Asparagus, canned, drained solids

Asparagus, canned, drained solids is a vegetable, providing very few calories (19.0 kcal per 100g). It is a good source of Vitamin K1, providing 34% of the Daily Value per 100g. This vegetable is a useful source of fiber, virtually fat-free. Vegetables provide essential vitamins, minerals, and dietary fiber with relatively few calories. They are a cornerstone of virtually every dietary guideline worldwide. Our database tracks 88 nutrients for this food, plus insulin index, environmental footprint data.

19.0

Calories

kcal

1.9

Protein

0.65

Fat

2.5

Carbs

3.9

Fiber

Serving size: or

Top Nutrients

☀️

Vitamin K1

41.3 µg

34% DV

💎

Iron

1.6 mg

20% DV

☀️

Folate

76.0 µg

19% DV

Data for 88 of 150 tracked nutrients

Nutrient Fingerprint

How this food scores across key nutrient categories, as a percentage of the daily recommended value per 100 g. Based on USDA DRIs for adults.

Complete Nutrient Profile

Macronutrients 10

Nutrient	Per 100g	Unit	Per Serving	% DV
Water AFCD	93.5	g	—	2%
Calories SR	19.0	kcal	—	—
Energy (kJ) SR	81.0	kj	—	—
Protein AFCD	1.9	g	—	3%
Total Fat SR	0.65	g	—	—
Carbohydrate SR	2.5	g	—	2%
Fiber AFCD	3.9	g	—	10%
Total Sugars SR	1.1	g	—	—
Starch AFCD	0	g	—	—
Ash AFCD	1.0	g	—	—

Minerals 10

Nutrient	Per 100g	Unit	Per Serving	% DV
Calcium AFCD	12.0	mg	—	1%
Iron AFCD	1.6	mg	—	20%
Magnesium AFCD	7.0	mg	—	2%
Phosphorus AFCD	35.0	mg	—	5%
Potassium AFCD	120	mg	—	4%
Sodium AFCD	240	mg	—	16%
Zinc AFCD	0.60	mg	—	6%
Copper AFCD	0.09	mg	—	10%
Manganese AFCD	0.10	mg	—	4%
Selenium AFCD	0	µg	—	—

Vitamins 27

Nutrient	Per 100g	Unit	Per Serving	% DV
Vitamin A (RAE) AFCD	67.0	µg	—	7%
Vitamin A (IU) SR	41.0	IU	—	—
Retinol AFCD	0	µg	—	—
Beta-Carotene AFCD	400	µg	—	—
Alpha-Carotene AFCD	0	µg	—	—
Beta-Cryptoxanthin AFCD	0	µg	—	—
Lycopene SR	24.0	µg	—	—
Lutein + Zeaxanthin SR	630	µg	—	—
Vitamin C AFCD	6.0	mg	—	7%
Vitamin D SR	0	µg	—	—
Vitamin D (IU) AFCD	0	IU	—	—
Vitamin D2 AFCD	0	µg	—	—
Vitamin D3 AFCD	0	µg	—	—
Vitamin E AFCD	0.60	mg	—	4%
Vitamin K1 SR	41.3	µg	—	34%
Thiamin (B1) AFCD	0	mg	—	—
Riboflavin (B2) AFCD	0.08	mg	—	6%
Niacin (B3) AFCD	0.70	mg	—	4%
Pantothenic Acid (B5) SR	0.14	mg	—	3%
Vitamin B6 AFCD	0.09	mg	—	7%
Folate AFCD	76.0	µg	—	19%
Folic Acid SR	0	µg	—	—
Folate (food) AFCD	76.0	µg	—	—
Folate (DFE) AFCD	76.0	µg	—	—
Vitamin B12 AFCD	0	µg	—	—
Choline SR	21.4	mg	—	4%
Betaine SR	0.70	mg	—	—

