Current Status of Guava (Psidium Guajava L) Production, Utilization, Processing and Preservation in Kenya: A Review

Duke G. Omayio1*, George O. Abong’1, Michael W. Okoth1, Charles K. Gachuiri2 , Agnes W. Mwang’ombe3

1Department of Food Science, Nutrition and Technology, University of Nairobi. P.O. Box 29053-00625, Nairobi, Kenya.

2Department of Animal Production, University of Nairobi. P.O. Box 29053-00625, Nairobi, Kenya.

3Department of Plant Science and Crop Protection, University of Nairobi. P.O. Box 29053- 00625, Nairobi, Kenya

Corresponding Author Email: dukegekonge@yahoo.com

DOI : http://dx.doi.org/10.12944/CARJ.7.3.07

Article Publishing History

Received: 19-10-2019
Accepted: 02-12-2019
Published Online: 10-12-2019

Review Details

Plagiarism Check: Yes
Reviewed by: Dr. Tzatzani Thiresia-Teresa
Second Review by: Arturo Alvino
Final Approval by: Dr. R. Pandiselvam

Article Metrics

Views     PDF Download PDF Downloads: 2365

Google Scholar

Abstract:

The guava (Psidium guajava L.) tree is extensively grown in the tropical and sub-tropical regions of the world. It is quite resilient, highly productive, has high economic returns and requires minimal care. The fruit is very nutritious with a characteristic flavor and has a high demand internationally especially when processed into pulp, concentrates, ready to serve beverages, wines, as well as jams and jellies. Although Kenya has a favorable climate for guava farming, the fruit’s nutritional and economic potential remain highly underutilized due to low adoption of processing and preservation techniques in addition to limited research. This review focuses on guava production utilization, processing and preservation with emphasis on Kenya There has been progressive increase in the total acreage under guava farming with various varieties of guavas being produced. The country produces as much as 11,327 tons of guava fruits worth 1.1 million US dollars although the fruit is mainly cultivated for local consumption with minimal processing. Naturalized guavas from sprouts of randomly dispersed seeds are common across all the agroecological zones both in the wild and on farms except in the arid areas. The fruit is however, climacteric and has a high rate of perishability resulting to high postharvest losses when in season. Processing of guavas into commercial products can increase the fruit’s value, improve farmers’ household incomes and enhance their utilization. The guava value chain also remains highly underexploited and since it is a neglected crop, there is need for a multisectoral approach in order to exploit the nutritional and economic potential of the fruit.

Keywords:

Guava; Postharvest; Processing; Preservation; Kenya

Download this article as: 

Copy the following to cite this article:

Omayio D. G, Abong G. O, Okoth M. W, Gachuiri C. K, Mwang’ombe A. W. Current Status of Guava (Psidium Guajava L) Production, Utilization, Processing and Preservation in Kenya: A Review. Curr Agri Res 2019;7(3). doi : http://dx.doi.org/10.12944/CARJ.7.3.07

Copy the following to cite this URL:

Omayio D. G, Abong G. O, Okoth M. W, Gachuiri C. K, Mwang’ombe A. W. Current Status of Guava (Psidium Guajava L) Production, Utilization, Processing and Preservation in Kenya: A Review. Curr Agri Res 2019;7(3). Available from: https://bit.ly/36ob1BZ


Introduction

Guava, Psidium guajava L., is a small monoecious evergreen tree with a height of between 2 and 10 meters belonging to the Myrtaceae family.1 It is native to tropical areas of southern Mexico and Northern South America although guava trees have now been grown by many other countries having tropical and subtropical climates, therefore allowing production around the world.2 The genus Psidium (Myrtaceae) consists of about 150 genera and about 5000 species which are widely distributed in the American, Asian and African tropics.2 The fruit which matures in approximately 120 days after flowering, is fleshy with a characteristic smell and aroma, contains many seeds and can weigh up to 500g depending on the variety and the environment.1

The guava tree is quite resilient, highly productive, requires minimal care and has high economic returns.3 The guava is widely distributed owing to its potential to adapt well to various ecological conditions including wastelands and soils with much higher pH levels (8.6 to 9.6) and it exceeds most other fruit trees in productivity, toughness and adaptability as they are easily naturalized.4 The dispersion of guavas has successfully been through agents including birds, bats, man and other animals.4 Commercial guava production involves use of improved guava varieties through various techniques mainly propagations from seeds and vegetative propagations for commercial purposes.5 However, commercial guava cultivation in East Africa is limited6,7 with naturally growing guavas being the most common resulting to guavas with diverse morphological and genetic diversity.

Guava fruits are often consumed fresh but are also suitable for processing into jam, juice, nectar wine and fruit leather among other products.8 The fruit is highly nutritious and is a good source of vitamin C, vitamin A, carbohydrates, proteins, minerals, pectin, calcium and phosphorus among other nutrients and can therefore help fight malnutrition.9 Besides, the guava plant has been widely used in Central and South America, West and North Africa and some parts of South East Asia for treatment of various ailments including, gastrointestinal disturbances as well as applications in the cosmetic and dermatological industry 10,11

This review paper focuses on providing information on guava production, utilization, preservation and processing in relation to Kenya based on literature findings.

Guava cultivation in Kenya

Fruit production including guavas in Kenya is mainly carried out by farmers with insufficient resources highly hindering fruit species experimentation and diversification.12 Various varieties of red/pink fleshed, white fleshed and strawberry guava with diverse morphological and genetic diversities grow in Kenya due to the different agro-ecological zones in the country.7,13–15

Naturalized guava cultivation is quite common in rural areas across all the agro-ecological regions both in the wild and on farms except in the arid areas.16 The guava trees grow widely with minimal care from sprouts of randomly dispersed seeds according to the Horticultural Crops Directorate (HCD, Kenya). There has been increased guava production over the years in the country according to HCD data.7,17 The total acreage under guava farming was estimated to be 1260 – 1806 Ha between 2014 to 2016 and a projected increase in production in the subsequent years. The total production was estimated at over 9800 – 11,327 tons. However due to low economic value, the guava prices have poor returns to farmers resulting to high post-harvest losses. The guava value chain therefore remains widely untapped despite its nutritional significance and economic potential.18

Guavas in Kenya are mainly consumed at household level and there is limited research and development aimed at domesticating and commercialization of the fruit which have hindered the establishment and improvement of structured guava value chains in Kenya.7,19 Furthermore, there are scattered and conflicting information on the guava production as well as very limited documentation on the development programs for the crop.19 There is also limited information on guava production for consumption and commercial purposes as well as lack of documentation of known guava plantations in Kenya.7 Moreover, the guava varieties and their performance in the country are yet to be profiled as very minimal studies related to the crop have been conducted. Consequently, the climatic, soil and agronomic conditions for optimum guava cultivation as well as guava post-harvest processing technologies in the country7 are not documented.

