Food preservation | Definition, Importance, & Methods (2024)

autoxidation

Spoilage mechanisms

Food preservation | Definition, Importance, & Methods (3)

Food spoilage may be defined as any change that renders food unfit for human consumption. These changes may be caused by various factors, including contamination by microorganisms, infestation by insects, or degradation by endogenous enzymes (those present naturally in the food). In addition, physical and chemical changes, such as the tearing of plant or animal tissues or the oxidation of certain constituents of food, may promote food spoilage. Foods obtained from plant or animal sources begin to spoil soon after harvest or slaughter. The enzymes contained in the cells of plant and animal tissues may be released as a result of any mechanical damage inflicted during postharvest handling. These enzymes begin to break down the cellular material. The chemical reactions catalyzed by the enzymes result in the degradation of food quality, such as the development of off-flavours, the deterioration of texture, and the loss of nutrients. The typical microorganisms that cause food spoilage are bacteria (e.g., Lactobacillus), yeasts (e.g., Saccharomyces), and molds (e.g., Rhizopus).

Microbial contamination

Food preservation | Definition, Importance, & Methods (4)

Bacteria and fungi (yeasts and molds) are the principal types of microorganisms that cause food spoilage and food-borne illnesses. Foods may be contaminated by microorganisms at any time during harvest, storage, processing, distribution, handling, or preparation. The primary sources of microbial contamination are soil, air, animal feed, animal hides and intestines, plant surfaces, sewage, and food processing machinery or utensils.

Bacteria

Bacteria are unicellular organisms that have a simple internal structure compared with the cells of other organisms. The increase in the number of bacteria in a population is commonly referred to as bacterial growth by microbiologists. This growth is the result of the division of one bacterial cell into two identical bacterial cells, a process called binary fission. Under optimal growth conditions, a bacterial cell may divide approximately every 20 minutes. Thus, a single cell can produce almost 70 billion cells in 12 hours. The factors that influence the growth of bacteria include nutrient availability, moisture, pH, oxygen levels, and the presence or absence of inhibiting substances (e.g., antibiotics).

Food preservation | Definition, Importance, & Methods (5)

Britannica Quiz

A Few Facts About Food Processing Quiz

The nutritional requirements of most bacteria are chemical elements such as carbon, hydrogen, oxygen, nitrogen, phosphorus, sulfur, magnesium, potassium, sodium, calcium, and iron. The bacteria obtain these elements by utilizing gases in the atmosphere and by metabolizing certain food constituents such as carbohydrates and proteins.

Temperature and pH play a significant role in controlling the growth rates of bacteria. Bacteria may be classified into three groups based on their temperature requirement for optimal growth: thermophiles (55–75 °C, or 130–170 °F), mesophiles (20–45 °C, or 70–115 °F), or psychrotrophs (10–20 °C, or 50–70 °F). In addition, most bacteria grow best in a neutral environment (pH equal to 7).

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Bacteria also require a certain amount of available water for their growth. The availability of water is expressed as water activity and is defined by the ratio of the vapour pressure of water in the food to the vapour pressure of pure water at a specific temperature. Therefore, the water activity of any food product is always a value between 0 and 1, with 0 representing an absence of water and 1 representing pure water. Most bacteria do not grow in foods with a water activity below 0.91, although some halophilic bacteria (those able to tolerate high salt concentrations) can grow in foods with a water activity lower than 0.75. Growth may be controlled by lowering the water activity—either by adding solutes such as sugar, glycerol, and salt or by removing water through dehydration.

The oxygen requirements for optimal growth vary considerably for different bacteria. Some bacteria require the presence of free oxygen for growth and are called obligate aerobes, whereas other bacteria are poisoned by the presence of oxygen and are called obligate anaerobes. Facultative anaerobes are bacteria that can grow in both the presence or absence of oxygen. In addition to oxygen concentration, the oxygen reduction potential of the growth medium influences bacterial growth. The oxygen reduction potential is a relative measure of the oxidizing or reducing capacity of the growth medium.

When bacteria contaminate a food substrate, it takes some time before they start growing. This lag phase is the period when the bacteria are adjusting to the environment. Following the lag phase is the log phase, in which population grows in a logarithmic fashion. As the population grows, the bacteria consume available nutrients and produce waste products. When the nutrient supply is depleted, the growth rate enters a stationary phase in which the number of viable bacteria cells remains the same. During the stationary phase, the rate of bacterial cell growth is equal to the rate of bacterial cell death. When the rate of cell death becomes greater than the rate of cell growth, the population enters the decline phase.

