Five forces are driving the switch:

• Consumer demand for protein. High-protein positioning is now mainstream across snacks, bakery, pasta, and beverages. Pulse flours are one of the fastest, cleanest-label ways to lift protein on a Nutrition Facts table without resorting to isolates.
• Plant-based and flexitarian growth. Plant-protein ingredients continue to grow across mainstream products, and pulse flours fit naturally into the trend.
• Clean-label pressure. Manufacturers are reformulating away from soy, gums, and modified starches. Pulse flour is recognizably food, simple to declare, and free from the top-eight
  allergens.
• Gluten-free demand. Pulse flours are naturally gluten-free and outperform rice flour on protein and fibre.
• Sustainability and supply-chain risk. Pulses fix nitrogen, use less water, and grow well on dryland prairie. For manufacturers building a sustainability story or hedging against wheat- or soy-supply volatility, pulse flour improves both ESG metrics and supply diversification at the same time.

For most manufacturers, the question is no longer whether to use pulse flour but which pulse, in what format, and from which supplier. Talk to the Simpson Seeds team about samples, specifications, or
contract milling for your next pulse-flour product.

Raw pulse flour is cold-milled directly from the dried pulse and must be cooked before consumption; precooked pulse flour has already been heat-treated and is safe and ready to use without further cooking. The two are not interchangeable in formulation — choosing the wrong format is one of the most common sourcing mistakes in pulse-based product development.

• Raw pulse flour is the most cost-effective format and is appropriate for applications where the flour will be cooked or baked at the manufacturer’s facility — pasta, baked goods, batters,
  soups, and most extruded snacks. Raw flour retains the pulses’ natural starch structure, which is important for elasticity and bite in pasta and for proper rise in bakery.
• Precooked pulse flour is heat-treated to gelatinize the starches, deactivate enzymes, and reduce the “beany” volatile compounds that some consumers find off-putting. The result is a flour that is fully cooked, immediately digestible, dispersible in cold water, and free of the anti-nutritional factors that raw pulse flour contains. Precooked flour is essential for protein bars, ready-to-mix beverages, instant soups, infant nutrition, and any cold-process or ready-to-eat product where the manufacturer cannot guarantee an in-process cook step.

Simpson Seeds Moose Jaw mill produces both formats for red lentil flour and chickpea flour, and offers contract-milled precooked options for pea and fava bean flours.

Pulse flour is a flour milled from dried, edible legume seeds — specifically lentils, chickpeas, dry peas, and fava beans. Unlike grain flours, which come from cereal crops like wheat, rye, or oats, pulse flours
come from the protein-rich seeds of legume plants and are naturally high in protein and fibre, low in fat, and gluten-free.

The category includes red lentil flour, green lentil flour, chickpea flour (also called besan or gram flour), yellow pea flour, green pea flour, and fava bean flour. Each has a different flavour, colour, and functional behaviour, but all share the same basic nutritional advantage over wheat: roughly twice the protein per 100 grams and significantly more fibre.

Pulse flours are produced in two main formats — raw (cold-milled) and precooked (heat-treated to gelatinize starch and reduce beany flavor). Some processors, including the Simpson Seeds pulse flour
mill in Moose Jaw, Saskatchewan, also produce extruded pulse ingredients for snack and protein-crisp applications.

The biggest differences between pulse flour and wheat flour are protein content, fibre, gluten, and functional behaviour in dough.

• Protein: Whole-grain wheat flour contains roughly 12–15% protein, while pulse flours contain 20–35% depending on the pulse — chickpea (~20–22%), pea (~20–24%), red lentil (~24–28%),
  and fava bean (~26–30%).
• Fibre: Most pulse flours have 2–3× the fibre of refined wheat flour, with significant amounts of resistant starch.
• Gluten: Pulse flours contain no gluten. They cannot replace wheat 1:1 in elastic-dough applications like bread without reformulation, but they perform well in batters, crackers, pasta, gluten-free baking, and protein-fortified bakery.
• Amino acid profile: Wheat is deficient in lysine; pulses are rich in lysine but lower in sulfur amino acids. Blending the two creates a more complete protein than either flour alone.
• Glycemic response: Pulse flours generally have a lower glycemic index than refined wheat flour, owing to higher fibre and slowly digestible starch.

For food manufacturers, the practical takeaway is that pulse flours are typically used to fortify or partially replace wheat flour to lift protein and fibre — not as a like-for-like substitute.

A functional flour is a flour engineered to deliver a specific technical or nutritional performance in a finished food product, beyond the basic role of providing structure or volume. The term covers any flour where function — protein content, water-binding, gelatinization profile, fibre delivery, viscosity, emulsification, or cold-process readiness — has been deliberately optimized through ingredient selection, processing, or both.