Fatty Acids 9

Nutrient	Unit	Per Serving	% DV
Saturated Fat AFCD	g	—	—
Monounsaturated Fat AFCD	g	—	—
Polyunsaturated Fat AFCD	g	—	—
Trans Fat AFCD	g	—	—
Cholesterol AFCD	mg	—	—
Omega-3 ALA AFCD	g	—	—
Omega-3 EPA AFCD	g	—	—
Omega-3 DPA AFCD	g	—	—
Omega-3 DHA AFCD	g	—	—

Individual Fatty Acids 10

Nutrient	Per 100g	Unit	Per Serving	% DV
Butyric Acid (4:0) SR	0	g	—	—
Caproic Acid (6:0) SR	0	g	—	—
Caprylic Acid (8:0) SR	0	g	—	—
Capric Acid (10:0) AFCD	0	g	—	—
Lauric Acid (12:0) SR	0.002	g	—	—
Myristic Acid (14:0) SR	0.004	g	—	—
Palmitic Acid (16:0) SR	0.13	g	—	—
Stearic Acid (18:0) SR	0.009	g	—	—
Linoleic Acid (18:2) AFCD	0	g	—	—
Linolenic Acid (18:3) SR	0.01	g	—	—

Amino Acids 18

Nutrient	Per 100g	Unit	Per Serving	% DV
Tryptophan AFCD	0.02	g	—	—
Threonine SR	0.06	g	—	—
Isoleucine SR	0.08	g	—	—
Leucine SR	0.09	g	—	—
Lysine SR	0.10	g	—	—
Methionine SR	0.02	g	—	—
Cystine SR	0.03	g	—	—
Phenylalanine SR	0.05	g	—	—
Tyrosine SR	0.03	g	—	—
Valine SR	0.08	g	—	—
Arginine SR	0.10	g	—	—
Histidine SR	0.03	g	—	—
Alanine SR	0.10	g	—	—
Aspartic Acid SR	0.25	g	—	—
Glutamic Acid SR	0.35	g	—	—
Glycine SR	0.07	g	—	—
Proline SR	0.11	g	—	—
Serine SR	0.08	g	—	—

Phytochemicals 1

Nutrient	Per 100g	Unit	Per Serving	% DV
Oxalic Acid AFCD	0	mg	—	—

Other 3

Nutrient	Unit	Per Serving	% DV
Caffeine AFCD	mg	—	—
Theobromine SR	mg	—	—
Alcohol AFCD	g	—	—

Nutrient Density Score

The NRF9.3 score measures overall nutritional quality per 100 kcal. It rewards 9 nutrients to encourage (protein, fiber, vitamins A, C, E, calcium, iron, magnesium, potassium) and penalizes 3 to limit (saturated fat, added sugars, sodium). Higher is better; negative scores indicate the food is high in limit nutrients relative to its beneficial content.

208

NRF9.3 Score

Excellent · per 100 kcal

Poor (<0) Moderate Good Excellent (100+)

NRF9.3 index: Fulgoni et al. (2009), J Nutr 139(8). DVs based on FDA 2020 reference values.

Nutrient Interactions in This Food

Nutrients in this food that enhance or compete with each other during absorption.

✔ Synergies — nutrients that help each other

Vitamin C + Iron●●●

Vitamin C dramatically enhances non-heme iron absorption by reducing Fe³⁺ to Fe²⁺ in the gut. Adding 75 mg vitamin C to a meal can increase iron absorption 3–4 fold.

Hallberg et al., Am J Clin Nutr, 1989

Dietary Fat + Vitamin A●●●

Vitamin A is fat-soluble and requires dietary fat for absorption. Adding fat to a meal significantly increases beta-carotene and retinol absorption.

Ribaya-Mercado et al., Am J Clin Nutr, 2007

Dietary Fat + Vitamin K●●●

Vitamin K is fat-soluble. Absorption increases significantly when consumed with dietary fat, particularly for phylloquinone (K1) from plant sources.

