Milk substitute
Milk substitutes, also known as plant-based milk alternatives, are emulsions derived from sources such as legumes, nuts, seeds, grains, or pseudocereals that are processed to emulate the color, viscosity, and culinary applications of bovine milk.[1][2] These beverages emerged historically with soy milk documented in China by the 14th century as an intermediate in tofu production, while almond milk traces to the Middle East in the 13th century for its creamy consistency during fasting periods.[3][4] Common varieties today include soy, almond, oat, rice, and coconut, each offering distinct flavor profiles and production methods involving grinding, soaking, and straining plant materials with water, often followed by fortification.[5] Their popularity has surged due to lactose maldigestion affecting roughly 65-70% of the global adult population, alongside preferences for vegan diets or perceived environmental benefits over dairy production.[6][7] Nutritionally, plant-based alternatives typically provide lower protein content and bioavailability compared to cow's milk, with soy being the closest match at around 7-8 grams per cup versus 8 grams in dairy, while others like almond or rice offer 1 gram or less; many require added calcium, vitamin D, and B12 to approximate dairy's profile, though natural iodine and certain amino acids remain deficient.[8][9] Controversies arise from their variability—some contain high added sugars or emulsifiers—and unsuitability as complete replacements for infants or growing children, where unfortified versions risk nutritional shortfalls.[10][11] Environmentally, while aggregate greenhouse gas emissions may be lower than dairy's, specific types like almond milk demand substantial water resources, challenging claims of universal sustainability.[12][13]
History
Origins in Traditional Practices
Soy milk, one of the earliest documented plant-based milk substitutes, originated in China during the Han dynasty (circa 25–220 AD), with archaeological evidence from stone inscriptions suggesting its production as early as the first century AD; it was traditionally prepared by soaking and grinding soybeans, then boiling and straining the mixture to create a beverage used in cooking and for direct consumption, particularly valued for its digestibility compared to animal milk.[4][14] By the 14th century, written records from 1365 explicitly describe its use, and by the 17th–18th centuries, it had become a common street food in China, often heated gently to enhance palatability and nutritional absorption.[15][16] Rice milk traces its roots even further back, emerging in China around 1000 BC through simple traditional methods of boiling rice in water and straining the resulting liquid, primarily as a staple porridge-like drink rather than a direct dairy mimic, though it served as an accessible alternative in rice-dependent agrarian societies where animal milk was less prevalent.[4] In medieval Europe and the Islamic world, almond milk gained prominence as a dairy substitute during religious fasting periods, such as Christian Lent, when animal products were prohibited; prepared by blanching, grinding, and infusing almonds in water before straining, it appeared in culinary texts as early as the 13th century, offering a creamy texture for sauces, desserts, and beverages among nobility and monasteries.[17] This practice was driven by practical necessity rather than widespread lactose avoidance, with recipes emphasizing its stability in non-refrigerated environments.[18] Coconut milk, extracted traditionally by grating mature coconut flesh and pressing it with water, has been integral to Southeast Asian, Indian, and Pacific Island cuisines for millennia, functioning as a versatile base in curries, desserts, and fermented drinks where fresh dairy was scarce due to tropical climates unsuitable for large-scale cattle herding.[12] These early methods relied on manual labor and local botanicals, predating mechanized processing and reflecting adaptive responses to environmental availability and cultural dietary norms rather than ideological rejection of dairy.[19]Modern Development and Commercialization
The modern commercialization of milk substitutes began in the early 20th century with soy milk, marking the transition from traditional, small-scale production to industrial manufacturing. In 1910, Chinese chemist Li Yu-Ying established the first dedicated soy milk factory near Paris, France, and secured a patent for "vegetable milk and its derivatives," enabling scalable production for urban markets.[4][20] This innovation addressed growing demand for non-dairy options amid lactose intolerance and dietary preferences in Europe. Concurrently, in the United States, pediatrician John Ruhräh developed the first soy-based infant formulas using full-fat soy flour in 1909, laying groundwork for therapeutic applications of soy milk as a cow's milk alternative.[21] By the 1920s, soy milk production expanded significantly, with factories emerging in the United States and China, driven by entrepreneurs like Harry W. Miller, who established commercial operations in Ohio.[15] In 1917, the first dedicated commercial soy milk plant opened in the U.S., further industrializing the process through mechanical extraction and homogenization to mimic dairy milk's texture and shelf life.[22] Figures such as Henry Ford promoted soy milk's viability, experimenting with soy-based products on his estates and advocating for its nutritional equivalence to cow's milk, which spurred adoption during wartime shortages and health campaigns.[22] These developments emphasized fortification with vitamins and emulsifiers to enhance palatability and nutritional profile, distinguishing modern products from artisanal predecessors. Commercialization extended to other plant milks later in the century, though soy dominated until the 1990s. Almond milk, rooted in medieval recipes, saw limited industrial production until brands like Almond Breeze introduced refrigerated versions in the U.S. in the 1990s, capitalizing on improved blending technologies.[23] Oat milk's modern origins trace to 1990, when Swedish scientist Rickard Öste patented an enzyme-based extraction method at Lund University, leading to Oatly's launch in 1994 as a creamy, sustainable alternative.[24] These innovations relied on advances in food processing, such as high-pressure homogenization and stabilizers, to achieve dairy-like consistency, fueling market entry by major corporations like Dean Foods and Silk by the late 20th century.[25]Recent Market Expansion (2000s–Present)