Sub-Saharan Africa Kenya included is characterized by significantly high rates of micronutrients deficiencies and malnutrition due to limited access and utilization of fruits and vegetable and as well as relatively high level of poverty leading to food and nutritional insecurity especially in the rural areas.20,21 Moreover, there are high postharvest losses as adoption of postharvest technologies remains low therefore contributing to increased poverty and hidden hunger.20 Guava value addition in Kenya remains extremely low and therefore there is need for a structured system for policy formulation focused on its trade with an aim of reducing the post-harvest losses, increase employment opportunities as well as maximization of the fruits’ value to farmers.19 Value addition through new products development while ensuring minimal destruction of nutrients is essential so as to combat malnutrition especially during the harsh weather conditions and can generate income that can be utilized to meet household food security for the farmers’ through commercialization of guava fruits and the processed products.

Nutritional Properties of Guava

Guava (Psidium guajava) fruit is often consumed fresh.22 The fruits are berries consisting of fleshy pericarps and seed cavities with fleshy pulps and numerous small seeds.23 The fruit contains high levels of vitamin C (up to 228.3 mg/100 g, fresh weight) with the highest concentration in the unpeeled fruits.24 Guavas also contain significant levels of essential oils, phenols, triterpenes, flavonoids, saponins, lectins, fiber and fatty acids as well as pectin.25 Furthermore, the fruits have considerable levels of minerals including phosphorus, calcium, iron and vitamins such as niacin, pantothenic acid, thiamin, riboflavin and vitamin A (Table 1).25–27

Guavas are rich in both carotenoids and polyphenolic compounds which give the fruit its antioxidative pigments making the fruit among the highest in antioxidation values.28 The pigments are responsible for the fruit’s skin color as well as that of its flesh. As such, the red-orange colored guavas have been found to contain high levels of the polyphenolic constituents, high carotenoids and pro-vitamin A substances and retinoids compared to the yellow–green colored varieties.29

The guava fruits also contains other constituents that have been shown to have various health benefits including, oxalic and malic acids, saponin combined with oleanolic acid among other polyphenolic compounds including; morin-3-O-α-L-lyxopyranoside and morin-3-O-α-L-arabopyranoside, flavonoids, guaijavarin and quercetin.27

Table 1: Food value of Psidium guajava fruit

Nutrient Value per 100 g Fresh weight Basis

Proximates

Water

80.8 g

Energy

68 kcal

Protein

2.55g

Total lipid (fat)

0.95g

Carbohydrate, by difference

14.32g

Fiber, total dietary

5.4g

Sugars, total

8.92g

Minerals

Calcium, Ca

18mg

Iron, Fe

0.26mg

Magnesium, Mg

22 mg

Phosphorus, P

40 mg

Potassium, K

417 mg

Sodium, Na

2 mg

Zinc, Zn

0.23 mg

Vitamins

Vitamin C, total ascorbic acid

228.3 mg

Thiamin

0.067 mg

Riboflavin

0.04 mg

Niacin

1.084

Vitamin B-6

0.11 mg

Folate, DFE

49 µg

Vitamin A, RAE

31 µg

Vitamin A, IU

624IU

Vitamin E (alpha-tocopherol)

0.73mg

Vitamin K (phylloquinone)

2.6

Lipids

Fatty acids, total saturated

0.272

Fatty acids, total monounsaturated

0.087

Fatty acids, total polyunsaturated

0.401

Adapted from USDA, 30

The findings by Chiveu, (2018)14 on Kenyan guavas showed significantly low levels of vitamin C compared to the USDA data (Table 1) ranging from 83-147 mg/100 g of fresh fruit. The mineral composition also varied significantly with some varieties extremely low or high as compared to the USDA data. The white-fleshed guavas generally had much more phosphorous, magnesium, sodium, and boron compared to the red-fleshed varieties.14 These variations were may be attributed to the climatic conditions and the fruits’ morphological traits31,32 as well as the maturity levels and the agricultural practices.33,34 There is need therefore for further research on the nutritional composition of Kenyan guavas and factors influencing the nutrient contents.

Health benefits of guavas

The guava plant’s leaves and the bark have been widely used in the treatment of various ailments.26 They possess phytochemicals and natural antioxidants that have been shown to counter chronic diseases as they possesses anticancer and antidiabetic properties and therefore reduce risks of contacting and developing Alzheimer’s disease, age-linked diseases, prevent liver injuries and cataracts due to their antioxidative and anti-inflammatory properties.35,36 Moreover, the fruit has hepatoprotective effects37,38 while the leaf extracts have been used for years to treat various disease in ethnomedical practices due to their high levels of flavonoids mainly quercetin.27 These include diarrhea, nephritis, stomachache, wounds, anorexia, cerebral ailments, jaundice, dermatitis, epilepsy and hysteria among others 26 (Table 2). The use of guava in ethnomedical practices in Kenya however remains unknown or if it has been practiced, there seems to be no recorded literature on the same.

 Table 2: Ethnomedical uses of the guava across the world

Country Usage

Amazonia

For diarrhea, dysentery, menstrual disorders, stomachache, vertigo26

Brazil

For anorexia, cholera, diarrhea, digestive problems, dysentery, gastric insufficiency, inflamed mucous membranes, laryngitis, mouth (swelling), skin problems, sore throat, ulcers, vaginal discharge39

Cuba

For colds, dysentery, dyspepsia, diarrhea and hypertension40

Ghana

Coughs, diarrhea, dysentery, toothache41

Haiti

For dysentery, diarrhea, epilepsy, itch, piles, scabies, skin sores, sore throat, stomachache, wounds26

India

For anorexia, cerebral ailments, childbirth, chorea, convulsions, epilepsy, nephritis, jaundice.26

Malaya

For dermatitis, diarrhea, epilepsy, hysteria, menstrual disorders

Mexico

For deafness, diarrhea, itch, scabies, stomachache, swelling, ulcer, worms, wounds42

Peru

For conjunctivitis, cough, diarrhea, digestive problems, dysentery, edema, gout, hemorrhages, gastroenteritis gastritis, lung problems, PMS, shock, vaginal discharge, vertigo, vomiting, worms.26

Philippines

For sores, wounds and as an astringent43

Trinidad

For bacterial infections, blood cleansing, diarrhea, dysentery 44

 

The use of guava in medicinal practices has been studied by several other researchers on various diseases and it has shown potential for treatment of most illnesses across the world.45 The ethnopharmacological assessments, laboratory studies and clinical trials have shown that the guava is effective in the treatment of these ailments.40 Furthermore, the toxicity assessments of the plant’s roots, bark, leaves, fruits, flowers and seeds have been found to be safe for medicinal purposes for both oral and topical uses if administered in infusions and decoction forms.46 However, further research needs to be conducted in order to isolate functional ingredients that can be used in developing of drugs and other therapeutic products.45,47

