"Dry fruit" redirects here. For the botanical term, see Dry fruits.
Dried fruit
Dried fruit and nuts on a platter
Origin
Mediterranean, Mesopotamia, India
Use
Preservation of fruit for use as food
Production
Earliest: Dates and raisins
Dried fruit is fruit from which the majority of the original water content has been removed prior to cooking or being eaten on its own.[1] either naturally, Drying may occur by sun, through the use of industrial dehydrators, or by freeze drying.[2] Dried fruit has a long tradition of use dating to the fourth millennium BC in Mesopotamia, and is valued for its sweet taste, nutritional content, and long shelf life.
Traditional dried fruits such as raisins, figs, dates, apricots, and apples have been a staple of Mediterranean diets for millennia. This is due partly to their early cultivation in the Middle Eastern region known as the Fertile Crescent, made up of parts of modern Iran, Iraq, southwest Turkey, Syria, Lebanon, Palestine, Israel, and northern Egypt. Drying or dehydration was the earliest form of food preservation: figs, dates or grapes which fell from the plant and were sun-dried may have been consumed by early hunter-gatherers as edible and more long-lasting and sweeter.[4][5][6]
The earliest recorded mention of dried fruits can be found in Mesopotamian tablets dating to about 1500 BC. These clay slabs, written in Akkadian, the daily language of Babylonia, were inscribed in cuneiform; these were about diets based on grains, vegetables, and fruits such as dates, figs, apples, pomegranates and grapes.[citation needed] These early civilizations used dates, date juice evaporated into syrup and raisins as sweeteners, and included dried fruits in their breads.[citation needed]
The date palm was one of the first cultivated trees. It was domesticated in Mesopotamia more than 5,000 years ago and grew abundantly in the Fertile Crescent. Dates were the cheapest of staple foods due to high productivity, as an average date palm produced 50 kilograms (110 lb) of fruit a year for more than 60 years.[citation needed]
Figs were also prized in early Mesopotamia, Palestine, Israel, and Egypt.[citation needed] In addition to appearing in wall paintings, many fig specimens were found in Egyptian tombs as funerary offerings.[citation needed]
Grape cultivation began in Armenia and the eastern regions of the Mediterranean in the 4th millennium BC.[citation needed] Raisins were produced by sun-drying grapes. Raisin production and viticulture spread across northern Africa, including Morocco and Tunisia.
Dried fruits spread through Greece to Italy where they became a major part of diets.[citation needed]Ancient Romans consumed raisins in large quantities and at all levels of society, including them as a key part of their common meals, along with olives and fresh fruits.
Having dried fruits was essential in ancient Rome as these instructions for housekeepers around 100 BC tell: "She must keep a supply of cooked food on hand for you and the servants. She must keep many hens and have plenty of eggs. She must have a large store of dried pears, sorbs, figs, raisins, sorbs in must, preserved pears, grapes, and quinces. She must also keep preserved grapes in grape pulp and in pots buried in the ground, as well as fresh Praenestine nuts kept in the same way, and Scantian quinces in jars, and other fruits that are usually preserved, as well as wild fruits. All these she must store away diligently every year."[7]
Dried figs were added to bread and formed a major part of the winter food of common people. They were rubbed with spices such as cumin, anise, fennel seeds or toasted sesame, wrapped in fig leaves and stored in jars.[citation needed]
Dried fruit is produced in most regions of the world, and consumption occurs in all cultures and demographic segments. As of 2010[update], raisins accounted for about two thirds of this volume.[10]California produces the largest percentage of the US's and the world's[citation needed] dried fruit crop. It accounts for over 99% of the US crop of raisins and dried plums, 98% of dried figs, 96% of dried peaches, 92% of apricots and over 90% of dates. Most of California dried fruit production is centered in the San Joaquin Valley where the soil and climate, especially the hot, dry summers, provide ideal growing conditions. While these fruits were commonly dried in the sun in the past, now only raisins are almost entirely naturally sun-dried.[11]
Preparation and use
Fruits can be dried whole (e.g., grapes, berries, apricot, plum), in halves, or as slices (e.g., mango, papaya, kiwi). Alternatively, they can be chopped after drying (e.g., dates), made into pastes, or concentrated juices. The residual moisture content can vary from small (3–8%) to substantial (16–18%), depending on the type of fruit. Fruits can also be spread out, dried and cut into stripes in its puree form without the addition of sugar or fats with at least 50% moisture content as fruit leather, (see patent listed under the references section)[12][13] or as a powder by spray or drum drying. They can be freeze dried. Fresh fruit is frozen and placed in a drying chamber under a vacuum. Heat is applied, and water evaporates from the fruit while it is still frozen.[14] The fruit becomes very light and crispy and retains much of its original flavor. Dried fruit is widely used by the confectionery, baking, and sweets industries. Food manufacturing plants use dried fruits in various sauces, soups, marinades, garnishes, puddings, and food for infants and children.
