Pasteurization Techniques

Pasteurization is a heating process developed in the 19th century and named after the French science scientist Louis Pasteur. This method aims to enhance food safety and extend product shelf life by eliminating pathogenic microorganisms in food and beverages. Pasteurization is typically applied at temperatures below the boiling point of water, 100°C, and unlike sterilization, it targets only pathogens that can cause disease and some microorganisms responsible for spoilage, not all microorganisms. This process seeks to preserve the safety of the product while minimizing changes to its sensory (taste, smell, color) and nutritional properties.

Historical Development

The origins of pasteurization trace back to food preservation techniques developed centuries earlier. For instance, records indicate that wine was heated in China in 1117 to prevent spoilage, and similar methods were used in Japan during the 15th century. In the late 18th century, Italian scientist Lazzaro Spallanzani demonstrated that boiled and sealed meat broth did not spoil, proposing that microorganisms from the air caused decay. In 1795, French confectioner Nicolas Appert developed a method of preserving food by boiling it in sealed jars (canning), laying the foundation for pasteurization.

The birth of pasteurization, however, occurred through the work of Louis Pasteur in 1864.

While studying the spoilage of wine and beer, Pasteur discovered that these processes were not due to chemical reactions but to the metabolic activity of microorganisms, particularly yeast and bacteria. He successfully killed pathogens and prevented acidification by heating wine to 50–60°C and named this method “pasteurization.” Pasteur’s discovery formed the basis of the “germ theory” of disease, which established that microorganisms cause illness, and led to major advances in food safety and medicine.

Milk pasteurization was proposed in 1886 by German chemist Franz von Soxhlet and became widespread in the early 20th century. In 1908, Chicago enacted the first law mandating milk pasteurization, thereby preventing milk-borne tuberculosis, brucellosis and typhus like diseases. Over time, technological advances led to the development of high-temperature short-time (HTST), ultra-high temperature (UHT), and other methods.

Purpose of Pasteurization

The International Dairy Federation (IDF) defines pasteurization as: “A heat treatment designed to eliminate public health risks from milk-associated pathogens while causing minimal change to the chemical, physical, and organoleptic properties of the product.” This definition summarizes two primary objectives of pasteurization:

1. Public Health: Eliminating pathogenic microorganisms in food (e.g., Mycobacterium tuberculosis, Brucella abortus, Coxiella burnetii, Salmonella spp., Escherichia coli O157:H7, Listeria monocytogenes) to prevent foodborne illnesses.

2. Shelf Life Extension: Inactivating spoilage-causing enzymes (e.g., lipase, protease) and vegetative microorganisms (e.g., Streptococcus spp., Lactobacillus spp.) to enhance food durability.

Pasteurization differs from sterilization, which aims to eliminate all microorganisms; bacterial spores (e.g., Clostridium botulinum spores) typically survive. Therefore, pasteurized products must be stored under appropriate conditions (typically at 4°C) and consumed before their expiration date.

Types and Techniques of Pasteurization

Pasteurization is classified into different types based on the combination of temperature and time applied. Below are the most common commonly used methods for milk pasteurization, described with scientific detail:

• Vat (Tank) Pasteurization (LTLT – Low Temperature Long Time):
• • Process: Milk is heated to 63°C in a closed tank for 30 minutes and then rapidly cooled.
  • Equipment: A temperature-controlled tank is used; agitation is critical for uniform heat distribution.
  • Target: Eliminate heat-resistant pathogens such as Mycobacterium tuberculosis.
  • Advantages: Suitable for small-scale operations and cultured products like yogurt and cheese; preserves sensory qualities of the product.
  • Disadvantages: A slow process with low energy efficiency; impractical for large-volume production.
  • Shelf Life: 2–3 weeks under refrigerated conditions.

• High Temperature Short Time (HTST – Flash Pasteurization):
• • Process: Milk is held at 72°C for 15 seconds in a plate heat exchanger and then rapidly cooled.
  • Equipment: Includes a continuous flow system, plate heat exchanger, holding tube, and return valve.
  • Target: Achieve a 5-log reduction by eliminating 99.9% of pathogens.
  • Advantages: Energy efficient, ideal for large-scale production, causes minimal flavor change in milk.
  • Disadvantages: Requires more complex and costly equipment.
  • Shelf Life: 2–3 weeks under refrigerated conditions.