Post-harvest losses of guava fruit

The guava fruit is a climacteric with a high rate of perishability.48 The main post-harvest losses in fruits occur through physiological processes due to wilting, shriveling and chilling injuries, pathologically as a result of fungi and bacterial attacks, and physically through mechanical injuries.49 Losses have been estimated at 20 to 40% in developing countries as compared to about 10 to 15% in developed countries, depending on the crop involved and the season.49–51

Guavas, like other fruits have quantitative and qualitative post-harvest-losses occurring at all stages from harvesting, through handling, packaging and transportation, post-harvest storage and during marketing.52 However, application of proper postharvest practices can help reduce this (Table 2). About 20-25% of guava fruits are damaged and unfit for consumption before they reach the consumers.53 It is therefore critical that development of affordable processing technology for guava are adopted.54 The guava post-harvest losses in Kenya remain unaccounted for. This may be attributed to the fruit not being considered as important compared to others such as mangoes and avocadoes.7 Furthermore, farmers rarely plant the guava fruit as an income generator compared other fruit trees.

Table 3: Post harvest losses reduction strategies for fruits

Stage Recommended handling

Harvesting

Careful handling during harvest to reduce bruising, scratching and punctures;
harvesting during the cooler hours of the day (e.g. the early morning); shading crops once harvested to remove field heat.

Handling

Protecting the crops from injury can minimize pest attacks and physiological and
dehydration damage.

Sorting and
Cleaning

Sorting and cleaning can increase shelf-life considerably. By separating higher and lower quality crops, the risk that fungi or bacteria spread form damaged crops to others is reduced. Quality parameters like size and color can be determined through the use of visual charts, and allows the crops to be targeted to appropriate markets to maximize revenue.

Packaging

Proper packaging to maintain freshness prevents quality deterioration as well as acting protecting against physical damage during transportation. Clean, smooth and ventilated containers are key, but the specific type depends on the crop.

Transportation

Use of clean, cool, ventilated and covered vehicles for the transport of perishable crops with transport during the colder hours of the day advised. The smoothness of the road is also important as excessive vibrations and movement can degrade crop quality. Avoid watering the produce before transport as this increases decay. Care during loading and unloading is a simple yet effective way to reduce loss.

Storage

Only crops that meet specific quality standards should be stored (correct level of
maturity, undamaged). Optimal temperatures for each commodity should be known and used as shelf-life is longer when stored in optimal temperature conditions.

Processing

Processing allows producers to stabilize the produce, diversify the food supply for enhanced nutrition throughout the year, and generates employment.

Adapted from Kiaya, 2014 55

The rate of guava deterioration is influenced by various external environmental factors that the harvested guavas are exposed to including, ambient temperatures, relative humidity , air speed and the atmospheric air composition (the ratio of carbon dioxide, ethylene and oxygen) as well as the hygienic conditions of storage area.49 On average, fresh guavas last for about 3 – 10 days but if some of these factors are controlled, the fruits can last 2 -11 more days depending on the varieties and methods used.25,56–58

Guavas undergo high respiration rates and subsequent post-harvest ripening which leads to the fruit perishability.48 The rate of guava perishability has however been shown to reduce significantly when guavas are packaged in modified forms. Rana et al.,25 reported that storage of guavas at 7 ± 3°C after shrink and cling wrapping using polythene bags (LDPE) reduced the ripening rates and the physiological weight losses and increased the shelf life by up to 15 days.

The use of salts such as calcium chloride and calcium nitrates has been found to extend the guava freshness as well.59 This is due to the counteractive effect on ethylene, therefore decreasing the ripening rates and extending the guava life by up to 12 days while storing the fruits at room temperatures. The use of salicylic acid at low concentrations have also been shown to effectively reduce the rate of guava degradation60 while application of antioxidants such as benzyl adenine have similarly increased the guava shelf life by upto 14 days during storage.61

Freeze-drying of guavas and guava pulp has been used to preserve the fruits.62–64 The technique has been found to be the most appropriate method for drying products especially fruits and vegetable that are highly sensitive to heat.62 Unlike in conventional drying, freeze drying is carried out at low temperatures (-20 to -50oC) that minimizes the shrinking and degradation reactions resulting to products with superior quality.62,63

In Kenya and the sub-Saharan Africa in general, postharvest losses are caused by many factors and come in different forms.65 Pre-harvest factors such as disease and insect infestation are the major causes.66,67 Other factors that highly influence post-harvest losses are; bad and inexperienced handling of fruits, poor packaging methods which may lead to physical damages and high temperatures which lead to moisture losses. Furthermore, delayed marketing and poor market distribution strategies which extend the time between harvesting and consumption have often been shown to contributes to postharvest losses as well.65

There has been limited research on the post-harvest losses of guavas in Sub-Saharan Africa due to limited processing but the losses have been shown to be as much as 49% as they are not considered to be major fruits.7,68 The actual postharvest losses of guavas in Kenya however may be extremely high as there is no structured value chain for the locally produced fruits due to lack of marketing and processing.

Guava Value Addition

The guava has great potential for extensive commercial use because of its ease of cultivation, high nutrient content and ease of processing into various industrial products.69 There are many products which can be obtained from processing guavas including guava pulp, jam, juice, jelly chocolates, wine and guava powder (which is mostly used in preparation of yogurt)3 and spray dried soluble guava extracts containing high concentration of antioxidants.3,70

Some of the commercial products from guava include;

i) Guava pulp

Processing of guavas into pulp provides a convenient form of guava fruits preservation.71–73 The guava pulp can best be preserved by addition of potassium metabisulphite at low concentrations (0.005 – 0.2%) and storing at low temperatures (2-5oC) to avoid nutrient breakdown.73 The pulp is easily processed into other products such as juices, ready to drink beverages, guava nectars and guava leather71–73 and can be stored for up to 90 days at 2-5oC.71

The process of extraction of the fruit pulp plays a critical role as it determines the quality and yields of the final product.74 Cold or hot methods can be used for extraction of pulp.3,74 Hot methods involve a preheating stage in which fruits are blanched before extraction using hot water or steam.74 Although the hot methods result to high extraction yield, there is usually browning and off flavors which affects the quality of the end product. On the other hand, cold methods involve pulping of clean fruits without preheating resulting to higher quality pulp although lower yields compared to the hot methods. Pulp can be prepared using either peeled on unpleed guavas.3 Peeling of guavas could be through lye peeling using diluted sodium hydroxide (NaOH) or hand peeling although the former is preferable as the product is uniformly peeled and results to higher pulp yield.74,75 The fruits are then pulped using blenders at household levels or pulpers at the industrial scale after which sieving or straining using muslin clothes or 1 mm stainless steel meshes to remove the seeds.74,76

ii) Blended ready to serve beverages

The guava fruit pulp has been used in preparation of different blended, ready to drink beverages by use of various ratios with other fruits such anola, papaya and pineapples.77 According to Jakhar et al.,78 blending of guava pulp with other fruit pulps has been found to improve the product appearance, nutritional value and enhances the flavors of the resultant products.