Gijsbers et al., Br J Nutr, 1996

Vitamin B6 + Folate●●●

Vitamin B6 is a cofactor in folate-dependent one-carbon metabolism. Together with B12, these three nutrients regulate homocysteine levels.

Selhub, J Nutr Health Aging, 2002

⚠ Antagonisms — nutrients that compete

Zinc vs Copper●●●

High zinc intake induces metallothionein in enterocytes, which traps copper and blocks its absorption. Prolonged high-dose zinc can cause copper deficiency.

Prasad et al., JAMA, 1978; Fosmire, Am J Clin Nutr, 1990

Zinc vs Iron●●●

Zinc and non-heme iron compete for the same intestinal transporter (DMT1). High doses of one can reduce absorption of the other when taken simultaneously.

Rossander-Hulten et al., Am J Clin Nutr, 1991

Fiber vs Iron●●●

Phytates in high-fibre foods (whole grains, legumes) bind non-heme iron and reduce its bioavailability. Soaking, sprouting, and fermentation reduce phytate content.

Hurrell & Egli, Int J Vitam Nutr Res, 2010

Fiber vs Zinc●●●

Phytates in fibre-rich foods chelate zinc, reducing its bioavailability by up to 50% in high-phytate diets. This is a major concern in plant-based diets.

Sandstrom, Food Nutr Res, 1997

Vitamin C vs Copper●●●

High-dose vitamin C (>1,500 mg/day) may reduce copper absorption by reducing Cu²⁺ to Cu⁺, though the clinical significance at normal intakes is minimal.

Harris, Am J Clin Nutr, 2003

Amino Acid Profile

Essential amino acid composition compared to the WHO/FAO adult reference pattern. The Amino Acid Score indicates protein quality — 100 means all essential amino acid requirements are met.

Amino Acid Score

Good

Leucine

Limiting Amino Acid

Amino Acids Tracked

Tip: The limiting amino acid is Leucine. Pair with dairy, eggs, and meat for a complete amino acid profile.

All Amino Acids (18)

Amino Acid	g / 100g	mg / g protein
Tryptophan	0.02	10.0
Threonine	0.06	31.6
Isoleucine	0.08	41.6
Leucine	0.09	48.9
Lysine	0.10	53.2
Methionine	0.02	11.1
Cystine	0.03	13.2
Phenylalanine	0.05	26.8
Tyrosine	0.03	17.9
Valine	0.08	43.2
Arginine	0.10	52.6
Histidine	0.03	17.4
Alanine	0.10	53.2
Aspartic Acid	0.25	130.5
Glutamic Acid	0.35	184.2
Glycine	0.07	36.3
Proline	0.11	60.0
Serine	0.08	42.6

How Cooking Changes Nutrients

Estimated percentage of each nutrient retained after cooking, based on USDA retention factors for the “Other Vegetables” food category. Values of 100% mean no loss; lower values indicate nutrients lost to heat, water, or oxidation.

Key insights

⚡Folate loses up to 31% when boiled (drained). Boiled (water used) retains 85%.

⚡Choline loses up to 10% when fried. Boiled (drained) retains 100%.

Source: USDA Table of Nutrient Retention Factors, Release 6 (2007). Retention values are category-level averages — actual retention depends on cooking time, temperature, and water volume.

USDA Retention Factors

Insulin Response

The Insulin Index (II) measures the actual insulin response to food on a scale where white bread = 100. Unlike the Glycemic Index (which only measures blood sugar), the II captures the full hormonal response — including the effect of protein and fat on insulin secretion. This is why high-protein foods like meat and dairy can have significant insulin scores despite having low or zero GI values.

Insulin Index

Moderate Insulin Response

Insulin Index Scale 52

0 Low ≤30 Mod ≤60 High ≤100 120

Macro Model ●●● Estimated from macronutrient composition (R²=0.49)

Source: Holt et al. 1997; Bao et al. 2016; Bell 2014

Environmental Impact

Environmental footprint per kilogram of food produced. Data represents the global average for the “Other Vegetables” category.