As ingredients in prepared food, dried fruit juices, purées, and pastes impart sensory and functional characteristics to recipes:
The high fiber content provides water-absorbing and water-binding capabilities.
Organic acids such as sorbitol act as humectants, provide dough and batter stability, and control water activity.
Fruit sugars add sweetness, humectancy, and surface browning, and control water activity.
The high drying and processing temperatures, the intrinsic low pH of the fruit, and the low water activity (moisture content) in dried fruit make them a stable food.
Sulfur dioxide is used as an antioxidant in some dried fruits to protect their color and flavor. For example, in golden raisins, dried peaches, apples, and apricots, sulfur dioxide is used to keep them from losing their light color by blocking browning reactions that darken fruit and alter their flavor. Over the years, sulfur dioxide and sulfites have been used by many populations for a variety of purposes. Sulfur dioxide was first employed as a food additive in 1664, and was later approved for such use in the United States as far back as the 1800s.
Sulfur dioxide, while harmless to healthy individuals, can induce asthma when inhaled or ingested by sensitive people. The U.S. Food and Drug Administration (FDA) estimates that one out of every hundred people is sulfite-sensitive, and about 5% of asthmatics are also at risk of suffering an adverse reaction. Given that about 10% of the population suffers from asthma, this figure translates to 0.5% of the whole population with potential for sulfite-sensitivity. These individuals make up the subgroup of greatest concern and are largely aware of the need to avoid sulfite-containing foods. Consequently, the FDA requires food manufacturers and processors to disclose the presence of sulfiting agents in concentrations of at least 10 parts per million.[15]
In Taipei, Taiwan, a 2010 city health survey found one-third of tested dried fruit products failed health standard tests, most having excessive amounts of sodium cyclamate, some at levels 20 times higher than the legal limit.[16]
Turkey exported 1.5 billion dollars worth of dried fruit in 2021 and became the world's largest exporter of dried fruit.[17]
Traditional dried fruit has a low to moderate glycemic index (GI), a measure of how a food affects blood sugar levels. GI measures an individual's response to eating a carbohydrate-containing food (usually 50 grams of available carbohydrates) compared to the individual's response to the same amount of carbohydrates from either white bread or glucose. Carbohydrate-containing foods are classified as high (above 70), moderate (56–69), or low (0–55) GI.[19] Foods with high fiber content generally have a low GI. However, other factors also contribute to a food's glycemic response, such as the type of carbohydrate or sugar present, the physical characteristics of the food matrix, and the presence of organic acids. All studies assessing the GI of dried fruit show that they are low- to moderate-GI foods and that the insulin response is proportional to their GI. Factors thought to contribute to this glycemic response include the viscous texture of dried fruits when chewed, their whole food matrix, the presence of phenolic compounds and organic acids and the type of sugar present (about 50% fructose in most traditional dried fruit).[20]
Research
Consumption of dried fruit is under preliminary research for the potential to improve nutrition and affect chronic diseases.[21]
People have practiced food preservation since ancient times. Many folktales describe ways of preserving foods in one way or another according to local and cultural traditions. Dehydration methods help to prevent food from spoilage and to maintain it for a longer period of time while keeping it suitable for consumption. Reducing the amount of water in fruits helps prevent bacteria, yeast or fungi from growing on them. There are several processes that can be used in the production of dried fruit, each of which affects its appearance, rehydration properties, and nutrients differently. These drying processes include sun drying, tray (air) drying, freeze drying, and vacuum microwave drying.[22] Each process has its own benefits and disadvantages.
This process uses sun exposure as its thermal source, combined with natural airflow. It is also a traditional drying method to reduce the moisture of fruits by spreading them under the sun. Warmer temperatures evaporate the moisture, and lower humidity allows moisture to move quickly from the fruit to the air. However, there are many disadvantages associated with it, such as the longer time required to dry, the hot climate and daylight, and risk of invasion by animals and unwanted microorganisms.
