nuts,⁸ all of which contribute to the daily recommendation for intake of 0.8 g/ kg of protein.² However, an increase of up to 1.6 g/ kg or greater for protein intake is recommended for individuals with intense physical activity.² A protein supplement, commonly in the form of a powdered protein isolate, can be an effective addition to an individual’s diet to help them achieve their protein goals.

Protein isolate can be sourced from animal sources such as dairy (casein and whey), beef or egg-white, or from plant-based sources such as pea, soy, pumpkin seed, and rice, and hemp seeds. While various sources of protein isolates exist, they are not equivalent and contain varying compositions of non-essential amnio acids and essential amino acids, which will be denoted with a “*” throughout the manuscript (Table 1). To better understand the variability in composition, we investigated the average amino acid compositions of protein isolates from various commercial sources currently on the market.

Materials and Methods

2.1. Search Methods

The amino acid profiles of nine different sources of protein isolates were retrieved directly from commercial websites. At least four brands were selected for each protein isolate source and missing or incomplete data was resolved by contacting the manufacturers directly.

2.2. Choosing Protein Sources

A diverse array of protein isolate sources were selected, including both animal-based and plant-based sources. We were specific in our search for protein isolates as opposed to protein concentrates, as the latter would likely contain additives which affect the amino acid content. The protein types chosen were whey, casein, beef, egg-white, soy, pea, rice, pumpkin seed, and hemp seed.

2.3. Data Extraction

Commercially available protein isolates only contained 18 amino acids and none of them contained the non-essential amino acids glutamate or asparagine. Data for the amino acid content was compiled for 18 amino acids across the 9 isolates chosen. Four to five brands were chosen, from which the mean amino acid quantities in milligrams per 100 grams were calculated. These mean quantities were used to compare the amino acid profiles across the protein sources.

2.4. Visualization of Amino Acid Profiles

The amino acid profiles for each protein isolate were illustrated using a lollipop chart generated with the ggplot2 package in R (R Foundation for Statistical Computing, Vienna, Austria). This chart displayed the mean quantities of individual amino acids, enabling direct comparisons of specific amino acid contents between the protein isolates.

2.5. Statistical Analysis and Visualization of T-Tests and Z-Scores

The total protein content for each isolate was calculated as the sum of the quantities of all 18 amino acids. Z-scores were calculated for each amino acid from every protein source by subtracting the overall mean from the corresponding amino acid quantity and dividing by the standard deviation across the nine isolates. Protein sources were then ranked by their z-scores within each amino acid. Additionally, their total z-scores, or z-score sum from all the amino acids was also considered. A heat map was generated to visualize the individual z-score results, with positive z-scores in red indicating a higher amino acid content and negative z-scores in blue indicating a lower amino acid content with respect to the mean. The mean rankings for z-scores within each amino acid were also tabulated and visualized via a bar chart. In this research, we associated quality with diversity of amino acid profile, which is determined by the z-score sum. Thus, a high-quality protein has a strong balance of amino acids.

To assess differences in amino acid content between protein isolates, a series of independent t-tests were performed. The mean quantity of each amino acid was compared to whey, chosen due to its commercial popularity. Positive t-statistics indicate the amino acid content was greater than in whey, while negative t-statistics indicated it was lower than in whey. Statistical significance was defined as p < 0.05, and percent differences between means were calculated for statistically significant comparisons.

To visualize the results, a heat map was generated with t-statistics driving the intensity of each cell. Positive t-statistics were identified in shades of red and negative t-statistics in shades of blue. Significant differences (p < 0.05 and p < 0.001) were annotated on the heat map.

Z-score sums were calculated using the equation shown below, where µ is the mean quantity across all isolates for a given amino acid a, and σ is the standard deviation across all isolates for that amino acid. X is the quantity of that amino acid in protein isolate i. N = 9 isolates and n = 18 amino acids measured.