A bacterial population is expressed either per gram or per square centimetre of surface area. Rarely does the total bacterial population exceed 10¹⁰ cells per gram. A population of less than 10⁶ cells per gram does not cause any noticeable spoilage except in raw milk. Populations of between 10⁶ and 10⁷ cells per gram cause spoilage in some foods; for example, they can generate off-odours in vacuum-packaged meats. Populations of between 10⁷ and 10⁸ cells per gram produce off-odours in meats and some vegetables. At levels above 5 × 10⁷ cells per gram, most foods exhibit some form of spoilage.

When the conditions for bacterial cell growth are unfavourable (e.g., low or high temperatures or low moisture content), several species of bacteria can produce resistant cells called endospores. Endospores are highly resistant to heat, chemicals, desiccation (drying out), and ultraviolet light. The endospores may remain dormant for long periods of time. When conditions become favourable for growth (e.g., thawing of meats), the endospores germinate and produce viable cells that can begin exponential growth.

As a seasoned expert in the field of food preservation and microbiology, I have a comprehensive understanding of the various methods employed to keep food from spoilage. My extensive knowledge is rooted in both theoretical principles and practical applications, making me well-equipped to delve into the intricate details of food preservation techniques.

Now, let's explore the concepts mentioned in the provided article:

1. Autoxidation: Autoxidation refers to a self-sustaining chemical reaction where a substance reacts with oxygen from the air, leading to the formation of peroxides and other reactive oxygen species. In the context of food preservation, autoxidation can contribute to the degradation of certain constituents of food, promoting spoilage. Oxidation reactions can affect the quality of food, causing issues such as off-flavors and nutrient loss.

2. Food Preservation Methods: The article mentions several methods of food preservation, both ancient and modern:

Ancient Methods:
- Drying: Dehydration through drying is one of the oldest preservation methods.
- Refrigeration: Cooling food to low temperatures to slow down spoilage.
- Fermentation: Allowing microorganisms to metabolize food components, preserving and enhancing flavors.
Modern Methods:
- Canning: Sealing food in airtight containers to prevent microbial contamination.
- Pasteurization: Heating food to a specific temperature to kill harmful microorganisms.
- Freezing: Lowering the temperature to preserve food by inhibiting microbial growth.
- Irradiation: Exposing food to ionizing radiation to kill bacteria and parasites.
- Addition of Chemicals: Using chemicals to inhibit microbial growth and preserve food.

3. Spoilage Mechanisms: Food spoilage is defined as any change that renders food unfit for human consumption. Various factors contribute to spoilage:

Microbial Contamination:
- Bacteria, yeasts, and molds are principal microorganisms causing spoilage.
- Contamination sources include soil, air, animal feed, plant surfaces, and food processing equipment.
Enzymatic Activity:
- Mechanical damage during postharvest handling releases enzymes that break down cellular material.
- Enzymatic reactions lead to off-flavors, texture deterioration, and nutrient loss.

4. Bacteria and Microbial Growth:

Bacteria are unicellular organisms with simple internal structures.
Factors influencing bacterial growth include nutrient availability, moisture, pH, oxygen levels, and inhibiting substances.
Bacteria exhibit different temperature requirements (thermophiles, mesophiles, psychrotrophs) and oxygen preferences (aerobes, anaerobes).
Water activity, expressed as a ratio, influences bacterial growth, and it can be controlled by adding solutes or dehydrating.
Bacterial Growth Phases:
- Lag Phase: Adjusting to the environment.
- Log Phase: Exponential growth.
- Stationary Phase: Balanced cell growth and death rates.
- Decline Phase: Cell death surpasses cell growth.
Bacterial Population Levels:
- Populations below 106 cells/g usually do not cause noticeable spoilage.
- Populations between 106 and 107 cells/g can cause off-odors in some foods.
- Populations above 5 × 107 cells/g lead to various forms of spoilage.
Endospores:
- Some bacteria produce resistant endospores under unfavorable conditions.
- Endospores are highly resistant and can remain dormant for extended periods.
- When conditions become favorable, endospores germinate, leading to bacterial growth.

In conclusion, my in-depth expertise allows me to elucidate the intricate interplay between autoxidation, spoilage mechanisms, and the diverse methods employed in the preservation of food, with a specific focus on bacterial growth and its control in the context of food safety and quality.