Small-scale producers have the option to harvest earlier, when vegetables are more delicate and valuable; harvest later, when fruits are at a riper, more flavorful stage; or harvest more often (taking advantage of multiple harvests to gather produce at its optimum stage of maturity). All these options can lead to higher profits due to the higher value of the produce you have to offer for sale.
One of the most common mistakes growers make is to harvest fruit crops too early, when they are under-ripe and have not yet developed their full flavor. Some vegetables, if allowed to grow large, will be too fibrous or full of seeds for good eating quality. With many horticultural crops, if you harvest all at once you are sure to have many items that are either under-mature or over-mature. Using a maturity index as a standard will greatly reduce pre-sorting losses. For some crops this involves using a refractometer to measure sugars or a penetrometer to measure firmness.
Mechanical damage during harvest can become a serious problem, as injuries predispose produce to decay, increased water loss and increased respiratory and ethylene production rates leading to quick deterioration. In general, harvesting by machine will cause more damage than harvesting by hand, although some root crops can be severely damaged by careless hand digging. The containers used by pickers in the field should be clean, have smooth inside surfaces and be free of rough edges. Stackable plastic crates, while initially expensive, are durable, reusable and easily cleaned (FAO, 1989). If baskets must be used, they should be woven "inside out" with the stubs of the beginning and end of each cane on the outside of the basket (Grierson, 1987).
Manual harvesters should be well trained in the proper way to harvest the crop to minimize damage and waste, and should be able to recognize the proper maturity stage for the produce they are handling. Pickers should harvest with care, by snapping, cutting or pulling the fruit or vegetable from the plant in the least damaging manner. The tips of knives should be rounded to minimize inadvertent gouges and excess damage to perennial plants. Knives and clippers should always be well sharpened. Pickers should be trained to empty their picking bags and/or baskets with care, never dumping or throwing produce into field containers. If harvesters pick directly into large bulk bins, produce can be protected from bruising by the use of a de-accelerating chute fashioned from canvas. Vented, stackable field containers should be kept clean and smooth.
Exposure to the sun should be avoided as much as possible during and after harvest, as produce left out in the sun will gain heat and may become sun-burned. Produce exposed to sunlight can soon become 4 to 6 °C (7 to 11 °F) warmer than air temperature (Thompson et al, 2001). Field bins should be placed in the shade or loosely covered (for example with light colored canvas, leafy plant materials, straw or an inverted empty container) if delays are expected in removing them from the field. Night or early morning harvest is sometimes an option for harvesting produce when internal temperatures are relatively low, reducing the energy needed for subsequent cooling. Latex flow is often lower later in the morning than it is at dawn for crops such as mango and papaya (Pantastico, 1980), so harvesting as late in the morning as possible can reduce later efforts required to clean the produce before packing. Also, citrus fruits should not be harvested early in the morning when turgid because of their greater susceptibility to the release of essential oils from the flavedo oil glands that cause oil spotting (green spots on yellow and orange citrus fruits after degreening).
Directly following harvest, when produce is prepared for marketing, cooling is essential. Cooling (also known as "pre-cooling") is the removal of field heat directly after harvest, before any further handling. Any delays in cooling will shorten postharvest life and reduce quality. Even produce undergoing repeated cooling and warming deteriorates at a slower rate than produce that has not been cooled (Mitchell et al, 1972).
Rough handling during preparation for market will increase bruising and mechanical damage and limit the benefits of cooling. Roads between the field and the packinghouse should be graded and free from large ruts, bumps and holes. Field boxes must be well-secured during transport and, if stacked, not overfilled. Transport speeds must be suited to the quality and conditions of the roads, and truck and/or trailer suspensions kept in good repair. Reduced tire air pressure on transport vehicles will reduce the amount of motion transmitted to the produce (Thompson et al in Kader, 2002).
Any practice that reduces the number of times the produce is handled will help reduce losses. Field packing (selection, sorting, trimming and packaging of produce at the time of harvest) can greatly reduce the number of handling steps the produce must undergo before marketing. Small carts or small mobile field packing stations can be designed to be moved along with the packers and to provide shade for packing operations.
Maturity standards have been determined for many fruit, vegetable and floral crops. Harvesting crops at the proper maturity allows handlers to begin their work with the best possible quality produce. Produce harvested too early may lack flavor and may not ripen properly, while produce harvested too late may be fibrous or overripe. Pickers can be trained in methods of identifying produce that is ready for harvest. The following table, from Reid (in Kader, 2002) provides some examples of maturity indices.
Index |
Examples |
|
Elapsed days from full bloom to harvest |
Apples, pears |
|
Mean heat units during development |
Peas, apples, sweet corn |
|
Development of abscission layer |
Some melons, apples, feijoas |
|
Surface morphology and structure |
Cuticle formation on grapes, tomatoes |
|
Size |
All fruits and many vegetables |
|
Specific gravity |
Cherries, watermelons, potatoes |
|
Shape |
Angularity of banana fingers |
|
Solidity |
Lettuce, cabbage, brussels sprouts |
|
Textural properties |
||
Firmness |
Apples, pears, stone fruits |
|
Tenderness |
Peas |
|
Color, external |
All fruits and most vegetables |
|
Internal color and structure |
Formation of jelly-like material in tomato fruits |
|
Compositional factors |
||
Starch content |
Apples, pears |
|
Sugar content |
Apples, pears, stone fruits, grapes |
|
Acid content, sugar/acid ratio |
Pomegranates, citrus, papaya, melons, kiwifruit |
|
Juice content |
Citrus fruits |
|
Oil content |
Avocados |
|
Astringency (tannin content) |
Persimmons, dates |
|
Internal ethylene concentration |
Apples, pears |
Source: Kader, A. A. 1983. Postharvest Quality Maintenance of Fruits and Vegetables in Developing Countries. In: Lieberman, M., Post-Harvest Physiology and Crop Preservation. Plenum Publishing Corporation. p.455-469.