iii) Dehydrated guava products

Drying preserves fruits through reduction of the moisture content which inhibits growth of microorganisms and prevents enzymatic reactions.79 There are various drying methods including sun and solar drying which result to contaminated and poor quality products as compared to products obtained through osmotic dehydration, vacuum, freeze and spray drying techniques.80

Dehydrated guava slices can be obtained by drying under direct sunlight.81 Although this method is the cheapest in preservation, it has been found to cause up to 84% losses in the heat labile nutrients such as ascorbic acid and the water soluble vitamins such as thiamine and niacin therefore limiting its application as a suitable preservation method.81–83

Osmo-dried guava slices are made from guavas of about 1.5cm thickness dipped in sugary syrups containing 0.05% potassium metabisulphite and citric acid.84,85 These lead to decrease in the moisture content and increases solid and sugar levels that have preservative effects. The method has minimal effect on the appearance of the guava slice, their texture as well as the flavor

iv) Guava jams and jellies

Guava jam is produced by cooking of pulp after addition of sugar , jellifying substances and other suitable additives to achieve desired consistency.86 The jam should correspond to 65- 68o Brix after which it is hot filled into cleaned and sterilized glass jars.87 Guava jellies are processed from fruits that are slightly ripe. The fruits are cut into small pieces and boiled for about 45 minutes using equal amount of water at low temperatures and the juice extracted by filtration using strainers or clean muslin clothes.88 Further processing involves addition of sugars to the extracted juice after which the mixture is boiled to 105C or formation of a sheet when a small portion is cooled off in a spoon.87 The amount of sugar used depends on the pectin levels of the extracted juices and it ranges from 0.5 kg sugar/kg juice to 0.75 kg sugar/kg juice for pectin-rich juice and low-pectin juices respectively.87 This is followed by hot filling into clean and sterilized jars.

v) Guava juice and nectars

The guava juices are prepared from either fresh fruits or the guava pulp. Juice is extracted by squeezing the guava fruits through hydraulic filter press or from the pulp after dilution with water and subsequent filtration.8 The juice is usually not clear and may require use of pectic enzymes for clearer juices that are easily filtered.8 Studies by Imungi,89 showed optimized conditions for the extraction of guava juice using proteolytic enzymes from the Kenyan guavas to be 400ppm of enzyme, at a temperature of 45-50oC for 90 minutes.

Nectars are obtained by addition of water to guava pulp or fresh juice.90 Permitted additives or sweeteners as well as sugar may or may not be added but the products must have a minimum of 8.5° Brix, 25.0% of the guava puree or juice and acidity of 0.15% at a pH of 3.4 – 4.8,90 Currently there are some guava juice products in the Kenyan markets although the guava used in processing are imported.18,91 Besides, information on the nutritional quality and safety of these local products is not available and therefore a need for a study to be conducted.

Guava juices or nectars can also be blended with other juices in order to boost their nutritional values. Various blended guava nectars have been developed by other researchers 3,72,92,93 who have reported that blending improves the product acceptability, enhances the nutritional content and increases the product stability therefore longer shelf life for the nectars.

The evaluation of the feasibility for commercialization of processed guava from locally procured fruits in Kenya is yet to be conducted. Processing guavas is easily achievable even at the household levels and farmers should be educated on affordable technologies that can help minimize the fruits postharvest losses. It is however critical that during processing, care is taken such that the techniques used to produce products are nutritionally, organoleptically and functionally preservative in order to ensure minimal damage on the nutrient.

Effects of Different Processing Methods on Guava Fruit Nutrients

Processing of guava into various products significantly affects the nutrient contents of the fruit. These include reduction of the heat labile nutrients such as vitamin C which may reduce by as much 50% and above94 depending on the intensity and time of exposure to heat. The carbonyl compounds that give the fruit its characteristic aroma as well as other phytochemical degeneration have been shown to occur and are attributed to the enzymatic activities due to exposure to light and oxygen.94,95 Besides, cutting of guavas also promotes ethylene production which accelerates the senescence processes and higher oxidase activities as well as lipoxygenase enzyme activity leading to fatty acids and carotenoids oxidation.95

Losses of ascorbic acid have been shown to occur by as much as 20.4% and 62.5% during juice and jam processing respectively,96 63% loss in vitamin C and 61.9% in lycopene during nectar manufacture.97 Drying increases the guava shelf life with minimal degradation of the fruit’s mineral and antoxidant activities.98 However, freeze drying has been shown to have the least effect on guava dehydration as it has minimal effects on the nutrient content levels as well as the fruits’ natural color, flavor and aroma although the method is quite costly.83,99,100

There are currently no data on the nutrient contents of processed guava products in the Kenyan markets and these calls for a need on conducting studies on them so as to ascertain the extent of nutrient degradation in processed guava products.

Processing of Guava Wastes

Processing of guavas into various products results to wastes including seeds, stone cells and fibrous tissues from the skin are generated especially during pulping .These make about 25% and are suitable for processing into animal feeds and other products.101,102 Guava wastes have been found to contain high levels of crude fiber (as much as 61%), significant quantities of ether extracts (mainly oleic and linoleic acids) and 1,336 kcal/kg – 1,808 kcal/kg metabolizable energy values.103,104 The minerals, including zinc, iron, potassium, phosphorus and manganese are also present in significant levels in guava seed meal.105 Guava wastes can be processed into value added food products as well, including pectin , dietary fibre that is obtained from ground dried wastes and powder which can be supplemented in bakery products to boost the dietary fiber and use of the waste as substrate in fermentation for ethanol production.106

Incorporation of guava wastes in broiler chicken feeds has been shown to improve the carcass yields107 while Farid and Kamel108 have shown that inclusion of about 20% of guava wastes in feeds can effectively be used without interfering with the animals health, their performance and digestibility and has got insignificant effect on the carcass quality. The use of guava wastes as rabbit feed or inclusion in their diets has been found to economize on the costs of feed and positively enhances the growth and health of rabbits with minimal interference in their digestion and the carcass quality.109 Therefore guava wastes could be processed into commercial products and thus help reduce the pollution from dumping the wastes.