Z s u m = ∑ a = 1 n X a i − μ a σ a

2.6. Software and Tools

All statistical analyses and visualizations were conducted using R version 4.4.1 within the RStudio integrated development environment (Posit Software, PBC, Boston, Massachusetts, USA). Graphical representations, including the lollipop chart, heat maps, and bar chart, were created using the ggplot2 package. The datasets used for this analysis were pre-processed and analyzed in R. The Shannon diversity index was calculated using the vegan package in R.

Results

3.1. Whey Protein

Whey protein is derived from milk during cheese production.⁶ Whey protein served as the reference standard for t-test comparisons.

Arginine had a low z-score (-1.63), indicating a lower than average content compared to the other isolates. Aspartic acid, cystine, isoleucine*, leucine*, lysine*, and threonine* had high z-scores (1.13, 1.20, 1.71, 1.67, 1.65, 2.22), indicating a greater than average content compared to the other isolates.

Proline (7742.38 mg/100 g), leucine* (7398.58 mg/100 g), and lysine* (6240.98 mg/100 g) were the most represented amino acids in whey isolate.

3.2. Casein Protein

Casein is derived from milk by precipitating the protein through acidification or enzyme (rennet) treatment.⁷ Amino acids which had increased relative abundance compared to those in whey protein include arginine (36.86%, p = 0.0258), histidine* (48.31%, p = 0.0243), phenylalanine* (38.83%, p = 0.0167), proline (42.91%, p = 0.0337), and tyrosine (42.08%, p = 0.0475). Amino acids which had decreased relative abundance when compared to whey protein include alanine (47.12%, p = 0.0011), aspartic acid (41.05%, p = 0.0043), cystine (82.78%, p = 0.0010), leucine* (23.69%, p = 0.0261), lysine* (28.42%, p = 0.0179), threonine* (45.65%, p = 0.0059), and tryptophan* (15.85%, p = 0.0429).

Arginine had a low z-score (-1.30), indicating a lower than average content compared to the other isolates. Glutamic acid, histidine*, methionine*, tyrosine, and valine* had high z-scores (1.08, 1.19, 1.27, 1.34, 1.13), indicating a greater than average content compared to the other isolates.

Proline (7723.38 mg/100 g), leucine* (7198.58 mg/100 g), and lysine* (6040.98 mg/100 g) were the most represented in casein isolate.

3.3. Beef Protein

Beef protein isolate is derived from animal meat.⁹ Amino acids which had increased relative abundance when compared to those in whey protein include alanine (88.77%, p = 0.0000), arginine (287.72%, p = 0.0000), glycine (1205.34%, p = 0.0000), and proline (123.63%, p = 0.0001). Amino acids which had decreased relative abundance when compared to whey protein include aspartic acid (41.17%, p = 0.0060), cystine (95.42%, p = 0.0007), glutamic acid (34.15%, p = 0.0121), isoleucine* (74.15%, p = 0.0010), leucine* (66.91%, p = 0.0002), lysine* (59.45%, p = 0.0009), methionine* (60.35%, p = 0.0001), phenylalanine* (25.69%, p = 0.0151), threonine* (68.50%, p = 0.0013), tryptophan* (83.44%, p = 0.0020), tyrosine (69.72%, p = 0.0001), and valine* (48.81%, p = 0.0022).

Alanine, glycine, and proline had high z-scores (2.26, 2.58, 2.19), indicating a greater than average content compared to the other isolates. Cystine, histidine*, isoleucine*, leucine*, methionine*, phenylalanine*^*, tryptophan*^*, tyrosine, and valine*^* had low z-scores (-1.26, -1.28, -1.47, -1.35, -1.29, -1.36, -2.04, -1.76, -1.26), indicating a lower than average content compared to the other isolates.

Glycine (19209.52 mg/100 g), proline (12085.71 mg/100 g), and glutamic Acid (10395.24 mg/100 g) were the most represented in beef isolate.