The market for milk substitutes, particularly plant-based varieties, experienced significant expansion beginning in the early 2000s, driven by increasing consumer awareness of lactose intolerance, rising veganism, and perceptions of environmental benefits over dairy production. Soy milk, which dominated prior decades, saw its U.S. market share peak around 2005 at over 70% of non-dairy sales before diversifying into almond and other options; by 2010, almond milk had captured 60% of the U.S. plant-based milk category due to its milder flavor and lower calorie profile.[3][12] Overall, U.S. household penetration of plant-based milks rose from about 20% in 2010 to 33% by 2016, reflecting broader retail availability and marketing efforts by brands like Silk and Almond Breeze.[26] The 2010s marked accelerated global growth, with the plant-based milk sector transitioning from niche to mainstream, fueled by innovations in texture and fortification that improved palatability and nutritional comparability to cow's milk. Oat milk emerged as a key disruptor around 2015–2016, propelled by brands like Oatly, whose viral marketing and partnerships (e.g., with Starbucks in 2018) contributed to a surge in oat-based sales exceeding 10% annual growth in Europe and North America by 2019.[3][12] The global market value climbed from approximately $5–7 billion in the early 2010s to $18 billion by 2020, with U.S. sales volumes increasing 20% that year alone amid heightened health and sustainability concerns during the COVID-19 pandemic.[27][12] Plant-based options captured about 15% of U.S. retail milk sales by 2021, though growth has since moderated to a CAGR of 7–8% through 2023, reaching $19.4 billion globally.[28][12] Key drivers included empirical rises in lactose intolerance diagnoses—affecting 65–70% of the global adult population—and vegan adoption, which grew from 1% of U.S. adults in 2014 to 6% by 2019, alongside environmental critiques of dairy's methane emissions and water use.[12][3] However, expansion has faced scrutiny over unsubstantiated sustainability claims, as almond milk production consumes substantial California groundwater amid droughts, potentially offsetting some ecological advantages touted by industry reports.[3] By 2023, the sector accounted for 16% of total U.S. milk sales, with projections to $32 billion globally by 2030, supported by diversification into coconut, pea, and hemp variants and entry into foodservice channels like coffee shops.[29][28] Despite this, dairy beverage consumption decline has been gradual, with total U.S. per capita dairy product intake rising 25% since 2000 due to cheese and yogurt offsets.[30]Types
Plant-Based Milks
Plant-based milks are liquid emulsions produced from plants such as nuts, seeds, grains, legumes, or cereals, designed to mimic the sensory qualities of cow's milk. They are typically manufactured by soaking, grinding, and filtering the source material in water, followed by homogenization and often pasteurization or ultra-high temperature processing for stability. Common additives include emulsifiers, stabilizers, and fortifications with calcium, vitamin D, and B12 to approximate dairy nutrition.[31] Soy milk, the oldest widely commercialized plant-based milk, traces its origins to China, where it has been consumed for over 2,000 years as a staple derived from soybeans through traditional soaking, grinding, boiling, and straining processes. It gained traction in the West during the 20th century, particularly amid wartime dairy shortages, with the first U.S. production efforts in the early 1900s supported by figures like Henry Ford. Soy milk constitutes about 13% of the U.S. plant milk market as of 2018 data, valued for its complete protein profile from soybeans.[32][33] Almond milk dominates the global plant-based milk market, holding over 35% share as of recent analyses, driven by its mild flavor and low calorie appeal in Western markets. Production involves blending blanched almonds with water and straining, but it demands substantial irrigation; a single 200 ml serving requires approximately 74 liters of water, primarily due to California's almond orchards amid regional droughts. Despite lower overall greenhouse gas emissions compared to dairy, its high water footprint and reliance on pollinator-intensive farming raise sustainability concerns relative to other plant options.[34][35][36] Oat milk has surged in popularity since the mid-2010s, particularly for its creamy consistency ideal for foaming in beverages like coffee lattes, capturing significant retail interest without dominating overall preferences. Its rise stems from favorable taste profiles, lower environmental demands than almond milk—including reduced water use and carbon emissions—and compatibility with sustainable oat farming in temperate regions. By 2024, oat milk contributes to the broader plant milk category's 14% dollar share of total U.S. milk sales.[37][38][39] Other variants include rice milk, noted for its sweet taste but low protein content; coconut milk, derived from coconut flesh with higher saturated fats; and emerging options like pea, hemp, and cashew milks, each varying in yield, texture, and resource intensity. The global plant-based milk market reached USD 20.93 billion in 2024, projected to grow at a 7.62% CAGR to USD 43.63 billion by 2034, fueled by veganism, lactose intolerance affecting up to 68% of the world population, and perceived health benefits, though actual nutritional equivalence requires fortification.[34][40]Dairy-Derived Alternatives
Lactose-free milk is produced through the addition of lactase enzyme to conventional cow's milk, which breaks down lactose into glucose and galactose, enabling digestion by individuals with lactase deficiency affecting up to 65-70% of the global adult population.[41] This treatment preserves the milk's casein and whey proteins, fats, and micronutrients such as calcium (approximately 300 mg per 240 ml serving) and fortified vitamin D, while minimizing symptoms like bloating and diarrhea in lactose-intolerant consumers.[42] Production methods include enzymatic hydrolysis or chromatographic separation of lactose, with the resulting product maintaining a similar nutritional profile to untreated milk but with a naturally sweeter taste due to the converted sugars.[43] A2 milk originates from cows of breeds like Guernsey or Jersey that naturally produce milk containing only A2 beta-casein, omitting the A1 variant found in milk from most Holstein cows, which constitutes about 50-60% of global dairy herds.[44] The A1 protein is hypothesized to release beta-casomorphin-7 (BCM-7), a peptide potentially linked to gastrointestinal inflammation and discomfort in sensitive individuals, though human studies show mixed results, with some indicating reduced digestive issues and improved gut barrier function compared to A1-containing milk.[45] [44] A2 milk retains standard dairy macronutrients—around 8 grams of protein and 120 calories per cup—but lacks robust evidence for broad superiority over regular milk beyond anecdotal reports; it is not lactose-free unless additionally processed.[46] Ultra-filtered milk, exemplified by brands like Fairlife introduced in 2012, employs membrane filtration to concentrate proteins and remove water, lactose, and some minerals, yielding 13 grams of protein per 240 ml serving (versus 8 grams in regular milk) and 6-13 grams of sugar (50% less than standard).[47] This process results in a lactose-free or low-lactose product suitable for moderate intolerance, with a denser texture and longer shelf life (up to 100 days refrigerated for some varieties) due to reduced microbial substrates.[48] Nutritional enhancements include higher casein content for satiety, but the filtration may deplete natural electrolytes, often necessitating re-fortification; it remains a full dairy product without plant additives.[49] These alternatives collectively address cow's milk sensitivities—lactose maldigestion affects 15% of Northern Europeans versus 90% of East Asians—while delivering bioavailable animal-derived nutrients unavailable in plant-based options.[50]Other Animal Milks