Pulse flours are among the most important functional flours available today because they deliver multiple functions at once: high protein, high fibre, gluten-free, naturally gelling (when precooked), and nutrient-dense. Precooked pulse flour, in particular, is a true functional ingredient — heat treatment gelatinizes the starch, denatures off-flavour compounds, and makes the flour cold-process ready for protein bars, instant beverages, and ready-to-eat applications where raw flour would be unsafe or unpalatable.

For R&D teams, the practical implication is that specifying a pulse flour means specifying not just the pulse type (chickpea, lentil, pea, fava) but also the format (raw vs. precooked vs. extruded), the particle size, and any additional functional treatment. Simpson Seeds' contract milling team works with food manufacturers to spec each of these parameters before a production run begins.

Pulse flour is a whole-food ingredient — soy isolate, pea protein isolate, and wheat gluten are extracted protein concentrates. They serve different roles in formulation and shouldn't be thought of as direct substitutes.

• vs. Soy protein isolate (~90% protein): Pulse flour has lower protein density (20–30%) but
  brings fibre, slowly-digestible carbohydrates, micronutrients, and cleaner-label appeal. Many
  manufacturers reformulating away from soy because of allergen concerns or label perception
  are using pulse flour as a direct replacement.
• vs. Pea protein isolate (~80% protein): Pea protein isolate is the same crop as yellow pea flour
  — but extracted, dried, and concentrated. Isolate is more expensive per kg, more processed,
  and lacks the fibre. Pulse flour wins on cost, label simplicity, and sustainability; isolate wins
  where high protein content per gram is essential.
• vs. Wheat gluten (~75% protein): Gluten provides chewy, elastic texture for meat analogs, but it
  is by definition not gluten-free, is allergenic for many consumers, and carries the regulatory and
  consumer-perception baggage of wheat. Pulse flour offers a gluten-free, often more digestible
  alternative for plant-based meat formulations.
• vs. Other pulse ingredients (pulse protein concentrates, fractions, isolates): Pulse flour is the
  simplest, lowest-processed, lowest-cost option. Pulse protein concentrates and isolates are
  higher-protein and more expensive — useful when formulation density matters more than
  ingredient simplicity.

The best formulations often combine multiple ingredients: pulse flour for whole-food positioning, an
isolate for protein density, and minimal gums or starches for finished texture.

Pulse flour is used across nearly every food category — wherever a manufacturer needs to lift protein, lift fibre, replace gluten, or add functional water-binding without changing flavour profile too dramatically. The most common applications:

• Pasta and noodles — red lentil and chickpea flour produce the leading commercial gluten-free and high-protein pastas on the market.
• Bakery and crackers — partial replacement of wheat flour to lift protein, fibre, and nutritional density without compromising structure.
• Snacks (extruded, baked, fried) — chickpea, lentil, and fava bean flours are workhorses in better-for-you snack formats; extruded pulse ingredients are used for protein crisps and texturized bites.
• Plant-based meat — fava bean and pea flour provide protein, water-binding, and texture in burgers, nuggets, and ground analogs.
• Plant-based dairy — chickpea and pea flours appear in dairy-alternative cheeses, yogurts, and creamy sauces.
• Soups, sauces, and ready-meals — precooked pulse flours add body, protein, and natural thickening without modified starches.
• Protein bars and cold-process products — precooked pulse flours are essential here because they are fully cooked and ready to use without further processing.
• Pet food and aquafeed — pulse flours and pulse fractions are increasingly used in premium pet food premixes.

Simpson Seeds supplies all of these end markets from its Moose Jaw, Saskatchewan mill, with both
standard SKUs and contract-milled custom specifications.

Pulses are one of the most sustainable crops in commercial agriculture — and that sustainability transfers directly to flour milled from them. Three properties drive the advantage:

• Nitrogen fixation. Lentils, chickpeas, peas, and fava beans form a symbiotic relationship with rhizobia bacteria that pull nitrogen from the air into the soil. This dramatically reduces the need
  for synthetic nitrogen fertilizer — both for the pulse crop itself and for the next crop in rotation. Including pulses in a wheat or oilseed rotation can reduce nitrous oxide emissions by 20–25%
  and cut the carbon footprint of the entire rotation.
• Low water footprint. Pulses have shorter growing seasons and root systems that use shallow soil moisture efficiently, sparing deeper water for subsequent crops. They are well-suited to
  dryland production in semi-arid regions like the Saskatchewan prairies, where most North American pulses are grown without irrigation.
• Soil health. Pulse residues improve soil organic matter and microbial diversity, leaving the soil better than they found it for the next rotation.

For food manufacturers building a sustainability story, sourcing pulse flour from a Saskatchewan-based mill compounds the advantage — Saskatchewan grows roughly half the world's lentils, and short-haul,
dryland-rainfed sourcing further reduces the embedded carbon of every kilogram of finished flour.