3.4. Egg-white Protein

Egg-white protein is a low-fat, and low-carb protein source that is particularly high in albumin, which is a highly bioavailable form of protein.¹⁰ The only amino acid that had increased relative abundance when compared to whey protein was arginine (162.58%, p = 0.0053). Amino acids which had decreased relative abundance include glutamic Acid (31.27%, p = 0.0156), lysine* (39.45%, p = 0.0047), and threonine* (46.76%, p = 0.0054).

Methionine*, serine, and valine* had high z-scores (1.62, 1.53, 1.20), indicating a greater than average content compared to the other isolates.

Glutamic Acid (10850.03 mg/100 g), arginine (5182.10 mg/100 g), and lysine* (5110.20 mg/100 g) were the most represented in egg-white isolate.

3.5. Soy Protein

Soy protein is derived from soybeans.¹¹ Amino acids which had increased relative abundance when compared to whey protein include arginine (219.07%, p = 0.0000), glycine (127.38%, p = 0.0000), histidine* (49.03%, p = 0.0088), and phenylalanine* (56.39%, p = 0.0004). Amino acids which had decreased relative abundance include alanine (23.03%, p = 0.0287), isoleucine* (35.76%, p = 0.0175), leucine* (28.37%, p = 0.0100), lysine* (38.36%, p = 0.0059), methionine* (39.80%, p = 0.0008), and threonine* (48.46%, p = 0.0062).

Cystine, glutamic acid, and histidine* had high z-scores (1.83, 1.08, 1.22), indicating a greater than average content compared to the other isolates.

Leucine* (6757.02 mg/100 g), arginine (6297.02 mg/100 g), and lysine* (5201.55 mg/100 g) were the most represented in soy isolate.

3.6. Pea Protein

Pea protein, derived from yellow split peas, is a highly digestible plant-based protein source.¹² When compared to those in whey protein, amino acids which had increased relative abundance include arginine (292.39%, p = 0.0016), glycine (147.80%, p = 0.0017), histidine* (45.73%, p = 0.0154), and phenylalanine* (79.13%, p = 0.0033). Amino acids which had decreased relative abundance include cystine (59.17%, p = 0.0034), methionine* (52.40%, p = 0.0019), threonine* (43.65%, p = 0.0080), and tryptophan* (31.86%, p = 0.0147).

Aspartic acid, histidine*, phenylalanine*, serine, and tyrosine had high z-scores (1.55, 1.22, 1.61, 1.02, 1.02), indicating a greater than average content compared to the other isolates.

Arginine (7744.03 mg/100 g), phenylalanine* (4823.52 mg/100 g), and glycine (3646.59 mg/100 g) were the most represented in Pea isolate.

3.7. Rice Protein

Rice protein is typically derived from brown rice.¹³ No amino acids in rice protein had increased relative abundance in comparison to those in whey protein. Amino acids which had decreased relative abundance include aspartic acid (49.90%, p = 0.0159), cystine (52.05%, p = 0.0096), isoleucine* (58.23%, p = 0.0039), leucine* (53.07%, p = 0.0078), lysine* (80.33%, p = 0.0001), proline (57.17%, p = 0.0089), threonine* (77.70%, p = 0.0011), and tryptophan* (39.40%, p = 0.0166).

Aspartic acid, histidine*, lysine*, serine, and threonine* had low z-scores (-1.12, -1.05, -1.28, -1.14, -1.10), indicating a lower than average content compared to the other isolates.

Aspartic Acid (4761.05 mg/100 g), leucine* (4427.07 mg/100 g), and proline (2314.56 mg/100 g) were the most represented in Rice isolate.

3.8. Pumpkin Seed Protein

Pumpkin seed protein is a nutrient-dense, plant-based protein that is a source of magnesium, zinc, and iron.¹⁴ When compared to the whey protein amino acid profile, arginine (304.69%, p = 0.0004) and glycine (126.28%, p = 0.0026) had increased relative abundance in pumpkin seed protein.

Arginine had a high z-score (1.10), indicating a greater than average content compared to the other isolates.