Goat milk is frequently used as a substitute for cow's milk due to its improved digestibility for some individuals, attributed to smaller fat globules (1.0–1.5 μm versus 3–4 μm in cow's milk) that form softer curds in the stomach, facilitating easier gastric emptying and reducing symptoms like bloating in those with non-allergic cow's milk sensitivities.[51][52] Nutritionally, goat milk contains comparable protein levels (around 3.25%) to cow's milk (3.42%) but higher medium-chain fatty acids, oligosaccharides for gut health, and certain minerals like calcium and potassium, though it has lower folate and vitamin B12 unless fortified.[53] It remains unsuitable for true cow's milk protein allergies, as it shares similar casein proteins (e.g., A1 beta-casein in some breeds), but its production efficiency—goats require less feed and space than cows—supports its use in smaller-scale or developing-region dairy alternatives.[52][54] Donkey milk serves as a hypoallergenic alternative for infants and children with cow's milk protein allergy (CMPA), closely resembling human breast milk in composition with low casein content (about 40% of total protein versus 80% in cow's milk), higher lactose (6–7%), and whey proteins like lysozyme for antimicrobial properties.[55] Its lower fat (0.5–1.5%) and cholesterol levels, combined with reduced allergenicity, make it a viable formula base, as evidenced by clinical studies showing tolerance in 80–90% of CMPA cases unresponsive to hydrolyzed cow formulas.[55] Donkey milk also has less lactose than cow's milk (around 6.5% versus 4.8%), potentially benefiting mild lactose intolerance, though enzyme supplementation may still be needed; production is limited globally, with yields of 1–2 liters per day per animal, restricting it to niche markets in Europe and Asia.[56] Camel milk emerges as a substitute in arid regions and for those seeking antimicrobial benefits, containing higher vitamin C (three times that of cow's milk at 5–10 mg/100 ml) and iron (10 times higher), alongside insulin-like proteins that may aid diabetes management by improving glycemic control in preliminary trials.[57] Its low beta-lactoglobulin allergen reduces reactions compared to cow's milk, and higher potassium and calcium support bone health, but lower total protein (2.9–3.5%) and fat necessitate fortification for infant nutrition.[53] Sheep milk, while richer in solids (18–20% versus 12–13% in cow's milk) and medium-chain fats for energy density, is less common as a direct beverage substitute due to its intense flavor and higher viscosity, finding more use in cheeses like Roquefort; it offers superior calcium and phosphorus for skeletal health but shares allergy risks with bovine caseins.[58] Overall, these non-bovine milks constitute under 5% of global dairy production as of 2023, valued for targeted nutritional profiles but limited by yield, taste, and processing challenges.[59]Production and Processing
Sourcing and Extraction Methods
Plant-based milk substitutes are derived from agricultural crops such as nuts, seeds, grains, and legumes, which are harvested and processed into liquid extracts. For almond milk, almonds are primarily sourced from orchards in regions like California, where over 80% of global supply originates, and extraction involves soaking the nuts in water for several hours, followed by grinding into a slurry, blending with additional water, and straining to separate the pulp from the liquid.[60] Soy milk production sources soybeans from major producers like the United States and Brazil, with extraction typically entailing soaking the beans overnight, grinding them with water, boiling the mixture to deactivate enzymes and improve flavor, and filtering to remove okara (soy pulp).[60] Oat milk uses oats grown in temperate regions such as North America and Europe; the process includes milling the grains, hydrating with water, enzymatic treatment to break down starches into sugars, homogenization, and filtration to yield a creamy base.[61] These methods often employ wet grinding techniques to minimize energy use and preserve nutritional components, though industrial scales incorporate high-shear mixers and centrifuges for efficiency.[62] Dairy-derived alternatives, such as lactose-free milk, begin with cow's milk sourced from dairy farms through standard milking operations. The extraction of lactose-free variants involves adding the enzyme lactase (β-galactosidase) to regular pasteurized cow's milk, which hydrolyzes lactose into glucose and galactose, reducing lactose content to below 0.1% while imparting a naturally sweeter taste without altering the protein or fat profile significantly.[63] [64] Some processes pre-filter milk to remove a portion of lactose mechanically before enzymatic treatment, followed by ultra-high temperature (UHT) sterilization to extend shelf life.[65] This method retains the original sourcing from bovine herds but modifies the milk post-harvest to accommodate lactose intolerance.[43] Other animal milks, including those from goats, sheep, and camels, are sourced from specialized herds in pastoral or farm settings, with extraction primarily via hand milking due to anatomical differences from cows. Goat milk is obtained from dairy goats raised on farms in regions like the United States and Europe, where over half of operations use hand milking twice daily to stimulate let-down and prevent mastitis, though machine milking is employed on larger scales.[66] Sheep milk sourcing occurs in Mediterranean and pastoral areas, involving hand milking by operators who compete with lambs for yield, typically yielding lower volumes per animal compared to goats.[67] Camel milk is extracted from camels in arid regions of Africa and Asia through traditional hand methods, often requiring the presence of a calf to induce let-down and milking both teats simultaneously multiple times daily for optimal yield.[68] [69] These practices emphasize hygiene and frequency to maintain quality, with transitions to mechanized systems limited by animal behavior and low production volumes.[70]Fortification and Additives