Vegetables are harvested over a wide range of maturities, depending upon the part of the plant used as food.
The following table provides some examples of maturity indices of vegetable crops.
Crop |
Index |
||
Root, bulb and tuber crops |
|||
Radish and carrot |
Large enough and crispy (over-mature if pithy) |
||
Potato, onion, and garlic |
Tops beginning to dry out and topple down |
||
Yam bean and ginger |
Large enough (over-mature if tough and fibrous) |
||
Green onion |
Leaves at their broadest and longest |
||
Fruit vegetables |
|||
Cowpea, yard-long bean, snap bean, batao, sweet pea, and winged bean |
Well-filled pods that snap readily |
||
Lima bean and pigeon pea |
Well-filled pods that are beginning to lose their greenness |
||
Okra |
Desirable size reached and the tips of which can be snapped readily |
||
Upo, snake gourd, and dishrag gourd |
Desirable size reached and thumbnail can still penetrate flesh readily (over-mature if thumbnail cannot penetrate flesh readily) |
||
Eggplant, bitter gourd, chayote or slicing cucumber |
Desirable size reached but still tender (over-mature if color dulls or changes and seeds are tough) |
||
Sweet corn |
Exudes milky sap from kernel if cut |
||
Tomato |
Seeds slipping when fruit is cut, or green color turning pink |
||
Sweet pepper |
Deep green color turning dull or red |
||
Muskmelon |
Easily separated from vine with a slight twist leaving clean cavity |
||
Honeydew melon |
Change in fruit color from a slight greenish white to cream; aroma noticeable |
||
Watermelon |
Color of lower part turning creamy yellow, dull hollow sound when thumped |
||
Flower vegetables |
|||
Cauliflower |
Curd compact (over-mature if flower cluster elongates and become loose) |
||
Broccoli |
Bud cluster compact (over-mature if loose) |
||
Leafy vegetables |
|||
Lettuce |
Big enough before flowering |
||
Cabbage |
Head compact (over-mature if head cracks) |
||
Celery |
Big enough before it becomes pithy |
Source: Bautista, O.K. and Mabesa, R.C. (eds). 1977. Vegetable Production. University of the Philippines at Los Banos. Additional detailed maturity indices for fruits, vegetables and cut flowers can be found online at http://postharvest.ucdavis.edu on a wide range of Produce Fact Sheets.
Sugars are the major soluble solids in fruit juices and therefore soluble solids can be used as an estimate of sweetness. A hand-held refractometer can be used outdoors to measure % SSC (equivalent degrees Brix for sugar solutions) in a small sample of fruit juice. Temperature will affect the reading (increasing about 0.5% SSC for every 5 ºC or 10 ºF), so you should adjust the measurement for the ambient temperature.
A garlic press works well to squeeze the juice from fruit samples. For small
fruits, use the whole fruit. For large fruits, take a wedge for the stem end
to the blossom end and to the center of the fruit. Remove any pulp by filtering
the juice through a small piece of cheesecloth. You must clean and standardize
the refractometer between each reading with distilled water (should read 0%
SSC at 20 ºC or 68 ºF).
Here are some examples of proposed minimum % SSC for selected commodities. If your reading indicates a higher % SSC, then your produce is better than the minimum standard. Strawberries which are of excellent flavor, for instance, would measure 8% SSC or above.
Minimum %SSC |
|
Apricot |
10% |
Blueberry |
10 |
Cherry |
14-16 |
Grape |
14-17.5 |
Kiwifruit |
6.5 |
Mango |
10-12 |
Muskmelon |
10 |
Nectarine |
10 |
Papaya |
11.5 |
Peach |
10 |
Pear |
13 |
Pineapple |
12 |
Plum |
12 |
Pomegranate |
17 |
Strawberry |
7 |
Watermelon |
10 |
Source: Kader, A.A. 1999. Fruit maturity, ripening and quality relationships. Acta Hort 485: 203-208.
The degree of softness or crispiness can be estimated by squeezing produce, or by taking a bite. Objective measurements can be made with inexpensive penetrometers. The most common way to measure firmness is resistance to compression or pounds-force (lbf). The Effe-gi fruit penetrometer is a hand-held probe with a gauge for pounds-force.
To measure firmness, use fruit that are uniform in temperature, since warm
fruit are usually softer than cold fruit. Use fruits that are uniform in size,
since large fruit are usually softer than smaller fruit. Make two puncture tests
per fruit on larger fruits, once on opposite cheeks, midway between stem and
blossom ends. Remove a disc of skin (larger than the tip to be used) and choose
the appropriate plunger tip (see below). Hold the fruit against a stationary,
hard surface, and force the tip into to fruit at a slow, uniform speed (take
2 seconds) to the scribed line on the tip. Take the reading to the nearest 0.5
lb-force.
Appropriate Effi-gi plunger tip sizes to use when measuring firmness in selected fruits:
1.5mm | (1/16 inch) | Olive |
3 mm | (1/8 inch) | Cherry, grape, strawberry |
8 mm | (5/16 inch) | Apricot, avocado, kiwifruit, pear, mango, nectarine, papaya, peach |
11 mm | (7/16 inch) | Apple |
Calibrate firmness testers by holding the tester vertically and placing the tip on the pan of a scale. Press down until the scale registers a given weight, then read the firmness tester. Repeat 3 to 5 times, if you find the instrument reads the same as the scale, it is ready to use. You can adjust the penetrometers by inserting washers in the appropriate locations (follow the instructions that come with the instrument).