Amino acids which had decreased relative abundance include alanine (32.06%, p = 0.0057), cystine (65.78%, p = 0.0019), glutamic Acid (27.19%, p = 0.0194), isoleucine* (44.57%, p = 0.0051), leucine* (42.44%, p = 0.0019), lysine* (64.41%, p = 0.0080), proline (63.36%, p = 0.0090), threonine* (68.76%, p = 0.0009), and valine* (39.92%, p = 0.0410). Glutamic acid (11493.33 mg/100 g), arginine (7986.67 mg/100 g), and leucine* (5430.00 mg/100 g) were the most represented in pumpkin seed isolate.

3.9. Hemp Seed Protein

Hemp seed protein is a plant-based protein derived from cleaning, hulling, and processing hemp seeds to isolate the protein.¹⁵ Amino acids which had increased relative abundance when compared to whey protein include arginine (221.05%, p = 0.0031) and glycine (50.54%, p = 0.0117). Amino acids which had decreased relative abundance when compared to whey protein include alanine (52.27%, p = 0.0005), aspartic acid (44.07%, p = 0.0030), cystine (59.62%, p = 0.0026), glutamic acid (52.54%, p = 0.0070), isoleucine* (63.29%, p = 0.0017), leucine* (63.72%, p = 0.0002), lysine* (76.20%, p = 0.0004), methionine* (33.62%, p = 0.0025), proline (60.11%, p = 0.0069), serine (34.10%, p = 0.0169), threonine* (69.40%, p = 0.0014), tryptophan* (51.83%, p = 0.0038), tyrosine (38.45%, p = 0.0141), and valine* (47.48%, p = 0.0026).

Glutamic acid, isoleucine*, leucine*, lysine*, serine, and valine* had low z-scores (-1.50, -1.01, -1.21, -1.13, -1.28, -1.20), indicating a lower than average content compared to the other isolates.

Glutamic Acid (7492.00 mg/100 g), arginine (6336.00 mg/100 g), and aspartic acid (5315.33 mg/100 g) were the most represented in hemp seed isolate.

3.10. Protein Source Rankings

The protein sources were ranked for each amino acid by comparison against the other protein sources and Table 5 shows a tabular histogram of how often a rank position was noted for an amino acid source. Pea and whey protein had the most instances of an amino acid ranking in the top three among the protein sources assessed. Notably, only egg-white, soy, and pea protein sources did not have an amino acid that ranked last when compared against other protein sources. An overall ranking of protein quality based on the mean z-score is depicted in Figure 6. Pea protein ranked first among all nice isolate sources followed by egg-white and soy.

317321 Table 3. Mean Amino Acid Content by Protein Isolate

	Whey	Casein	Beef	Egg-white	Soy	Pea	Rice	Pumpkin Seed	Hemp Seed
Alanine	4441	2348	8382	5457	3418	3802	3012	3017	2119.33
Arginine	1974	2701	7652	5182	6297	7744	4245	7987	6336
Aspartic Acid	9503	5602	5591	7889	9080	10394	4761	6410	5315
Cystine	2338	403	107	1694	2915	954	1121	800	944
Glutamic Acid	15786	16104	10395	10850	16091	15412	9489	11493	7492
Glycine	1472	1456	19210	5997	3346	3647	2369	3330	2215
Histidine ^*	1515	2247	1098	1746	2258	2208	1208	1690	1317
Isoleucine ^*	5497	4076	1421	3959	3531	4040	2296	3047	2018
Leucine ^*	9433	7199	3122	6671	6757	7351	4427	5430	3422
Lysine ^*	8439	6041	3422	5110	5202	6628	1660	3003	2009
Methionine ^*	1915	2232	759	2433	1153	912	1477	1383	1271
Phenylalanine ^*	2693	3738	2001	4254	4211	4824	2940	2987	2358
Proline	5404	7723	12086	5058	4015	4161	2315	1980	2156
Serine	3892	4130	3059	5144	4381	4673	2691	3273	2564
Threonine ^*	5997	3259	1889	3193	3091	3379	1337	1873	1835
Tryptophan ^*	1244	1047	206	1025	1224	848	754	1377	599
Tyrosine	2610	3709	790	2690	2906	3406	2715	1483	1606
Valine ^*	4766	5021	2439	5107	3717	4403	3391	2863	2503