Plant-based milk substitutes are frequently fortified with micronutrients to compensate for deficiencies inherent in their source ingredients, such as low natural levels of calcium, vitamin D, and vitamin B12 compared to cow's milk. Common fortifications include calcium in forms like calcium carbonate or tricalcium phosphate, vitamin D, vitamin A, riboflavin (B2), and vitamin B12, aiming to approximate the nutritional profile of dairy milk and prevent inferiority in replacement foods as per FDA policy guidelines.[71][9][12] For instance, many commercial oat and almond milks add these nutrients to reach levels matching 20-30% of daily values per serving, though soy milk often requires less extensive fortification due to its naturally higher protein and mineral content.[72][73] In the United States, fortification remains voluntary without mandatory compositional standards for most plant-based milks, unlike standards of identity for dairy, though the FDA includes fortified soy beverages in dietary guidelines' dairy group when they meet specific nutrient thresholds for calcium, vitamins A, and D.[74] In the European Union, Regulation (EC) No 1925/2006 permits the addition of approved vitamins and minerals under conditions ensuring safety and efficacy, with no uniform minimums for plant milks but emphasis on avoiding misleading claims.[75] Variability persists across brands and types; for example, peer-reviewed analyses show that while fortified plant milks can deliver comparable calcium and vitamin D, bioavailability may differ due to plant matrices or added forms, potentially affecting absorption rates.[12] Additives in milk substitutes primarily serve to enhance stability, texture, and palatability, addressing challenges like phase separation in emulsions of water, plant solids, and oils. Stabilizers and emulsifiers such as xanthan gum, gellan gum, guar gum, locust bean gum, and lecithin are commonly incorporated at 0.1-1% by weight to prevent sedimentation and create a creamy mouthfeel, as plant bases lack dairy's natural casein proteins.[76] Other additives include preservatives like potassium sorbate for shelf life extension and natural flavors or sweeteners (e.g., cane sugar or stevia) to mask beany or nutty off-notes, though unsweetened variants minimize these.[77] Carrageenan, a seaweed-derived thickener, has been used but faces scrutiny in some formulations due to potential gastrointestinal irritation in high doses, leading brands to phase it out in favor of gums.[78] Regulatory oversight for additives aligns with general food safety standards, requiring FDA approval as generally recognized as safe (GRAS) substances in the U.S. and similar EU evaluations, with labels disclosing all ingredients to enable consumer choice.[1] Homemade or minimally processed substitutes avoid these additives entirely, relying on blending and straining, but commercial products prioritize them for uniformity and extended distribution. Empirical data from market surveys indicate that additive profiles contribute to higher processing levels in plant milks versus unprocessed dairy, influencing overall product quality and consumer perceptions of "naturalness."[79]Quality Control and Shelf Life
Quality control in the production of milk substitutes emphasizes microbial safety, contaminant detection, and nutritional consistency, as these products lack the standardized regulatory framework applied to cow's milk under FDA Grade "A" standards.[74] Manufacturers adhere to current good manufacturing practices (cGMP) and hazard analysis and critical control points (HACCP) protocols to mitigate risks from raw plant materials, which can harbor spore-forming bacteria or pathogens if not properly sourced and processed.[80] Rigorous testing includes microbial enumeration for total bacterial load, detection of pathogens like Listeria monocytogenes and Salmonella spp., and chemical analysis for additives, heavy metals, and mycotoxins, with studies confirming that untreated plant-based ingredients often exceed safe microbial thresholds.[81] [82] For dairy-derived alternatives like lactose-free milk, quality control mirrors traditional dairy processes, incorporating antibiotic residue testing and somatic cell counts, while other animal milks such as goat milk undergo similar pasteurization validation to prevent Brucella or Coxiella burnetii contamination.[83] Pasteurization—typically high-temperature short-time (HTST) or ultra-high temperature (UHT)—serves as a core control measure across plant-based and alternative milks, reducing vegetative pathogens but not eliminating heat-resistant spores, necessitating additional filtration and aseptic packaging.[84] Inline sensors monitor parameters like pH, viscosity, and fortificant levels (e.g., calcium, vitamin D) during extraction and homogenization to ensure batch uniformity, with deviations triggering rejection.[85] Allergen cross-contamination risks, particularly in facilities processing nuts or soy, are addressed through dedicated lines or validated cleaning protocols, as plant-based milks can inadvertently include traces from shared equipment.[86] Shelf life of milk substitutes varies by base ingredient, processing method, and packaging, generally shorter for refrigerated varieties due to susceptibility to microbial growth in carbohydrate-rich bases like oat milk. UHT-processed plant-based milks achieve unopened shelf stability of 6-12 months at ambient temperatures via aseptic filling, outlasting pasteurized versions that require constant refrigeration and last 2-3 weeks unopened.[80] Once opened, almond and soy milks typically endure 7-14 days under refrigeration before spoilage indicators like off-odors or curdling emerge, attributed to lower protein content limiting bacterial adhesion compared to oat milk's 5-7 days. Dairy-derived lactose-free milks align closely with cow's milk, offering 2-3 weeks refrigerated post-opening due to enzymatic hydrolysis not altering stability. Factors extending shelf life include minimal preservatives (e.g., gellan gum for emulsion) and oxygen-barrier packaging, though studies highlight faster Bacillus spore germination in plant milks under abuse conditions like temperature fluctuations.[87]| Milk Substitute Type | Unopened Shelf Life (UHT/Shelf-Stable) | Opened Shelf Life (Refrigerated) | Key Stability Factors |
|---|---|---|---|
| Almond Milk | 6-9 months | 7-10 days | Low microbial nutrient profile; UHT effective against spoilers[88] |
| Soy Milk | 6-12 months | 7-14 days | Higher protein aids emulsion but risks fermentation; pasteurization critical[84] |
| Oat Milk | 6-12 months | 5-7 days | Enzyme activity accelerates spoilage; antioxidants mitigate oxidation[89] |
| Lactose-Free Cow's Milk | N/A (refrigerated) | 14-21 days | Similar to dairy; hydrolysis does not reduce stability[90] |
| Goat Milk | 6-9 months (UHT) | 10-14 days | Smaller fat globules enhance stability; prone to lipolysis if unpasteurized[91] |
Nutritional Composition
Macronutrients and Micronutrients
Milk substitutes, particularly plant-based varieties, display substantial variability in macronutrient profiles attributable to their source ingredients and processing methods. Soy milk typically contains 3.1–3.8 grams of protein per 100 milliliters, rendering it the closest plant-based analog to cow's milk in this regard, whereas almond, oat, and rice milks provide under 1 gram, often 0.2–1.0 grams.[8][93] Fat content ranges from 1.0–3.6 grams per 100 milliliters across types, predominantly unsaturated except in coconut-based options which feature elevated saturated fats at approximately 1.1–7.1 grams.[8][93] Carbohydrates are minimal in nut milks (0.3–1.3 grams) but higher in grain-based substitutes like oat (3.7 grams) and rice (4.8 grams), derived from starches rather than lactose.[8]| Type | Protein (g/100 ml) | Fat (g/100 ml) | Carbohydrates (g/100 ml) |
|---|---|---|---|
| Soy | 3.1–3.8 | 2.0–4.3 | 1.5–4.9 |
| Almond | 0.5–1.0 | 1.0–3.6 | 0.3–1.3 |
| Oat | 0.5–1.0 | 1.0–2.0 | 3.7–7.0 |
| Rice | 0.2–0.5 | 1.0–1.3 | 4.8–8.8 |
Comparison to Cow's Milk
