Saturday, December 17, 2016

Importance of Pack-houses and their need

Importance of Pack-houses

A pack house can be defined as a place protected from weather for both product and people working there. It also allows special operations to be performed.

What is a Pack house?
A packing house is a facility where fruit is received and processed prior to distribution to market.  Bulk fruit (such as apples, oranges, pears) is delivered to the plant via trucks or wagons, where it is dumped into receiving bins and sorted for quality and size. Fruit that is ready to be packed into crates or flats is run through a washer and then air-dried. A light coating of natural wax is applied to help the fruit retain moisture and enhance its appeal. The fruit is transported via conveyor belts to the grading tables where it is visually sorted. With its capacity to process large volumes, farmers associations, cooperatives, or even community organizations can take advantage of these opportunities. 

Requirements:
A packinghouse needs to be located close to the production area and within easy access to main roads or highways. Sufficient space outside is also required to avoid congestion of vehicles entering and leaving. It is important to create a comfortable environment both for produce and workers. Lighting is critical in identifying defects on inspection tables. Dull colors and non-glossy surfaces are a requirement for equipment, conveyor belts and outfits. In this way, defects are not masked because of the reflection of light. It also helps to reduce eye fatigue. Packed fruit is designated by size, based on the average number of pieces it takes to fill a box. Packed boxes are stored in a "pre-cooler" to prepare them for the trip to market by truck or rail.

Importance of Pack house:
Preparation of the produce before it is sent for the market comprises four basic key operations: 
·        Removal of unmarketable material
·        Sorting by maturity and/or size
·        Grading
·        Packaging

Products need to be transported to a packing shed for special operations like washing, brushing, waxing, controlled ripening, refrigeration, storage or any specific type of treatment or packaging.

India and Pack house:
In agro-trade, India stands sixth in the world. Its export share is 2.4% or $43.5billion (in 2014-15) while imports share is 1.5% with a ninth rank and total value of exports is $27.3 billion. APEDA is a non-commercial export promotion organization of government of India and acts as a link between industry and the government. It helps in giving assistance and guidance for promotion of exports of fruits, vegetables and their products, meat and meat products, poultry and poultry products, dairy products etc.

According to a report titled ‘All India Cold-chain Capacity Assessment (Status & Gaps)’ released by Minister of State for Agriculture and Farmers Welfare, to fulfill current consumption of urban clusters, India needs about 70,000 pack-houses, each equipped with a pre-cooler and dispatch room for onwards transport links. Lack of pack-houses and transport connectivity results in a breach in the integrity of cold-chain. This also results in most of the cold storage capacity being used to store only crops like potato, dried chillies, pulses, etc. which do not need onwards cold-chain connectivity. The report has highlighted that the gap in India’s cold-chain is not as much due to a lack of cold storage capacity, but more to do with various other components, necessary to implement farm-to-fork connectivity. The report highlights that in future, development focus needs to be more on modern pack-houses and refrigerated transport, which are important to initiate the appropriate logistics chain from villages to city centers.

What are factors hindering exports of horticulture produce?
Quality of produce and packing are two issues hindering our exports. State farmers are producing in bulk but they lack in giving attention to quality. This does not mean the produces are bad but the produce sometimes contains insecticides, which is more than the permissible limit. In exports of perishable items, packing is important.

How can hurdles be removed?
With joint efforts of the state government and APEDA, packing hurdles can be removed. Government is exploring possibility to set up common pack house facility in clusters for processing. It is also considering the option of a common infrastructure at ports also. Similarly, orientation programs for exports should help. Value addition to produces like mango and orange jams, juices, squash etc and potato flour and chips, dehydrated onion flakes, frozen peas, sauces and concentrates can also help in boosting export of horticulture produces from the state.

Conclusion:
There is an urgent need to improve market linked connectivity for agricultural produce. Previously, the main focus was on creating of cold stores. Farm-gate infrastructure in form of modern pack-houses and reefer vehicles is the key to connecting the farmers with the distribution network. Modern pack-houses, which are used to prepare and pre-condition the fresh farm produce for subsequent logistics connectivity in the cold-chain, are a critical missing link. Without these village level facilities, farmers of high value fruits and vegetables are not able to take full advantage of the cold-chain. 

Saturday, December 3, 2016

All you need to know about Shiitake Mushrooms!

Shiitake Mushrooms


The Shiitake mushroom, the third most widely distributed mushroom in the world, has enjoyed a prominent spot in Asian cuisine for centuries. They have been used medicinally by the Chinese for more than 6,000 years. Mushrooms are a fungus, a special type of living organism that has no roots, leaves, flowers or seeds. People eat shiitake mushrooms raw, cooked or dried. Raw shiitakes offer the largest number of health benefits, but dried shiitakes are also rich in vitamins and minerals. 


What's New and Beneficial about Shiitake Mushrooms?

Shiitake mushrooms have long been recognized as a very good, non-animal food source of iron. Recent studies have shown the ability of shiitake mushrooms to help protect us against cardiovascular diseases. There are very few studies on shiitake mushrooms in the human diet. However, there is a clear message about shiitake mushrooms: they can provide us with some fantastic health benefits.
  • Shiitake mushrooms can enhance immune function in two ways; giving it a boost when needed, and cutting back on its activity when needed.
  • Shiitake mushrooms are rich in B vitamins. Additionally, they are concentrated in minerals.       
  • Linoleic acid helps with weight loss and building muscle. It also has bone-building benefits, improves digestion, and reduces food allergies and sensitivities.
  • Shiitake mushrooms contain many chemical compounds that protect your DNA from oxidative damage.
  • They provide us with protection from a variety of problems involving oxidative stress and immune function including rheumatoid arthritis (RA).
  • Based on research to date, adding shiitake mushrooms to diet is likely to offer anti-cancer benefits, especially with respect to prevention of prostate cancer, breast cancer, and colon cancer.
  