The estimated wastes produced from the Kenyan industries processing guavas have not been documented. There is need therefore for promoting guava processing and assessing the suitability of processed guava wastes from the Kenyan cultivars,

Conclusion

The guava fruit’s nutritional and economic potential remain unexploited in Kenya. More research on the factors limiting its full exploitation needs to be done. Although the Kenya Agricultural & Livestock Research Organization (KALRO))has been in the forefront in promoting guava production through provision of guava seedlings to farmers,18 a multisectoral approach from the other government bodies, policy makers, farmers, processors and researchers should be set up in order to promote guava production and processing. It is worth noting that guava production can be produced in most counties across the country and therefore there may be need on educating farmers on the fruit’s potential. Furthermore, the involved authorities should be in the forefront in providing farmers with the high quality guava seedlings, carrying out extension services on proper agronomic practices for guavas and establishing marketing channels just like with other fruits such as mangoes. Besides, simple processing and preservation techniques that can be done at household levels can be promoted through farmer education groups in order to minimize the fruits postharvest losses while the government could also intervene in order to ensure that fruit processors in the country also produce and market guava products from locally sourced guava fruits.

Acknowledgement

The authors would like to acknowledge the FruVaSE Project for awarding grants for this study through the University of Nairobi.

Funding

This work was funded by fruits and vegetables for all seasons (FruVase) Project. Research grant no – 2816PROC04.

Conflict of Interest

The authors declare no conflict of interest.