Cow's milk contains approximately 3.2 to 3.8 grams of high-quality protein per 100 milliliters, consisting of complete proteins with all essential amino acids in balanced proportions, yielding a digestible indispensable amino acid score (DIAAS) superior to that of most plant-based substitutes.[8] In contrast, soy milk provides comparable protein quantity at around 3 grams per 100 milliliters but with slightly lower DIAAS due to differences in amino acid profiles, while almond, oat, and rice milks offer markedly less protein—typically 0.4 to 1.5 grams per 100 milliliters—and incomplete profiles limiting their biological value.[94] [73]| Nutrient (per 240 mL serving, unsweetened varieties) | Cow's Milk (whole) | Soy Milk | Almond Milk | Oat Milk | Rice Milk |
|---|---|---|---|---|---|
| Calories | 146 | 80 | 30 | 120 | 120 |
| Protein (g) | 8 | 7 | 1 | 3 | 1 |
| Total Fat (g) | 8 | 4 | 2.5 | 5 | 2.5 |
| Carbohydrates (g) | 12 | 4 | 1 | 16 | 23 |
| Calcium (mg, natural or fortified) | 276 (natural) | 300 (fortified) | 450 (fortified) | 300 (fortified) | 300 (fortified) |
| Vitamin D (IU, typically fortified) | 100 | 100 | 100 | 100 | 100 |
| Vitamin B12 (mcg, natural or fortified) | 1.1 (natural) | 1 (fortified) | 1 (fortified) | 1 (fortified) | 1 (fortified) |
Variability Across Types
Plant-based milk substitutes exhibit substantial variability in macronutrient profiles, primarily due to differences in source materials and processing. Soy milk typically provides 7-9 grams of protein per 240-milliliter serving, approaching levels in cow's milk (approximately 8 grams), owing to its complete amino acid profile derived from soybeans.[95][31] In contrast, almond milk contains less than 1 gram of protein, emphasizing low caloric density (30-60 calories per serving) but minimal satiating potential from protein. Oat milk offers around 3 grams of protein with higher carbohydrates (up to 16 grams, including beta-glucans for fiber), yielding 120-130 calories, while rice milk is carbohydrate-dominant (23 grams) with negligible protein (1 gram) and similar caloric content. Coconut milk stands out for elevated saturated fats (up to 5 grams) and low carbohydrates (1-6 grams), resulting in 45-80 calories per serving. These differences stem from inherent botanical compositions, with legumes like soy yielding higher proteins than nuts or grains.[101][94][102]| Type | Protein (g/240mL) | Carbs (g/240mL) | Fat (g/240mL) | Calories (kcal/240mL) |
|---|---|---|---|---|
| Soy | 7-9 | 4 | 4 | 80-100 |
| Almond | <1 | 1 | 2.5 | 30-60 |
| Oat | 2-3 | 16 | 5 | 120-130 |
| Rice | 1 | 23 | 2 | 120 |
| Coconut | <1 | 1-6 | 4-5 | 45-80 |
Health Effects
Addressing Lactose Intolerance
Lactose intolerance, resulting from insufficient lactase enzyme activity, impairs the digestion of lactose, the primary sugar in mammalian milk, leading to symptoms such as abdominal bloating, cramps, flatulence, and diarrhea in affected individuals.[7] Globally, primary lactose intolerance affects roughly 65% of adults, with prevalence varying by ethnicity and region: rates exceed 75% among Asian and Native American populations, 50-80% in African descent groups, and remain lower at 5-15% in Northern European populations due to historical genetic adaptations for lactase persistence.[105] In the United States, an estimated 30-50 million adults experience symptoms upon dairy consumption, though many remain undiagnosed or self-manage through partial avoidance.[106] Plant-based milk substitutes, including those from soy, almonds, oats, rice, and coconuts, inherently lack lactose as they derive from non-dairy sources, directly mitigating the maldigestion that triggers symptoms.[107] By replacing cow's milk in diets, these alternatives enable lactose-intolerant individuals to consume milk-like beverages without gastrointestinal distress, as confirmed by clinical observations where symptom resolution correlates with lactose elimination rather than broader dietary changes.[7] For instance, soy milk, one of the earliest commercial plant-based options developed in the mid-20th century, provides a nutritionally comparable profile without lactose, supporting its use in intolerance management since the 1950s in regions with high prevalence like East Asia.[78] Empirical data from dietary intervention reviews show that incorporating lactose-free plant milks sustains symptom-free consumption in most cases, with breath hydrogen tests—the gold standard for confirming malabsorption—demonstrating reduced fermentation markers post-switch.[106] This approach avoids the need for pharmaceutical lactase supplements, which hydrolyze only a portion of ingested lactose and may not fully prevent symptoms at higher doses.[7] Adoption rates have risen accordingly; U.S. surveys from 2014-2020 indicate that over 40% of plant milk consumers cite lactose avoidance as a primary motivator, correlating with decreased reported digestive issues among users.[107] While effectiveness hinges on complete lactose exclusion, fortified varieties can approximate dairy's calcium and vitamin D content, though unfortified options require complementary nutrient sources to prevent deficiencies observed in strict dairy avoiders.[108]Broader Nutritional Impacts
Plant-based milk substitutes generally provide lower quantities of high-quality protein compared to cow's milk, with average protein content ranging from 0.5–3.5 grams per 240 ml serving versus 8 grams in cow's milk, and plant-derived proteins exhibiting inferior digestibility-corrected amino acid scores (DIAAS) such as 62 for pea protein and 47 for rice protein.[109][110] This disparity arises from the incomplete amino acid profiles in most plant sources, potentially compromising muscle maintenance and satiety when substitutes fully replace dairy in the diet.[111] Micronutrient profiles in unfortified plant-based milks are typically deficient in bioavailable calcium, iodine, phosphorus, potassium, zinc, and vitamin B12 relative to cow's milk, which naturally supplies these nutrients through animal biosynthesis.[94] Fortification addresses some gaps—such as added calcium carbonate or vitamin D—but absorption rates may be reduced due to interference from phytates, oxalates, and fibers inherent in plant matrices, leading to variable efficacy in meeting daily requirements.[110][112] For instance, almond and rice milks often fall short in these elements even when fortified, heightening risks of suboptimal intake in populations relying heavily on them.[94] In pediatric populations, habitual consumption of plant-based milks as a dairy replacement has been linked to lower gains in height, body mass index, and micronutrient levels, including vitamin D and iron, based on systematic reviews of observational data.[113] This may stem from diluted nutrient density and incomplete fortification adherence, underscoring the need for supplemental sources to support growth.[113] Adults substituting plant milks may face similar challenges, particularly for bone mineralization, where dairy's synergistic effects of protein, calcium, and bioactive peptides correlate with reduced osteoporosis risk in meta-analyses of cross-sectional studies (odds ratio 0.63).[114] Plant alternatives, lacking these synergies unless meticulously fortified and consumed alongside diverse diets, show no equivalent protective association.[114][115] Cardiometabolic outcomes present a mixed picture: soy milk substitution for cow's milk demonstrates modest improvements in lipid peroxidation and intermediate markers like LDL cholesterol in randomized trials, attributable to isoflavones and unsaturated fats (meta-analysis of effect sizes favoring soy).[116][117] However, broader plant milks like oat or almond offer fewer such benefits and may elevate glycemic load due to higher carbohydrate content (e.g., 16–17 grams per serving in oat milk versus 12 grams in cow's milk), potentially exacerbating insulin dynamics in susceptible individuals.[110][118] Long-term reliance on these substitutes without compensatory nutrition risks cumulative deficiencies, as evidenced by modeling scenarios indicating reduced overall nutrient adequacy when replacing cow's milk with typical plant profiles.[119] Thus, while versatile for dietary inclusion, milk substitutes demand vigilant fortification and dietary diversification to mitigate broader nutritional shortfalls.Risks and Allergies