Key: The symbol ^* denotes an essential amino acid throughout the tables and manuscript

317322 Table 4. Z-Scores Across All Amino Acids and Protein Isolates

	Whey	Casein	Beef	Egg-white	Soy	Pea	Rice	Pumpkin Seed	Hemp Seed
Alanine	0.24	-0.84	2.26	0.76	-0.29	-0.09	-0.50	-0.59	-0.95
Arginine	-1.63	-1.30	0.94	-0.18	0.33	0.98	-0.60	1.10	0.35
Aspartic Acid	1.13	-0.72	-0.72	0.36	0.93	1.55	-1.12	-0.56	-0.85
Cystine	1.20	-0.93	-1.26	0.49	1.83	-0.33	-0.14	-0.52	-0.34
Glutamic Acid	0.99	1.08	-0.63	-0.49	1.08	0.87	-0.90	-0.49	-1.50
Glycine	-0.59	-0.59	2.58	0.22	-0.25	-0.20	-0.43	-0.29	-0.46
Histidine ^*	-0.38	1.19	-1.28	0.12	1.22	1.22	-1.05	-0.23	-0.81
Isoleucine ^*	1.71	0.60	-1.47	0.51	0.18	0.66	-0.79	-0.40	-1.01
Leucine ^*	1.67	0.60	-1.35	0.35	0.39	0.74	-0.73	-0.45	-1.21
Lysine ^*	1.65	0.62	-0.52	0.21	0.25	0.98	-1.28	-0.80	-1.13
Methionine ^*	0.72	1.27	-1.29	1.62	-0.60	-0.97	-0.04	-0.31	-0.40
Phenylalanine ^*	-0.66	0.40	-1.36	0.93	0.88	1.61	-0.41	-0.40	-1.00
Proline	0.13	0.84	2.19	0.02	-0.30	-0.26	-0.82	-0.93	-0.87
Serine	0.17	0.43	-0.74	1.53	0.70	1.02	-1.14	-0.69	-1.28
Threonine ^*	2.22	0.27	-0.71	0.22	0.15	0.39	-1.10	-0.70	-0.75
Tryptophan ^*	0.99	0.42	-2.04	0.35	0.94	-0.13	-0.44	0.81	-0.89
Tyrosine	0.17	1.34	-1.76	0.26	0.49	1.02	0.29	-0.92	-0.89
Valine ^*	0.89	1.13	-1.26	1.20	-0.08	0.65	-0.38	-0.95	-1.20

Table 4 shows the z-scores for each amino acid within the nine protein isolates. Values greater than positive 1 are highlighted in red and values less than -1 are highlighted in blue. Z-scores >1 indicate a higher amino acid content relative to the mean amino acid content across all nine isolates. Z-scores < -1 indicate a lower amino acid content relative to the mean amino acid content across all nine isolates.

Key: The symbol ^* denotes an essential amino acid throughout the tables and manuscript

317323 Table 5. Ranking Protein Sources by Z-Scores Within Each Amino Acid

	Rank 1	Rank 2	Rank 3	Rank 4	Rank 5	Rank 6	Rank 7	Rank 8	Rank 9
Whey	5	2	5	0	1	2	1	1	1
Casein	2	3	5	3	0	1	0	3	1
Beef	3	0	1	0	0	1	4	0	9
Egg-white	3	3	1	5	5	1	0	0	0
Soy	1	3	4	3	5	1	1	0	0
Pea	3	7	1	3	2	1	0	1	0
Rice	0	0	0	3	0	4	5	3	3
Pumpkin Seed	1	0	1	0	5	5	4	1	1
Hemp Seed	0	0	0	1	0	2	3	9	3

Table 5 displays the number of amino acids for which each protein isolate source was ranked first through ninth.