Tray drying
A tray dryer is similar to a convection drier, which is placed in enclosed, insulated chambers and trays on top of each other in the tray. Input materials are batch-fed, placed in trays, and loaded into ovens for drying. Dryers are used in processing where drying and heating are important parts of the industrial manufacturing process, like dried fruits. Tray drying means dehydrating small pieces of fruit from a source of hot, dry air or the sun until they are dry enough to store at ambient temperature with minimal spoilage. Despite its poor re-hydration properties and shrunken appearance, this process requires a short period of time along with controlled humidity and heated air.
Freeze drying
Freeze-drying is a special form of drying that removes all moisture and has less effect on the taste of food than normal dehydration. Freeze drying is a water removal process commonly used to preserve pear material. The fruit is placed in a vacuum chamber at low heat to increase shelf life. This process works by freezing the material, then reducing the pressure and adding heat to neutralize the frozen water in the material. Unlike the other drying methods, this method allows the dried mango to retain its shape, retain the highest color value, and provide a great rehydration property despite its high costs. Foods that contain adequate amounts of water are very easy to work with and will maintain their initial shape after the freeze-drying process is complete.
Vacuum microwave drying
The microwave generates a specific amount of energy, easily shortening the drying time. In addition, the boiling point of water is lowered under vacuum, causing a high temperature inside the dried particles on the surface of the product. Microwave vacuum drying is a dehydration process that uses microwave radiation to generate heat at full pressure (chamber pressure). During vacuum drying, high-energy water molecules propagate to the surface and evaporate due to low pressure. Due to the absence of air, vacuum drying inhibits oxidation and maintains the color, texture, and taste of dried products. This device can improve the quality of products, and the equipment can prolong the shelf life of food, preserve the original taste and nutrients of food, maintain the physical activity of raw materials, enhance the function of healthy food, and increase the value of agricultural products. This method provides better flavor retention, greater rehydration, least nutrient loss, and least color change among other thermal drying methods, along with a faster drying rate compared to freeze drying. Vacuum microwave not only dries the mango quickly, it also reduces the amount of fibers and microorganisms present in the pulpy part of the fruit. The fruit taste is distorted at some rate. The vacuum drying also reduces the amount of water contained, and in a closed environment, no other microorganisms can enter into the fruit.
Gallery
Fruit leather
Dried fruit and fruit leather
Dried fruits for sale at a market
Dried fruits for sale
A dry fruit seller in Armenia
Dried apples, pears and plums — a traditional product of Poland, used, for example, to prepare Christmas compote
^Hui, Y. H. Handbook of fruits and fruit processing. Blackwell Publishing, Oxford UK (2006) p. 81
^Trager J. The food chronology: a food lover's compendium of events and anecdotes, from prehistory to the present. Henry Holt and Company Inc, New York, NY 1995
^Brothwell D, Brothwell P. Food in antiquity: A survey of the diet of early people. Johns Hopkins University Press, Baltimore and London (1998) pp. 144–147
^Tannahill R. Food in History, Three Rivers Press, New York (1998) pp. 49–51
US patent 20090169694A1, Fleisch, Jens; Hilker, Erhard & Markwardt, Klaus, "Method and Apparatus for Producing Fruit Leather from a Fruit Mass", published 2009-07-02, issued 2012-05-15
Further reading
Al-Sahib W. and Marshall R. J. "The fruit of the date palm: Its possible use as the best food for the future?" J Food Science Nutr 2003; 54: 247–59
Barta J. Fruit Drying Principles (Chapter 5) In: Handbook of Fruits and Fruit Processing Hui YH. Ed. Blackwell Publishing, Iowa (2006)
Grivetti L. E. and Applegate E. A. "From Olympia to Atlanta: Agricultural-historic perspective on diet and athletic training". J Clinical Nutr 1997; 127:S860–868
Hooshmand S. and Arjmandi B. H. "Viewpoint: Dried plum and emerging functional foods that may effectively improve bone health". Ageing Res Reviews 2009; 8: 122–7
Ratti C. and Mujumdar A. S. Drying of Fruit (Chapter 7) In: Processing Fruit Barrett D. M., Somogyi L. and Ramaswamy H., Eds. CRC Press, New York (2005)