References

  1. Patel RK, Maiti CS, Deka BC, Deshmukh NA, Roy D. Variability Studies in Guava ( Psidium guajava L .) Genotypes for Growth , Yield and Quality Attributes at Mid-hills of Meghalaya. Indian J Hill Farming. 2011;24(1):25-29.
  2. Salazar DM, Melgarejo P, Martínez R, Martínez JJ, Hernández F, Burguera M. Phenological stages of the guava tree (Psidium guajava L.). Sci Hortic (Amsterdam). 2006;108(2):157-161. doi:10.1016/J.SCIENTA.2006.01.022
  3. Kadam M, Kaushik P, Kumar R. Evaluation of Guava Products Quality. Int J Food Sci Nutr Eng. 2012;2(1):7-11. doi:10.5923/j.food.20120201.02
  4. Gautam NN, Singh K, Singh B, Seal S, Goel A, Goel VL. Studies on clonal multiplication of Guava (Psidium guajava L.) through cutting under controlled conditions. Aust J Crop Sci. 2010;4(9):666-669.
  5. Pereira FM, Usman, Muhammad, Newton Alex Mayer , Jair, Costa Nachtigal, Oscar, Ranny Mbongeni Maphanga SW. Advances in guava propagation. Rev Bras Frutic. 2016;39(4):1-24. doi:10.1590/0100-29452017
  6. Omurungi SM. Guavas: Common in homesteads but hardly on the market – Daily Monitor. Daily Monotor. https://www.monitor.co.ug/Magazines/Farming/Guavas–Common-in-homesteads-but-hardly-on-the-market/689860-1402522-1jr0bcz/index.html. Published 2012. Accessed October 6, 2018.
  7. HCD. Horticulture Validated Report. Agriculture, Fisheries and Food Authority (AFFA), horticulture performance report. http://www.agricultureauthority.go.ke/wp-content/uploads/2016/05/Horticulture-Validated-Report-2014-Final-copy.pdf. Published 2014.
  8. Kumari, K. Usha, Rishitha, G., Prasad, K. Rajendra, Kumar PS. Value added products of guava. Agric Updat. 2017;12:2171-2177. doi:10.15740/HAS/AU/12.TECHSEAR(8)2017/2270-2276.K
  9. Youssef M. Molecular markers associated with high Vitamin-c content in guava. JAgricChem.and Biotechn, Mansoura Univ. 2016;7(3):49-55.
  10. Chiari-andréo B, Trovatti E, Marto J, et al. Guava : phytochemical composition of a potential source of antioxidants for cosmetic and / or dermatological applications. 2003.
  11. Morais-Braga MFB, Carneiro JNP, Machado AJT, et al. Psidium guajava L., from ethnobiology to scientific evaluation: Elucidating bioactivity against pathogenic microorganisms. J Ethnopharmacol. 2016;194(November):1140-1152. doi:10.1016/j.jep.2016.11.017
  12. Mbora A, Jamnadass R, Lillesø JB. Growing High Priority Fruits and Nuts in Kenya:Uses and Management. The World Agroforestry Centre, United Nations Avenue; 2008.
  13. Gatambia, E. K., Gitonga, J. K., Menza M. K., Njuguna, J. K., Wanjala, S. B., Karumwa N., Wasilwa LA. Situation analysis of guava (Psidium guajava L) production in Eastern Province of Kenya. In: Kenya Agricultural Research Institute 12th Biennial Scientific Conference. ; 2010.
  14. Chiveu J. Assessment of genetic and nutritional diversity, and salinity tolerance of Kenyan guava (Psidium guajava L.): an underutilized naturalized fruit species. 2018.
  15. Kidaha L, Alakonya A, Nyende A. Morphological Characters of Guava landraces in Western and Coastal Kenya. Am J Exp Agric. 2015;9(6):1-11. doi:10.9734/AJEA/2015/12674
  16. Chiveu J, Naumann M, Pawelzik E, Kehlenbeck K. Morphological Diversity of the Underutilised Fruit Species Guava ( Psidium guajava L .) in Kenya. In: Tropentag, 2016. Vienna, Austria; 2016:1.
  17. HCD. Horticulture Validated Report 2015-2016. Agriculture and Food Authority (AFA), Data validation report. https://www.agricultureauthority.go.ke/wp-content/uploads/2016/09/Horticulture-2015_2016-Validated-Report3.pdf. Published 2016.
  18. Oyugi Z. KALRO gives Busia farmers 55,000 free guava, gooseberry and jack fruit seedlings. http://farmbizafrica.com/advertise/10-profit-boosters/2054-kalro-givers-busia-farmers-55-000-free-guava-gooseberry-and-jack-fruit-seedlings. Published 2018. Accessed October 6, 2018.
  19. Wasilwa LA, Wayua F, Wasilwa T, Wasike VW, Omari F, Ndungu J. Preferences of Guava (Psidium Guajava L.) Types amongst School Children in Western Kenya.; 2018.
  20. Armachius J, Vumilia Z. Postharvest management of fruits and vegetable : A potential for reducing poverty , hidden hunger and malnutrition in sub-Sahara Africa. Cogent Food Agric. 2017;66:1-13. doi:10.1080/23311932.2017.1312052
  21. Vinceti B, Termote C, Ickowitz A, Powell B, Kehlenbeck K, Hunter D. The contribution of forests and trees to sustainable diets. Sustain. 2013;5(11):4797-4824. doi:10.3390/su5114797
  22. Marquina V, Araujo L, Ruiz J, Rodriguez-Malaver A, Vit P. Composition and antioxidant capacity of the guava (Psidium guajava L.) fruit, pulp and jam. Arch Latinoam Nutr. 2008;58(1):98-102.
  23. Jiménez-Escrig A, Rincón M, Pulido R, Saura-Calixto F. Guava fruit (Psidium guajava L.) as a new source of antioxidant dietary fiber. J Agric Food Chem. 2001;49(11):5489-5493. doi:10.1021/jf010147p
  24. Yan LY. Antioxidant Properties of Guava Fruit: Comparison With Some Local Fruits. Sunw Acad J. 2006;3:9-20.
  25. Rana S, Siddiqui S, Goyal A. Extension of the shelf life of guava by individual packaging with cling and shrink films. J Food Sci Technol. 2015;52(12):8148-8155. doi:10.1007/s13197-015-1881-5
  26. Kamath J, Rahul N, Kumar CA, Lakshmi S. Psidium guajava L: A review. Int J Green Pharm. 2008;2(1):1-6. doi:10.22377/IJGP.V2I1.386
  27. Das AJ. Review on nutritional, medicinal and pharmacological properties of guava (Psidium guajava Linn). J Biol Act Prod from Nat. 2011;1(4):216-228. doi:10.1080/22311866.2011.10719089
  28. Jiménez-Escrig A, Rincón M, Pulido R, Saura-Calixto F. Guava Fruit (Psidium guajava L.) as a New Source of Antioxidant Dietary Fiber. J Agric Food Chem. 2001;49(11):5489-5493. doi:10.1021/jf010147p
  29. Rojas-Garbanzo C, Gleichenhagen M, Heller A, Esquivel P, Schulze-Kaysers N, Schieber A. Carotenoid Profile, Antioxidant Capacity, and Chromoplasts of Pink Guava (Psidium guajava L. Cv. ’Criolla’) during Fruit Ripening. J Agric Food Chem. 2017;65(18):3737-3747. doi:10.1021/acs.jafc.6b04560
  30. USDA. National Nutrient Database for Standard Reference Release Legacy April , 2018 full report (All nutrients ) 09139,Guavas, common, raw. National Nutrient Database. https://ndb.nal.usda.gov/ndb/foods/show/09140. Published 2018.
  31. Chiveu J, Naumann M, Kehlenbeck K, Pawelzik E. Variation in fruit chemical and mineral composition of Kenyan guava ( Psidium guajava L .): Inferences from climatic conditions , and fruit morphological traits. 2019;159(November 2015):151-159. doi:10.5073/JABFQ.2019.092.021
  32. Ferreira JEM, Rodriguez-Amaya DB. Degradation of lycopene and beta-carotene in model systems and in lyophilized guava during ambient storage: kinetics, structure, and matrix effects. J Food Sci. 2008;73(8):C589-94. doi:10.1111/j.1750-3841.2008.00919.x
  33. Bakshi P. Maturity indices of Guava. Agric Sci. 2015;(January 2014):18.
  34. Río Segade S, Soto Vázquez E, Díaz Losada E. Influence of ripeness grade on accumulation and extractability of grape skin anthocyanins in different cultivars. J Food Compos Anal. 2008;21(8):599-607. doi:10.1016/j.jfca.2008.04.006