Figure 2.

Description: Screening, Inclusion, and Exclusion of Protein Isolates

Figure 3.

Description: Amino Acid Content by Protein Isolate Source

Figure 4.

Description: Z-Score Heat Map

Figure 5.

Description: T-Statistic Heat Map

Figure 6.

Description: Mean Z-Score Rankings

Discussion

The comparison of amino acid profiles across various protein isolates reveals significant differences in both the relative and absolute quantities of essential and non-essential amino acids. The analysis underscores the impact of protein source—whether animal or plant-based—on the specific amino acid composition and highlights the importance of these differences in protein quality. The data shows marked variation in the amino acid content across different protein isolates, with each source offering unique advantages depending on its amino acid profile.

Our analysis shows that both plant-based and animal-based supplements can be a good quality source of a diverse amino acid profile. However, plant-based protein sources were the highest quality protein with pea being the high quality of protein source. Among animal derived protein, egg-white was the highest quality followed by whey. Alternatively, several of the plant and animal-based proteins were lower on quality such as beef, rice, and hemp seed sources. Our discussion is limited to the evaluation of pure protein isolates and does not include the use of blends of protein sources. Protein blends may be able to adjust for deficiencies from specific sources and is outside the scope of this manuscript.

In the context of supporting muscles and muscular growth, leucine* has emerged as a key driver, likely through the activation of the mTOR pathway.¹⁶ Assessment of the absolute leucine* content revealed that the dairy-derived protein sources (whey and casein) were the most abundant. Additionally, plant-based pea and soy also provide substantial amount of leucine*. A previous clinical study evaluating pea and whey-based protein intake showed that both sources are similar in their ability to support muscle growth, increase in muscle strength, and force production,^17,18 suggesting that after a certain threshold of leucine* there may be no benefit for the presence of additional leucine* for muscle support.

On the other hand, leucine* is known to be an activator of the mTOR pathway.¹⁹ Overactivation of mTOR has been associated with increased aging,^20,21 increased insulin levels with the presence of insulin resistance,²² and exacerbation of several inflammatory conditions such as acne, psoriasis, and hidradenitis suppurativa.^22,23 Furthermore, whey protein has been implicated in flares of acne.^24,25 When comparing whey protein to plant based protein, whey has greater activation of the mTOR pathway,²⁶ suggesting that the leucine* content in whey may not only be beyond the threshold needed for support of muscle health but may also lead to more mTOR activation related side effects. However, more comparative studies between whey protein and other protein such as egg-white, pea, and soy are needed.

Protein and collagen supplements are frequently used in support of skin health. In particular, it appears that the ingestion of branched amino acids (isoleucine*, leucine*, and valine*) along with arginine, glutamine, and proline) may support collagen synthesis.²⁷ Our analysis shows that pea, soy, and egg-white sources may be the most supportive as they are comparatively higher sources of arginine, glutamic acid, proline, and branched chain amino acids compared to whey. A study that comparatively evaluated the effect of soy versus casein protein supplementation for improvement of photoaging and reduction of wrinkles in post-menopausal women showed that soy was superior to casein while casein did not have a significant effect on photoaging or wrinkles.⁹ While more studies are needed, plant-based sources of protein appear to be superior in supporting skin health in comparison to milk derived sources.

Amino acids like arginine, which play a pivotal role in nitric oxide production, hair health, collagen production, and vascular health,^27–29 were found to be more abundant in several plant-based proteins, such as pumpkin seed (7,987 mg/100 g), pea (7,744 mg/100 g), and hemp seed (6,336 mg/100 g), when compared to whey (1,974 mg/100 g). This trend, as seen in Figure 2, suggests that plant-based proteins may provide a significant source of arginine in addition to the other amino acids. Both of the milk-based sources of protein (whey and casein) had low levels of arginine in comparison to the other protein sources.

