Young Scientist, Postgraduate, winning article by Saravjeet Kaur Bajwa, Manchester Metropolitan University
Food safety has increasingly become a fundamental health concern for consumers and a major challenge for food manufacturers due to foodborne diseases outbreaks caused by pathogenic microorganisms [1]. In the process of combating the impact of foodborne microorganisms, there has been increased use of synthetic chemical preservatives such as nitrites, nitrates, benzoic acid as antimicrobial agents. Studies showed that nitrites, nitrates when used in processed meat and products causes increased risk of colon cancer[2],[3]. The utilisation of sulphites can result in allergic responses in sulphite sensitive persons. The use of synthetic phenolic antioxidants like butylated hydroxyanisole (BHA) and butylated hydroxytoluene (BHT) has been reduced, due to health risks concerns[4]. Moreover, consumers are increasingly suspicious of synthetic preservatives and have increased desire for ‘CLEAN LABEL’. In the last decades, many research studies have focused on finding alternate antimicrobial agents for use in food to combat both pathogenic and spoilage microorganisms. Some of the studies have looked at potential bioactive compounds from natural plant based materials that could be used in food products, which inhibit growth of microorganisms and provide food safety and preservation effects2,[5].
Plant sources of natural antimicrobials
A number of spices and herbs contain natural antimicrobial properties and can be used to extend the shelf life of unprocessed and processed foods by reducing microbial growth[6],[7],[8]. Spices and herbs are natural plant materials, that are not only used as flavouring or colouring agents in food, but as standardised extracts for medicinal purposes, such as eugenol (from clove oil), and are also used in small quantities as preservatives in food[9]. Application in the preservation of foodstuff is mainly through inhibition of lipid oxidation, colour loss and as retardants of microbial activity2,5. Commonly used Indian spices and herbs are listed in Table 1.
Table 1 Some commonly used Indian spices and herbs
Common name |
Biological name |
Family |
Part used |
Bay leaves |
Laurus nobilis |
Lauraceae |
Leaves |
Black pepper |
Piper nigrum |
Piperaceae |
Fruit |
Cinnamon |
Cinnamomum verum |
Lauraceae |
Bark |
Cloves |
Syzygim aromaticum |
Myrtaceae |
Flower buds |
Coriander |
Coriandrum sativum |
Apiaceae |
Seeds |
Cumin |
Cuminum cyminum |
Apiaceae |
Seeds |
Mace |
Myristica fragrans |
Myristica |
Aril (seed covering) |
Nutmeg |
Myristica fragrans |
Myristica |
Seed |
Saffron |
Crocus sativus |
Iridaceae |
Stigmas with style |
Sesame seeds |
Sesamum indicum |
Pedaliceae |
Seeds |
Thyme |
Thymus vulgaris |
Lamiaceae |
Leaves with flowering tips |
Turmeric |
Curcuma longa |
Zingiberaceae |
Roots |
Bioactive components of spices and herbs
Spices and herbs contain secondary metabolites – a variety of bioactive compounds such as phenolic acids, flavonoids, and terpenes, which may be present in various parts of the plants such as flowers (jasmine, rose and lavender), buds (clove), leaves (thyme, bay leaves), fruits (star anise), twigs, bark (cinnamon), seeds (coriander, cardamom), wood (sandal), roots (ginger)5,[10] imparting antimicrobial and antioxidant properties2,5,[11]. Cinnamon, cloves, oregano, thyme and rosemary are some common spices with strong antimicrobial activity. The essential oil extracted from spices and herbs has shown antimicrobial activity inhibiting foodborne pathogens such as Listeria monocytogenes, Salmonella typhi, E.coli and Bacillus cereus in food as well as providing longer shelf life1,3.
Essential oil composition depends on internal and external agents influencing the plant such as genetic structures, ecological situations and agricultural factors[12]. In addition, seasonal variations, developmental stages of collected plant material, methods of harvest, processing of plant material, such as extraction methods and the conditions of analysis, are influenced on the essential oil yield and on the composition of bioactive compounds12,[13]. The active components including phenols, saponin, thiosulfinates, glucosinolates, alcohols, aldehydes, ketones, ethers and hydrocarbons especially in spices, for example, cinnamon, clove, garlic, mustard and onion show antimicrobial properties in inhibition of Gram-positive and Gram-negative pathogens1 (Table 2).