  35. Conway P. Tree Medicine: A Comprehensive Guide to the Healing Power of over 170 Trees. London: Judy Piatkus (Publishers) Limited; 2001.
  36. Peng J, Yue C, Qiu K, et al. Protective Effects of Guava Pulp on Cholestatic Liver Injury. ISRN Hepatol. 2013;2013:1-11. doi:10.1155/2013/601071
  37. Rai PK, Mehta S, Watal G. Hypolipidaemic & hepatoprotective effects of Psidium guajava raw fruit peel in experimental diabetes. Indian J Med Res. 2010;131:820-824.
  38. Rai PK, Jaiswal D, Mehta S, Watal G. Anti-hyperglycaemic potential of Psidium guajava raw fruit peel. Indian J Med Res. 2009;129(5):561-565.
  39. Holetz FB, Pessini GL, Sanches NR, Cortez DAG, Nakamura CV, Dias Filho BP. Screening of some plants used in the Brazilian folk medicine for the treatment of infectious diseases. Mem Inst Oswaldo Cruz. 2002;97(7):1027-1031. doi:10.1590/S0074-02762002000700017
  40. Daswani PG, Gholkar MS, Birdi TJ. Psidium guajava: A Single Plant for Multiple Health Problems of Rural Indian Population. Pharmacogn Rev. 2017;11(22):167-174. doi:10.4103/phrev.phrev_17_17
  41. Gutiérrez RMP, Mitchell S, Solis RV. Psidium guajava: A review of its traditional uses, phytochemistry and pharmacology. J Ethnopharmacol. 2008;117(1):1-27. doi:10.1016/j.jep.2008.01.025
  42. Leonti M, Vibrans H, Sticher O, Heinrich M. Ethnopharmacology of the Popoluca, Mexico: an evaluation. J Pharm Pharmacol. 2001;53(12):1653-1669. doi:10.1211/0022357011778052
  43. Bonuel N. Perception of health and health practices of five Filipino elders. J Nurs Educ Pract. 2018;8(5). doi:10.5430/jnep.v8n5p68
  44. Word Health Organization W. Medicinal plants in the South Pacific : information on 102 commonly used medicinal plants in the South Pacific. Manila. In: WHO Regional Office for the Western Pacific. ; 1998:163.
  45. Díaz-de-Cerio E, Verardo V, Gómez-Caravaca AM, Fernández-Gutiérrez A, Segura-Carretero A. Health effects of Psidium guajava L. Leaves: An overview of the last decade. Int J Mol Sci. 2017;18(4):897. doi:10.3390/ijms18040897
  46. Morais-Braga MFB, Carneiro JNP, Machado AJT, et al. Psidium guajava L., from ethnobiology to scientific evaluation: Elucidating bioactivity against pathogenic microorganisms. J Ethnopharmacol. 2016;194:1140-1152. doi:10.1016/j.jep.2016.11.017
  47. Anand V, M M, Kumar V, Kumar S, P P, Hedina A. Phytopharmacological overview of Psidium guajava Linn. Pharmacogn J. 2016;8(4):314-320. doi:10.5530/pj.2016.4.3
  48. Rawan S, Bibi F, Khan N, et al. Postharvest Life of Guava (Psidium guajava L.) varieties as affected by storage intervals at room temperature. Pakistan J Agric Res. 2017;30(2):155-161.
  49. Kader AA. Increasing food availability by reducing postharvest losses of fresh produce. Acta Hortic. 2005;682:2169-2176. doi:10.17660/ActaHortic.2005.682.296
  50. Mpho M. Assessment of post harvest losses of fruits at Tshakhuma fruit market in Limpopo Province, South Africa. African J Agric Res. 2012;7(29):4145-4150. doi:10.5897/AJAR12.392
  51. Madrid M. Reducing postharvest losses and improving fruit quality worldwide: the one-billion-dollar untapped business opportunity. https://fruitprofits.com/new/reducing-postharvest-losses-and-improving-fruit-qualitworldwide:-the-one-billion-dollar-untapped-business-opportunity/12. Published 2011. Accessed November 17, 2018.
  52. Paltrinieri G. Handling of fresh fruits, vegetables and root crops. Food Agric Organ United Nations. 2014:35-39.
  53. Kanwal N, Randhawa MA, Iqbal Z. A Review of Production, Losses and Processing Technologies of Guava. Asian J Agric Food Sci. 2016;04(02):2321-1571.
  54. Nikhanj P, Kocher GS, Boora RS. Fermentative production of guava wine from pectinase treated and untreated juice of ‘punjab pink’ cultivar of Psidium guajava L. Agric Res J. 2017;54(2):244. doi:10.5958/2395-146X.2017.00044.8
  55. Kiaya V. Post-harvest losses and strategies to reduce them. J Agric Sci. 2014;149(3-4):49-57. doi:10.13031/aim.20152189434
  56. Pareek S, Kitinoja L, Kaushik RA, Paliwa R. Postharvest physiology and storage of ber. Stewart Postharvest Rev. 2009;5(5):1-10. doi:10.2212/spr.2009.5.5
  57. Gill KBS. Techniques for extending shelf life of guava fruits: A review. In: Acta Horticulturae. International Society for Horticultural Science (ISHS), Leuven, Belgium; 2018:959-969. doi:10.17660/ActaHortic.2018.1205.124
  58. Phebe D, Ong PT. Extending “Kampuchea” guava shelf-life at 27oC using 1-methylcyclopropene. Int Food Res J. 2010;17:63-69.
  59. Kumar R, Lal S, Misra KK. Effect of post harvest calcium treatments on shelf life of guava cv. Sardar. HortFlora Res Spectr. 2012;1(4):344-347.
  60. Biosci IJ, Amanullah S, Sajid M, Qamar MB, Ahmad S. Postharvest treatment of salicylic acid on guava to enhance the shelf life at ambient temperature. 2017;6655:92-106. doi:10.12692/ijb/10.3.92-106
  61. Jayachandran KS, Srihari D, Reddy YN. POST-HARVEST APPLICATION OF SELECTED ANTIOXIDANTS TO IMPROVE THE SHELF LIFE OF GUAVA FRUIT. In: Acta Horticulturae. International Society for Horticultural Science (ISHS), Leuven, Belgium; 2007:627-632. doi:10.17660/ActaHortic.2007.735.81
  62. Marques LG, Freire JT. Analysis of freeze-drying of tropical fruits. Dry Technol. 2005;23(9-11):2169-2184. doi:10.1080/07373930500212438
  63. Conceição MC, Fernandes TN, de Resende JV. Stability and microstructure of freeze-dried guava pulp (Psidium guajava L.) with added sucrose and pectin. J Food Sci Technol. 2016;53(6):2654-2663. doi:10.1007/s13197-016-2237-5
  64. Mahendran T. Physico-Chemical Properties and Sensory Characteristics of Dehydrated Guava Concentrate: Effect of Drying Method and Maltodextrin Concentration. Trop Agric Res Ext. 2011;13(2):48. doi:10.4038/tare.v13i2.3138
  65. Kitinoja L, Kader AA. Measuring postharvest losses of fresh fruits and vegetables in developing countries. The Postharvest Education Foundation. doi:10.13140/RG.2.1.3921.6402
  66. Kitinoja L, Saran S, Roy SK, Kader AA. Postharvest technology for developing countries: Challenges and opportunities in research, outreach and advocacy. J Sci Food Agric. 2011;91(4):597-603. doi:10.1002/jsfa.4295
  67. Sheahan M, Barrett CB. Food loss and waste in Sub-Saharan Africa: A critical review. Food Policy. 2017;70:1-12. doi:10.1016/j.foodpol.2017.03.012
  68. Hailu G, Derbew B. Extent, causes and reduction strategies of postharvest losses of fresh fruits and vegetables − A review. J Biol Agric Healthc. 2015;5(5):49-64.
  69. Gurvinder Singh Kocher. Status of wine production from guava (Psidium guajava L.): A traditional fruit of India. African J Food Sci. 2011;5(16):851-860. doi:10.5897/AJFSX11.008
  70. Kr Chauhan A. Determination of Antioxidant Capacity, Total Phenolics and Antimicrobial Properties of Spray-Dried Guava Extract for Value-Added Processing. J Food Process Technol. 2014;05(09). doi:10.4172/2157-7110.1000368
  71. Yadav SK, Sarolia DK, Pilania S, Meena HR, Mahawer LN. Studies on Keeping Quality of Preserved Guava Pulp during Storage. Int J Curr Microbiol Appl Sci. 2017;6(3):1235-1242.
  72. Kumari Y. STUDIES ON EFFECT OF BLENDING IMPACT OF GUAVA ( Psidium guajava L.) AND PAPAYA ( Carica papaya L.) PULP ON RECIPE STANDARDIZATION OF BLENDED NECTAR AND RTS (Ready to Serve) BEVERAGES. 2016.