Overall, when analyzing the amino acid z-scores across the nine protein isolates, pea, egg-white, whey, and soy protein isolates are shown to rank highest. The z-scores show that, when compared to other isolates, pea protein has higher amino acid contents of phenylalanine*, histidine*, and aspartic acid. These amino acids and their functions may position pea protein to be a strong supporter of gut, skin, and brain health.³⁰ For example, histidine* supplementation has been shown to improve atopic dermatitis³¹ and pea protein may be rich in histidine*. Egg-white protein, when compared to other isolates, showed notably greater quantities of serine and methionine*. These amino acids suggest a role for egg-white protein in skin and brain health, as their functions encompass skin hydration, barrier function, detoxification, and neurotransmitter function.³⁰ Whey was notable for its higher quantities of threonine*, lysine*, leucine*, and isoleucine* when compared to those amino acids in other isolates.

Surprisingly, we found that beef derived protein was one of the lowest quality isolates, considering how beef is touted as a good source of protein. However, most consumer-focused advice in regard to beef has focused on quantity, our study highlights the importance of quality as well.

Asparagine (Asn) and glutamine (Gln) were excluded from the analyses due to their absence in the amino acid profiles provided by the manufacturers. This may be because these amino acids are considered non-essential and can be synthesized by the body.³² Some manufacturers listed these amino acids interchangeably with aspartic acid (Asp) and glutamic acid (Glu), potentially because both amino acids can be interconverted in vivo via asparaginases and glutaminases, respectively.³² While the exact reason for their exclusion remains unclear, this may reflect the manufacturers’ focus on more stable amino acids in their profiles, and further discussion of this limitation is warranted.

The Clean Label Project tested multiple protein supplements may contain heavy metal contamination which may be higher among plant-based proteins, especially among those that have a chocolate flavoring. Unfortunately, this report awaits peer-review and is not published in a peer-reviewed journal at the time of the writing of this manuscript. A peer-reviewed and published manuscript that evaluated the heavy metal contents in protein powders noted that all of the supplements (plant-based or otherwise) were not associated with an increased non-carcinogenic risk.³³ The authors of this manuscript further note that heavy metal measurements should be performed in the context of the background exposure rates.³³ Therefore, the current evidence supports no harm or are inconclusive at best for the potential heavy metal related health hazards from protein supplementation.

The findings from this study have significant implications for protein selection, especially for individuals with specific dietary preferences or health goals. For those focused on muscle growth, post-exercise recovery, or immune support, pea or whey protein offer similar benefits for muscle growth, although pea is likely to have a lower risk of acne exacerbation but that would require further study.

For individuals following plant-based diets or seeking alternatives due to food sensitivities or ethical considerations, blending multiple plant-based proteins—such as soy, pea, pumpkin seed, and hemp seed—may provide a more complete amino acid profile, addressing potential deficiencies in key amino acids like methionine*, cystine, and lysine*. Further research is needed to explore the synergistic effects of combining different plant-based protein isolates to optimize amino acid profiles for specific health and fitness goals.

Conclusion

The systematic comparison of amino acid profiles across various protein isolates emphasizes the importance of understanding the specific amino acid composition of protein sources, particularly in the context of health, fitness, and muscle recovery. Metric based ranking of quality showed that pea and egg-white were the highest quality followed by whey and soy sources. By considering the amino acid profiles of different protein isolates, individuals can better tailor their protein intake to meet their specific nutritional and performance needs. Future research should focus on developing strategies for enhancing the amino acid quality of plant-based proteins and exploring the benefits of protein blends.

Conflicts of Interest

Raja K Sivamani serves as a scientific advisor for LearnHealth, Arbonne, and Codex Labs and has served as a consultant or speaker for Burt’s Bees, Novozymes, Novartis, Sanofi, Bristol Myers Squibb, Pfizer, Nutrafol, Galderma, Novartis, Abbvie, Leo, UCB, Sun, and Regeneron Pharmaceuticals. All other authors declare no conflicts of interest.

Funding

None

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