Plant-based milk substitutes, while generally posing lower overall allergenicity compared to cow's milk, can trigger allergic reactions in susceptible individuals due to proteins inherent in their base ingredients. Soy milk, derived from soybeans, carries a risk of soy allergy, which affects approximately 0.4% of children and can manifest as hives, gastrointestinal distress, or anaphylaxis. Almond and other tree nut-based milks pose risks for those with tree nut allergies, estimated to affect 1% of the population, potentially leading to severe reactions including respiratory distress. Oat milk may exacerbate issues in individuals with gluten sensitivity or avenin intolerance, though cross-contamination remains a concern in processing. Rice milk, often recommended for its hypoallergenic profile, is generally safer but not entirely risk-free for those with rice allergies, which are rare but documented. Up to 50% of infants with cow's milk protein allergy exhibit cross-reactivity with soy protein, necessitating careful selection of alternatives under medical guidance. Additives commonly used in commercial plant milks to enhance texture and stability introduce additional health risks. Carrageenan, a seaweed-derived emulsifier present in many formulations, has been linked in animal studies to intestinal inflammation and promotion of colitis-like symptoms, though human evidence is mixed and it remains FDA-approved for food use at low levels. Gums such as guar gum, xanthan gum, and locust bean gum, employed as thickeners, frequently cause gastrointestinal side effects including bloating, gas, and diarrhea, particularly in those with irritable bowel syndrome or sensitive digestion. These effects stem from their indigestible fiber nature, which ferments in the gut, potentially disrupting microbiota balance. Beyond allergies and additives, unfortified or poorly formulated substitutes risk nutritional shortfalls when used as direct replacements for cow's milk, potentially leading to iodine, vitamin B12, or calcium deficiencies in vulnerable populations like children or the elderly. High-oxalate content in almond and cashew milks elevates kidney stone risk factors for predisposed individuals, contrasting with lower-oxalate options like oat or soy. Microbial contamination risks are heightened in these products due to their neutral pH and nutrient-rich profiles, underscoring the need for rigorous quality controls to prevent outbreaks of pathogens like Listeria.Specialized Uses
Infant and Toddler Feeding
Exclusive breastfeeding for the first six months of life, followed by continued breastfeeding with complementary foods up to two years or beyond, is recommended by major health authorities including the American Academy of Pediatrics (AAP) and World Health Organization (WHO).[120] For infants unable to breastfeed, commercial infant formulas designed to mimic human milk composition are the appropriate substitute, as plant-based milk alternatives lack the necessary balance of macronutrients, vitamins, and minerals required for infant growth and development.[10] Plant-based beverages, such as almond, oat, or rice milk, are not suitable for infants under 12 months due to insufficient protein, calories, iron, and fat content, which can lead to malnutrition, failure to thrive, anemia, and electrolyte imbalances.[121][122] Use of non-dairy milks in infants has been associated with clinical issues including hypoalbuminemia, hypocalcemia, and impaired height and weight gain, as documented in case series where one-third of affected children presented with malnutrition.[121] The Centers for Disease Control and Prevention (CDC) advises against introducing any cow's milk or plant-based alternatives before 12 months, citing risks such as intestinal bleeding from excess proteins and minerals overwhelming immature kidneys.[10] Even fortified versions fail to replicate the bioavailability and completeness of infant formula, potentially exacerbating deficiencies if relied upon as a primary nutrition source.[123] For toddlers aged 12 to 24 months, pasteurized whole cow's milk or fortified unsweetened soy milk is recommended to support needs for calcium, vitamin D, protein, and potassium, providing approximately 400-500 mL daily as part of a balanced diet.[10][9] Other plant-based options like almond or oat milk are generally inadequate as primary beverages due to lower protein (often <1 g per 100 mL versus 3-4 g in cow's or soy milk) and caloric density (e.g., almond milk at 13-25 kcal per 100 mL), risking deficits in bone development and overall growth if not supplemented.[124][125] Soy milk, when fortified, approximates cow's milk nutritionally but requires monitoring for allergies affecting up to 0.4% of infants, manifesting as rashes, gastrointestinal distress, or respiratory symptoms.[126][127] In cases of cow's milk allergy or intolerance (prevalence ~2-3% in early childhood), hypoallergenic formulas or soy-based alternatives may be used under pediatric guidance, but non-soy plant milks remain unsuitable without rigorous fortification and dietary oversight to prevent nutritional shortfalls.[128][129] Variability in fortification levels across brands underscores the need for label verification, as unfortified or inconsistently supplemented products can contribute to suboptimal intake of essential nutrients like vitamin B12 and iodine in young children relying on them.[124] AAP consensus emphasizes that plant-based milks should not replace dairy or soy equivalents routinely, particularly for children under five, to avoid misleading nutritional claims and ensure evidence-based feeding practices.[130]Culinary and Functional Applications
Plant-based milk substitutes are employed in various culinary contexts, including beverages, sauces, and desserts, often as direct replacements for dairy milk to accommodate dietary restrictions or preferences. Soy milk, for instance, serves effectively in cooking and baking due to its high protein content (approximately 7 g per 240 ml), which supports emulsification and structural integrity similar to dairy milk.[78] Coconut milk is commonly used in savory dishes like curries for its rich fat content and flavor stability under heat.[131] In baking applications, soy milk performs comparably to dairy milk by contributing to browning and texture through its protein and mild flavor, making it suitable for items like cakes and breads.[132] Oat milk, with its creamy consistency from β-glucan, works well in sweeter baked goods but can form a gel-like texture when heated excessively due to starch gelatinization.[78] Almond milk, lower in protein, is less ideal for baking where structure is key, performing better in uncooked preparations like smoothies.[133] Functionally, these substitutes are integrated into food industry products such as plant-based yogurts, cheeses, and ice creams, where processing enhances stability and texture mimicry.[134] For barista applications, oat and soy variants exhibit moderate foaming capacity for lattes, though inferior to dairy milk's protein-driven stability, often requiring formulation adjustments like added emulsifiers.[133] Soy milk also functions as an emulsifier in products like mayonnaise, replacing up to 50% of eggs.[78]Environmental Impacts