Table 2 Bioactive (phenolic) components found in commonly used spices and herbs as a major antimicrobial compounds (Adapted from 1,[14])
Category |
Class |
Sub-class |
Example of spices and herbs |
Polyphenols |
Flavonoids |
Flavanols (e.g. Catechin) |
Cinnamon |
Flavanones |
Fennel |
||
Flavones |
Onion, Oregano |
||
Flavonols (e.g. Quercetin) |
Coriander, Cumin, Black pepper, Onion |
||
Non- Flavonoids |
Phenolic acids |
Cloves |
|
Terpenes |
Limonene |
Fenugreek, Mustard |
|
Vanilloids |
Curcumin |
Turmeric, Ginger |
|
Organosulphur compound |
Disulfides, Thiosulfinates |
Garlic, Onion |
These bioactive components are responsible for antimicrobial action including degradation of the cell wall, disruption of the cytoplasmic membrane, leakage of cellular components, and destruction of protein2. Figure 1 shows scanned electron microscopic (SEM) images of the effect of spice extract on Bacillus cereus and E.coli.
Antimicrobial properties of spices and herbs
Numerous studies have shown that cinnamon, which is the world’s most frequently consumed spice and has been granted generally recognised as safe (GRAS) status, is rich in bioactive compound such as cinnamaldehyde that possesses antimicrobial effects1,14.
Tiwari et al.[15] reported that antimicrobial efficacy of spices extracts depends upon their chemical profile and concentration of bioactive components. Studies have shown that antimicrobial effects of essential oil extracts from spices and herbs have comparable effects to synthetic additives but their applications in the food industry has been limited due to their inherent characteristics, such as strong odour, flavour, aroma and relatively high cost1. Research on essential oils of spices and herbs over the past few years are listed in Table 3.
Table 3 Research into essential oils of plant antimicrobials (spices and herbs) over 20 years
Spices and herbs |
Applications |
Effective against |
Reference |
Oregano, thyme, coriander |
Effective antimicrobial components in essential oils (EOs) use in food preservation, |
Enterobacteria, lactic acid bacteria, B. cereus, Pseudomonas spp; Bacillus cereus, Pseudomonas aeruginosa, E.coli, Listeria monocytogenes |
Almajano et al.[16] Gutierrez et al.[17] |
Cinnamon, cloves, cumin |
EOs showed strong antimicrobial effect, Food flavouring and preservation |
Staphylococcus aureus, Klebsiella pneumonia aeruginosa, E. coli; Bacillus cereus, L. monocytogenes, Pseudomonas fluorescens, Salmonella enteritidis |
Ceylan and Fung[18] Agaoglu et al.[19] Wei et al.9 |
Bay leaves, coriander, cinnamon, thyme |
Effective antimicrobial properties for pathogenic spoilage microorganisms |
Bacillus subtilis, E.coli, L. monocytogenes, Salmonella typhimurium, Staphylococcus aureus |
Burt5 Gutierrez et al.17 Bajpal et al.[20] |
Thyme, cinnamon, clove |
Effective essential oil components |
Bacillus cereus |
Davidson and Naidu[21] |
Future of antimicrobial agents in food
Studies showed that the addition of spice extracts could effectively retard microbial growth, reduce lipid oxidation, maintain or improve sensory attributes and extend the shelf life of food during storage1,5,[22]. Several studies showed that spice extracts have antimicrobial, antioxidant properties1,5. The bioactive components in spice extract could be relevant to use as natural antimicrobial alternatives to synthetic chemical preservatives in food safety and preservation.
With thanks to supervisors – Dr Tristan Dew, Dr Nessar Ahmed, Dr Daniel Anang, Department of Health Professions, Manchester Metropolitan University, UK.
References
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2. Witkowska, A.M., Hickey, D.K., Gomez, M.A. and Wilkinson, M (2013). ‘Evaluation of antimicrobial activities of commercial herb and spice extracts against selected food-borne bacteria.’ Journal of food research, 2 (4).
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