0.53

kg CO₂e / kg

Very Low Impact

0.37

m² land / kg

Land Use

103

L water / kg

Water Use

3.2

g SO₂e / kg

Acidification

How this compares (GHG emissions)

Potatoes (0.5)Chicken (9.9)Beef (99.5)

Greenhouse Gas Emissions0.53 kg CO₂e / kg

Land Use0.37 m² / kg

Water Use103 L / kg

Eutrophication4.9 g PO₄e / kg

Acidification3.2 g SO₂e / kg

⚠️ Important context about this data

Global averages: These figures are production-weighted averages from a meta-analysis of ~38,700 farms across 119 countries (Poore & Nemecek, 2018). Actual impact varies enormously by farming method, geography, and supply chain.
System boundary: Cradle-to-retail only — does not include consumer transport, home cooking energy, or food waste.
Soil carbon not included: This data does not account for soil carbon sequestration. Some argue that well-managed regenerative grazing partially offsets ruminant emissions; however, full lifecycle accounting — including methane, land-use change, and the opportunity cost of using land for grazing vs. reforestation — typically makes the net footprint of ruminant meat higher, not lower. This is especially relevant in temperate grassland regions like Ireland.
Not gospel: This data is informational and illustrative. It is useful for understanding relative magnitudes, but should not be treated as precise measurements for any individual product or farm.

Source: Poore & Nemecek (2018), Science 360(6392). Meta-analysis of ~38,700 farms, 119 countries, 46 product categories.

Global Supply: Vegetables

Top 10 countries by per capita supply of the “Vegetables” food group (kcal/capita/day, 2023). This is food group–level data from FAO Food Balance Sheets, not specific to this individual food.

China; mainland

310

China

306

Albania

258

North Macedonia

221

Guyana

209

Kazakhstan

204

Oman

192

Uzbekistan

190

Tajikistan

186

10.

Bosnia and Herzegovina

183

Global Supply Trend (1961–2023)

+76%

1961: 38 kcal2023: 67 kcal

Source: FAO Food Balance Sheets (2023). Supply = production + imports − exports − waste, converted to kcal/capita/day.

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Frequently Asked Questions

How many calories are in Asparagus, canned, drained solids?

Asparagus, canned, drained solids contains 19.0 kcal per 100 grams, making it a very low-calorie food. The energy comes from 1.9g of protein (40% of calories), 0.65g of fat (31%), and 2.5g of carbohydrates (52%). Carbohydrates are the primary energy source.

What is Asparagus, canned, drained solids most nutritious for?

The standout nutrient in Asparagus, canned, drained solids is Vitamin K1, providing 41.3 µg per 100g (34% of the Daily Value). It is also a notable source of Iron (20% DV). Our database tracks 88 individual nutrients for this food, allowing detailed comparison across vitamins, minerals, amino acids, and fatty acids.

Is Asparagus, canned, drained solids high in protein?

At 1.9g per 100 grams, Asparagus, canned, drained solids is not a significant source of protein. Pair with protein-rich foods like legumes, meat, fish, or dairy to meet daily protein needs.

How much fiber is in Asparagus, canned, drained solids?

Asparagus, canned, drained solids contains 3.9g of fiber per 100 grams — a moderate amount. This contributes to the recommended daily intake of 25-38g. Pairing with other fiber-rich foods like vegetables, legumes, or whole grains can help meet daily targets.

What is the insulin index of Asparagus, canned, drained solids?

Asparagus, canned, drained solids has a moderate insulin response (II: 52) (estimated from macronutrient composition) on the insulin index scale (white bread = 100). This is a typical insulin response for most mixed foods. Note that the insulin index can differ substantially from the glycemic index — dairy products and high-protein foods often have higher insulin responses than their GI would suggest.

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