Resource Consumption and Emissions
Plant-based milk alternatives generally exhibit lower greenhouse gas (GHG) emissions than cow's milk across lifecycle assessments, though resource consumption varies significantly by type, with some alternatives incurring higher water or land demands in specific contexts. Cow's milk production emits approximately 3 kg CO₂-equivalents per liter, driven largely by methane from enteric fermentation and manure management, accounting for about 3% of global anthropogenic GHG emissions from the dairy sector. In comparison, soy milk averages 0.4-1 kg CO₂eq/L, oat milk around 0.9 kg, almond milk 0.7 kg, and rice milk up to 2.5 kg, benefiting from the absence of ruminant digestion but offset by processing energy for extraction and formulation.[135][136][12] Water footprints highlight disparities, particularly for nut-based alternatives; almond milk requires 371-3,715 liters of water per liter produced—substantially exceeding dairy's 628 L/L—due to intensive irrigation in arid regions like California's Central Valley, where almond orchards consume 10% of the state's agricultural water amid chronic shortages. Soy milk uses about 297 L/L, oat milk even less at under 50 L/L in efficient systems, and rice milk around 260 L/L, though scarcity-weighted assessments amplify almond's impact by factors of 10 or more in drought-prone areas. Land use follows a similar pattern of reduction for most plant options: dairy demands 2.4 m² per liter for feed and grazing, versus 0.5 m² for almond, 0.7 m² for soy, 0.4 m² for oat, and 1.1 m² for rice, though oat's reliance on monoculture grains can elevate eutrophication from fertilizers.[135][12][137] Energy consumption in plant milk production centers on industrial processing—milling, enzymatic treatment, and homogenization—which can add 0.5-1 MJ/L, comparable to dairy's pasteurization and cooling but amplified by higher volumes for low-yield crops like almonds (requiring 1-2 kg nuts per liter). Critiques of environmental claims note methodological inconsistencies in studies, such as varying system boundaries that undercount transport or packaging for plant milks, or overlook indirect effects like soy-linked deforestation in South America, potentially inflating perceived benefits; nonetheless, aggregate data from meta-analyses confirm plant alternatives' net reductions in GHG (up to 80% for soy) and land (50-90%), albeit with water trade-offs necessitating regional sourcing considerations.[136][135][138]| Milk Type | GHG Emissions (kg CO₂eq/L) | Freshwater Use (L/L) | Land Use (m²/year/L) |
|---|---|---|---|
| Cow's | 3.15 | 628 | 2.41 |
| Almond | 0.74 | 371 | 0.51 |
| Soy | 1.00 | 297 | 0.7 |
| Oat | 0.90 | <50 | 0.4 |
| Rice | 2.50 | 260 | 1.1 |
Lifecycle Assessments and Critiques
Lifecycle assessments (LCAs) evaluate the environmental impacts of milk substitutes across their full production chain, from raw material cultivation to processing, packaging, and distribution. These studies typically measure metrics such as greenhouse gas (GHG) emissions, water use, land occupation, and eutrophication potential, often using a functional unit of one liter of product. A 2024 review found that plant-based milks (PBMs) generally exhibit lower GHG emissions than animal-based milks, with coconut milk averaging 0.257 kg CO₂-equivalent per kg, compared to 1.29 kg CO₂-equivalent per kg for cow milk. However, PBMs like almond milk can require substantially higher water footprints, exceeding those of dairy in water-scarce regions due to irrigation-intensive nut production.[136][136] Comparisons vary by PBM type and dairy production system. Soy and oat milks often show 50-80% lower GHG emissions than dairy milk on a volumetric basis, with oat milk emitting approximately 0.2-0.4 kg CO₂-equivalent per liter versus 1.0-2.5 kg for cow milk. Almond milk, while low in GHG (around 0.7 kg CO₂-equivalent per liter), demands up to 1,000-2,000 liters of water per liter produced, far surpassing dairy's 250-630 liters per liter, primarily from California almond orchards. Rice milk tends to have higher methane emissions from paddy fields, sometimes rivaling dairy levels. Dairy impacts are dominated by enteric fermentation and feed production, while PBM hotspots include crop inputs, processing energy, and transport.[139][140][137] Critiques of these LCAs highlight methodological limitations that can skew results toward PBMs. Volumetric functional units overlook nutritional disparities, as PBMs deliver fewer calories, proteins, and micronutrients per liter than dairy, potentially understating dairy's efficiency when adjusted for nutrient delivery; a 2024 study using nutrient-specific indices found fortified soy drinks lowest in impacts per nutritional unit, but unfortified PBMs like oat or coconut often exceeded dairy. System boundaries frequently exclude indirect effects, such as deforestation from soy expansion or pesticide use in monoculture crops, and allocation methods for co-products (e.g., meat from dairy herds) vary, inflating dairy footprints in some models. Data variability arises from regional differences—e.g., European pasture-based dairy may sequester soil carbon not fully credited in standard LCAs—while PBM studies sometimes rely on optimistic assumptions about sustainable sourcing.[141][141][136] Regenerative dairy practices, emphasizing rotational grazing and soil health, demonstrate potential for 20-50% GHG reductions beyond conventional LCAs, though few assessments incorporate carbon sequestration from improved pastures. Industry-funded studies, such as those by oat milk producers, may underreport processing emissions, while academic LCAs often draw from averaged global data that undervalue localized dairy efficiencies. Overall, while PBMs reduce certain pressures like land use in aggregate, blanket claims of superiority ignore context-specific trade-offs and the need for consistent, nutrition-adjusted methodologies to avoid misleading environmental narratives.[142][143][141]Economic and Regulatory Landscape
Market Growth and Trends