• Ultra Pasteurization (UP):
• • Process: Milk is heated to 138°C for 2 seconds and rapidly cooled; sterile equipment is used but no hermetic sealing is applied.
  • Advantages: Extends shelf life to 30–90 days, though refrigeration is required.
  • Disadvantages: May cause up to 20% loss in nutrients such as vitamins A, D, and E; perceptible flavor change.
  • Shelf Life: 30–90 days under refrigerated conditions.

• Ultra High Temperature (UHT):
• • Process: Milk is heated to 135–150°C for 2–5 seconds and aseptically packaged in hermetically sealed containers.
  • Equipment: Commercially sterile equipment and aseptic packaging systems are used.
  • Advantages: Eliminates all microorganisms including spores; provides a shelf life of 6–9 months at ambient temperature.
  • Disadvantages: Nutrient loss (especially B vitamins), flavor alteration, and high energy consumption.
  • Shelf Life: 6–9 months unopened.

Note: For dairy products with fat content above 10% or products with added ingredients, the temperature is increased by 3°C (e.g., 75°C in HTST).

Effect on Microorganisms

Pasteurization relies on the thermal death kinetics of microorganisms. Heat denatures bacterial enzymes (e.g., those facilitating metabolic reactions) proteins and weakens the cell membrane, increasing internal pressure and causing cell rupture. Below are the main groups of microorganisms targeted by pasteurization:

• Acid Producers: Streptococcus spp., Lactobacillus spp., Microbacterium spp., Coliforms, Micrococcus spp.

• Gas Producers: Coliforms, Clostridium butyricum, Torula cremoris

• Stringy/Mucoid Fermentation: Alcaligenes viscolactis, Enterobacter aerogenes

• Proteolytic Organisms: Bacillus spp., Pseudomonas spp., Proteus spp., Streptococcus liquefaciens

• Lipolytic Organisms: Pseudomonas fluorescens, Achromobacter lipolyticum, Candida lipolytica, Penicillium spp.

• Pathogens: Mycobacterium tuberculosis, Coxiella burnetii, Salmonella spp., Listeria monocytogenes, Escherichia coli O157:H7

bacterial spores (e.g., Clostridium botulinum) are heat-resistant and are not destroyed by pasteurization; therefore, methods requiring higher temperatures such as UHT are used.

Thermal Death Kinetics:

• D-Value: The time required at a specific temperature to reduce a microbial population by 90% (e.g., the D-value for Coxiella burnetii at 72°C is approximately 0.07 minutes).

• Z-Value: The temperature increase required to change the D-value by a factor of 10 (e.g., typically 5–10°C for bacteria).

Technological Advancements

Pasteurization techniques have evolved significantly since the 20th century:

• 1941: Pyrex heat-resistant glass tubing was introduced during wartime to conserve materials.
• 1955: The first automatic CIP (Clean-in-Place) system was installed in Ohio.
• 1956: Due to the heat resistance of Coxiella burnetii, the minimum temperature for vat pasteurization was raised from 142°F to 145°F.
• 1978: The first UHT “sterile” milk system was introduced in the United States.
• 1979: Magnetic flow meters replaced traditional timing pumps.
• Modern Innovations: Non-thermal methods such as High-Pressure Processing (HPP), Pulsed Electric Field (PEF), and Microwave Volumetric Heating (MVH) have been developed; these reduce nutrient loss.

Advantages and Disadvantages

Advantages:

• Eliminates pathogens and prevents diseases such as tuberculosis, diphtheria, and brucellosis.
• Extends shelf life (2–3 weeks with HTST, 6–9 months with UHT).
• Better preserves sensory qualities of food compared to sterilization.
• Facilitates global food trade.

Disadvantages:

• Can cause losses in vitamins (B2, C, A, D, E) and enzymes (e.g., up to 20% loss in UHT).
• Changes in taste and texture (especially a “cooked” flavor in UHT).
• Also eliminates beneficial microorganisms such as probiotics (Lactobacillus).
• Does not kill spores, requiring additional protective measures.

Pasteurization is a revolution essential technique for food safety and public health. Since Louis Pasteur’s 19th-century discovery, it has ensured the safe consumption of milk, fruit water, beer, and other foods, dramatically reducing foodborne illnesses. Different methods (Vat, HTST, UP, UHT) have been optimized according to product type and desired shelf life. However, side effects such as nutrient loss and flavor changes reveal the limitations of pasteurization. Although modern technologies (HPP, PEF) aim to mitigate these drawbacks, pasteurization remains one of the foundational pillars of the food industry. Scientific evidence confirms its effectiveness, while underscoring the need for balanced evaluation of its use.