  73. Correa MIC, Chaves JBP, Jham GN, Ramos AM, Minim VPR, Yokota SRC. Changes in guava (Psidium guajava L. var. Paluma) nectar volatile compounds concentration due to thermal processing and storage. Ciência e Tecnol Aliment. 2010;30(4):1061-1068. doi:10.1590/S0101-20612010000400035
  74. Tillett A, Kim D, Madison OMA. Fruit nectar as a refreshing beverage an overall review. Libr Resour Tech Serv. 2014;7654185763(July):47906. doi:10.1111/j.1469-0691.2011.03558.x/pdf
  75. Han B, Gu H, Liu S. Lye Peeling of Fruits and Vegetables. Shiyou Diqiu Wuli Kantan/Oil Geophys Prospect. 2018;53(2). doi:10.13810/j.cnki.issn.1000-7210.2018.02.010
  76. Bhuvaneswari S, Tiwari RB. Pilot scale processing of red flesh guava RTS beverage. J Hort Sci. 2007;2(1):50-52.
  77. Sarkar A, Bulo J. Standardization of Blending of Guava Pulp with Pineapple Juice for Preparation of Ready-To-Serve ( RTS ). Int J Curr Microbiol Appl Sci. 2017;6(11):395-401.
  78. Jakhar M.S., Vaish P.K. PS. Studies on the standardization and preservation of guava (Psidium guajava L.) and barbados cherry (Malpighia glabra L.) blended ready-to-serve beverage. J Progress Hortic. 2013;45(1):95-99.
  79. María L, Acosta V. Analysis of Nutritional and Functional Properties of Dry Guava 1 Análisis de las propiedades nutricionales y funcionales. 2014;18(1):159-175. doi:10.11144/Javeriana.IYU18-1.apnf
  80. Sagar VR, Suresh Kumar P. Recent advances in drying and dehydration of fruits and vegetables: A review. J Food Sci Technol. 2010;47(1):15-26. doi:10.1007/s13197-010-0010-8
  81. Ndawula J, Kabasa JD, Byaruhanga YB. Alterations in fruit and vegetable beta-carotene and vitamin C content caused by open-sun drying, visqueen-covered and polyethylene-covered solar-dryers. Afr Health Sci. 2004;4(2):125-130.
  82. Wojdyło A, Figiel A, Lech K, Nowicka P, Oszmiański J. Effect of Convective and Vacuum-Microwave Drying on the Bioactive Compounds, Color, and Antioxidant Capacity of Sour Cherries. Food Bioprocess Technol. 2014;7(3):829-841. doi:10.1007/s11947-013-1130-8
  83. Ali MA, Yusof YA, Chin NL, Ibrahim MN. Effect of different drying treatments on colour quality and ascorbic acid concentration of guava fruit. Int Food Res J. 2016;23:155-161.
  84. Sagar VR, Suresh Kumar P. PROCESSING OF GUAVA IN THE FORM OF DEHYDRATED SLICES AND LEATHER. In: Acta Horticulturae. International Society for Horticultural Science (ISHS), Leuven, Belgium; 2007:579-589. doi:10.17660/ActaHortic.2007.735.75
  85. da Silva WP, e Silva CMDPS, Farias Aires KLC de A. Description of Guava Osmotic Dehydration Using a Three-Dimensional Analytical Diffusion Model. J Food Process. 2014;2014:1-7. doi:10.1155/2014/157427
  86. Kanwal N, Randhawa MA, Iqbal Z. Influence of processing methods and storage on physico-chemical and antioxidant properties of guava jam. Int Food Res J. 2017;24(5):2017-2027. doi:10.1080/23311932.2016.1176287
  87. Sidhu JS. Tropical Fruits : Guava , Lychee , and Papaya. In: Handbook of Fruits and Fruit Processing. ; 2006:597-634.
  88. Kuchi VS, Gupta R, Gupta R, Tamang S. Standardization of recipe for preparation of guava jelly bar. J Crop Weed. 2014;10(2):77-81.
  89. Imungi JK. Physical and chemical changes taking place during extraction, concentration and storage of clarified guava juice. 1979.
  90. FAO. GENERAL STANDARD FOR FRUIT JUICES AND NECTARS. 2005:1-19.
  91. Ndemo B. The tragedy of buying fruit at the roadside. Daily Nation. https://www.nation.co.ke/oped/blogs/dot9/ndemo/2274486-3087408-p1p6aqz/index.html. Published 2016. Accessed June 23, 2019.
  92. Rani TB, Babu JD. Acceptability and storage studies of guava – Aloe nectar blends. Asian J Hortic. 2015;10(1):80-85. doi:10.15740/HAS/TAJH/10.1/80-85
  93. Mehta V, Delvadia D V, Galav A, Sharma AK. Standardization of Processing Technology for Guava / Blended Guava ( Psidium guajawa L .) Ev . Lucknow – 49 Ready-To-Serve Beverage. Int J Adv Sci Res Manag. 2018;(1):184-187.
  94. Dweck AC. A review of Guava (Psidium guajava). Malayan J Med Sci. 2001;8(1):27-30.
  95. Hussein A, Odumeru J., Ayanbadejo T, et al. Effects of processing and packaging on vitamin C and β-carotene content of ready-to-use (RTU) vegetables. Food Res Int. 2000;33(2):131-136. doi:10.1016/S0963-9969(00)00027-2
  96. Jawaheer B, Goburdhun D, Ruggoo A. Effect of processing and storage of guava into jam and juice on the ascorbic acid content. Plant Foods Hum Nutr. 2003;58(3):1-12. doi:10.1023/B:QUAL.0000041161.05123.66
  97. Ordóñez-Santos LE, Vázquez-Riascos A. Effect of processing and storage time on the vitamin C and lycopene contents of nectar of pink guava (Psidium guajava L.). Arch Latinoam Nutr. 2010;60(3):280-284.
  98. Patel P, Sunkara R, Walker LT, Verghese M, Patel P. Effect of Drying Techniques on Antioxidant Capacity of Guava Fruit. Food Nutr Sci. 2016;7(7):544-554. doi:10.4236/fns.2016.77056
  99. Marques LG, Silveira AM, Freire JT. Freeze-drying characteristics of tropical fruits. Dry Technol. 2006;24(4):457-463. doi:10.1080/07373930600611919
  100. Kumar PS, Sagar VR. Drying kinetics and physico-chemical characteristics of osmo- dehydrated mango, guava and aonla under different drying conditions. J Food Sci Technol. 2014;51(8):1540-1546. doi:10.1007/s13197-012-0658-3
  101. Augusto J, Campos S De, Santos D, et al. Intake, total digestibility, microbial protein production and the nitrogen balance in diets with fruit by-products for ruminants. Rev Bras Zootec. 2011;40(5):1052-1060.
  102. El Boushy, A. R. Y. and van der Poel AFB. Handbook of Poultry Feed from Waste: Processing and Use. Springer-Verlag New York; 2000.
  103. Pereira E, Arabutan D, Bôa-viagem C, Lima RB, Lima MB, Ludke JV. Physicochemical composition and energy and nutritional characteristics of guava and tomato residues for free range broilers. Rev Bras Zootec. 2009;38(6):1051-1058.
  104. Guimarães AADS. Utilização do resíduo de goiaba (Psidium guajava L.) na alimentação de poedeiras comerciais. 2007. doi:616.89-008.47:616-
  105. Uchoa-thomaz AMA, Sousa EC, Carioca JOB, et al. Chemical composition, fatty acid profile and bioactive compounds of guava seeds (Psidium guajava L.). Food Sci Technol. 2014;34(3):485-492. doi:10.1590/1678-457x.6339
  106. Sharma HK, Kaur M. Utilization of Waste from Tropical Fruits. In: Anal AK, ed. Food Processing By-Products and Their Utilization. First Edit. ; 2018:27-51.
  107. Lira RC, Rabello CB, Ferreira PV, et al. Revista Brasileira de Zootecnia Inclusion of guava wastes in feed for broiler chickens 1. Rev Bras Zootec. 2009;38(12):2401-2407.
  108. Farid AS, Kamel ER. Effect of feeding guava waste on growth performance, diet digestibility, carcass characteristics and production profitability of ossimi lambs. Egypt J Nutr Feed. 2016;19(3):463-475.
  109. Ramadan Kamel E, Abdel-Fattah F, Samy El-Qaliouby H, Eaa M. Response of New Zealand rabbits to diet containing guava waste (Psidium guaijava L.): Effect on growth performance, diet digestibility and economic efficiency. Alexandria J Vet Sci. 2016;50(1):24-35. doi:10.5455/ajvs.232098
scroll to top