The global market for dairy alternatives, including plant-based milk substitutes such as almond, soy, oat, and pea varieties, was valued at approximately USD 32.77 billion in 2024.[144] This segment has expanded significantly since the early 2010s, driven by rising consumer demand for lactose-free options amid increasing awareness of lactose intolerance affecting up to 65% of the global population.[144] Projections indicate continued growth, with the market expected to reach USD 66.91 billion by 2030 at a compound annual growth rate (CAGR) of 12.7% from 2025 onward, fueled by product innovation and broader adoption in foodservice and retail.[144] Alternative estimates project a slightly higher trajectory, valuing the market at USD 36.76 billion in 2025 and expanding to USD 90.78 billion by 2032.[40] In the United States, a key market, dairy alternative beverages generated USD 7.27 billion in 2024, with forecasts for a 12.0% CAGR through 2030, reflecting strong per capita consumption shifts away from traditional dairy.[145] However, recent retail data reveal softening trends, with U.S. plant-based milk dollar sales declining 5% to USD 2.8 billion in 2024, attributed to higher prices relative to dairy milk and consumer reevaluation of value amid inflation.[39] Globally, oat milk has emerged as the fastest-growing subcategory, capturing market share due to its creamy texture and neutral flavor suitable for coffee and cereals, while almond milk maintains dominance but faces scrutiny over water-intensive production.[146] Soy milk, long-established, holds steady in Asia-Pacific regions but has lost ground in Western markets to newer options. Key drivers include health-conscious consumers seeking lower-calorie or allergen-free alternatives, alongside vegan and flexitarian diets, though growth is tempered by nutritional debates and supply chain vulnerabilities like crop yield fluctuations.[34] Emerging trends point to fortified products addressing nutrient deficiencies (e.g., added calcium and vitamin D) and sustainable sourcing claims, yet premium pricing has led to some market contraction in volume sales as consumers opt for cost-effective dairy during economic pressures.[147] Regional variations persist, with Europe and North America leading adoption, while Asia benefits from traditional soy consumption but slower uptake of Western-style substitutes.[148] Overall, while long-term expansion is anticipated through diversification into hybrid and functional beverages, short-term headwinds underscore the market's sensitivity to economic and perceptual factors.Labeling Standards and Controversies
In the United States, the Food and Drug Administration (FDA) defines "milk" under 21 CFR 131.110 as the lacteal secretion from cows, yet permits plant-based alternatives to use the term "milk" when qualified by the source, such as "almond milk" or "soy milk," recognizing these as established common or usual names in the marketplace.[149] The FDA's 2023 draft guidance explicitly endorses this practice for products imitating the taste, appearance, or function of cow's milk, while recommending—though not requiring—voluntary nutrient content statements to disclose differences, such as lower protein levels (typically 1-2 grams per cup in almond or oat varieties versus 8 grams in cow's milk) or reliance on fortification for calcium and vitamin D.[150] In contrast, the European Union enforces stricter standards under Regulation (EU) No 1308/2013 and related rulings, reserving "milk" exclusively for animal-derived products and prohibiting its use for plant-based substitutes, even with qualifiers; terms like "soy drink" or "oat beverage" must be employed instead to avoid consumer deception regarding composition and nutritional profile.[151] This approach stems from EU directives aimed at protecting traditional dairy designations, with the European Court of Justice upholding prohibitions on dairy terms for non-animal products since at least 2017.[152] Controversies surrounding these labels center on claims of consumer confusion and nutritional misrepresentation, with the dairy industry arguing that unqualified or loosely qualified use of "milk" leads consumers to overestimate the equivalence of plant-based products, which often contain minimal natural protein and require fortification to approximate cow's milk nutrients—a process that does not replicate bioavailability or completeness.[153] A 2018 Ipsos survey commissioned by dairy groups found that many consumers erroneously believe plant-based milks match dairy milk's nutritional value, fueling legislative pushes like the reintroduced Dairy Pride Act in 2025, which seeks to ban dairy terms for non-dairy alternatives to safeguard economic interests amid declining dairy sales.[154] [155] Plant-based advocates counter that such terms are descriptive of sensory and functional similarities, not nutritional identity, and that historical standards of identity were intended to prevent adulteration rather than stifle innovation; the FDA's 2023 guidance aligns with this by prioritizing market-established names over rigid redefinition, despite dairy critiques of inadequate enforcement.[156] [157] These disputes have spurred litigation risks, including class-action suits over implied nutritional parity, highlighting tensions between empirical nutritional disparities and commercial naming conventions.[158]Debates and Criticisms
Nutritional Superiority Claims
Proponents of milk substitutes frequently assert nutritional superiority over cow's milk, citing attributes such as lower saturated fat content, absence of cholesterol, and inclusion of fiber or plant-based antioxidants in varieties like oat or almond milk.[159] These claims often emphasize reduced calorie density and suitability for lactose-intolerant individuals, positioning plant-based options as inherently healthier for cardiovascular health and weight management.[104] However, such assertions overlook empirical comparisons revealing cow's milk's higher concentrations of essential macronutrients and micronutrients, including protein (approximately 8 grams per cup versus 1-2 grams in most unfortified almond or oat milks), bioavailable calcium, phosphorus, iodine, and vitamins B2, B12, and A.[8][96] Peer-reviewed analyses consistently demonstrate that plant-based milks exhibit high variability in nutrient profiles and rarely match dairy milk's density without fortification, which introduces inconsistencies in absorption and stability.[160] For instance, a 2023 evaluation of over 200 products found that only 28 plant-based alternatives approximated cow's milk in protein, calcium, and vitamin D levels, with many containing added sugars (up to 7 grams per serving in flavored oat milks) that undermine low-calorie claims.[96] Soy milk fares relatively better in protein content (around 7 grams per cup) but includes phytoestrogens and lower bioavailability of minerals compared to dairy's complete amino acid profile and natural iodine (essential for thyroid function, often deficient in plant sources).[12] Almond milk, while low in calories (30-50 per cup), provides negligible protein and relies on fortification for calcium, which studies indicate is less effective for bone mineralization than dairy's organic matrix.[109] Oat milk, higher in carbohydrates (often 16 grams per cup), scores better in some nutritional indices due to beta-glucans but lags in essential amino acids and micronutrients like zinc and potassium.[104]| Nutrient (per 240ml serving) | Cow's Milk (whole) | Almond Milk (unsweetened) | Soy Milk (unsweetened) | Oat Milk (unsweetened) |
|---|---|---|---|---|
| Protein (g) | 8 | 1 | 7 | 3 |
| Calcium (mg, natural/fortified) | 276 / N/A | 0 / 450 | 0 / 300 | 0 / 350 |
| Vitamin B12 (µg) | 1.1 | 0 / 3 | 0 / 3 | 0 / 1 |
| Iodine (µg) | 56 | Trace | Trace | Trace |
| Saturated Fat (g) | 4.6 | 0.1 | 0.5 | 0.2 |