How to grow Shiitake?

Shiitake mushrooms can be one of the most sustainable foods in your diet! While the majority of shiitake mushrooms produced worldwide have been grown on sawdust block in a non-natural setting, it is fully possible for shiitake mushrooms to be produced on natural hardwood logs in a forest setting. This approach to shiitake mushroom production is called "forest farming".

Till some time there was no proper technology to grow this variety on a successful commercial scale but recently the Directorate of Mushroom Research (DMR), situated at Chmabaghat in Solan district and Indian Institute of Horticulture Research (IIHR), at Hassargatta near Bangalore have developed new techniques for growing this crop. They have experimented with the growing technology by using willow wood as a substrate.

The commercial cultivation can be carried out on sawdust of broad leave trees mainly tuni, mango, safeda, oak, maple and poplar using saw dust (80 kg), wheat bran (19 kg) and calcium carbonate (1 kg). Water should be adjusted to 60-65% and pH to be adjusted to 5.5-6.0 using gypsum. Saw dust is soaked for 16-18 hours and wheat bran for three hours. All the ingredients are thoroughly mixed. 


Production and Market:

Presently, China and Japan are the bulk producers of this prized mushroom variety. China produces over 80% of all commercially sold shiitake mushrooms. Japan, Korea and Taiwan also produce shiitake mushrooms. One quickly growing market for shiitake mushrooms is Brazil, which currently produces more shiitake mushrooms than any other South American country.

Since the mushroom is grown in very small quantities in India, the demand for it is mostly met through imports from Thailand, Korea and China. As a result, the cost of 1 kg of dried shiitake mushroom is almost Rs. 1,600 per kg. If farmers in India do start cultivating shiitake mushroom it is likely to benefit them economically because of the high price it demands in the market.

Storage:

Here is some background on why we recommend refrigerating shiitake mushrooms. Whenever food is stored, four basic factors affect its nutrient composition: exposure to air, exposure to light, exposure to heat, and length of time in storage. Vitamin C, vitamin B6, and carotenoids are good examples of nutrients highly susceptible to heat, and for this reason, their loss from food is very likely to be slowed down through refrigeration.



Sources:
http://www.whfoods.com/genpage.php?dbid=122&tname=foodspice 

Wednesday, November 23, 2016

Post-harvest Management and Preservation of Pomegranates

If pomegranates are to be stored in packages, its storage capacity of totally dependent on proper peeling or pomegranate and quality of the arils. Storage becomes difficult if the arils/seeds are damaged during the process of peeling. There are various machines available in the market which helps in peeling and sorting pomegranate seeds. To continue with processing on such seeds, it is vital to disinfect pomegranate with the help of hydrogen peroxide. 

Ready-to-eat packages of pomegranate:

To prepare ready-to-eat packages of pomegranate, it is important to choose good quality fruit. They should be washed in clean and sterile water using chlorine. The seeds must be soaked in water with 100ppm chlorine and should later be cleaned in normal clean water. Chlorinated water used to clean seeds must have pH between 6 to 7. Usage of disinfected gloves during handling and entire process is recommended. 

Method:

Gently peel the pomegranate. Another enhanced option is to peel the seeds in clean and disinfected water. Keep aside broken or damaged kernel. Since pomegranate is acidic in nature, it is vital to remove broken or leaking seeds. In a package, acidic sap from such broken seeds can infect and rot other kernels resulting in foul smell. Transparent and turgid looking arils in good condition should be picked away. Stainless steel table or plastic containers disinfected by Food grade Hydrogen Peroxide should be used for sorting and collection. Pomegranate seeds should be disinfected by soaking for 5 minutes in a solution of 100 to 150 ppm sodium hypochlorite. Thus processed arils should be washed in clean water and then carefully be passed on a muslin cloth spread on a stainless steel table to dry the water. After the water is dried, they should be processed in a solution of lemon juice and water for 30 seconds. This solution should have 5% lemon juice extract. Lemon juice works as an antioxidant. It can be replaced by solution of ascorbic acid (5 gram per liter) or citric acid solution (5 gram per liter) or a mixture of both. If processed in these solutions for 30 seconds, they also work as antioxidants. 

The seeds after this process can be removed from the solution and they should be kept under cold blower (6to 8 degree Celsius) or high speed fan until all the water has dried out. The time required to drain the water depends on the blower speed and the thickness of layer of pomegranate arils. Depending on these factors, seeds are properly and completely dried out in 30 to 60 minutes. There are also machines available in the market to accelerate this process. Thus processed seeds can be packaged domestically. Packed ready-to-eat seeds stored at cold temperature which are suitable to launch in market. 4 to 6 degree Celsius is the ideal temperature to store such packed pomegranate seeds. Cold-chain plays an important role in increasing the shelf-life of processed arils.

Packaging:

Pomegranate arils packed using domestic machines and stored at 4 to 6 degree Celsius are edible for 3 to 4 days while those packed at 1 degree Celsius can stay till 6 days. Antioxidants and sanitizers used to process pomegranates should be checked for approval by the export countries. Generally used and almost globally approved chemicals are lemon juice, ascorbic acid, sodium hypochlorite and citric acid. The shelf life of these ready-to-eat pomegranate arils can be increased exponentially up to 14-16 days with the help of Modified Atmosphere Storage (MAP) by regulating the amount of nitrogen, oxygen and carbon dioxide in the atmosphere in which these packages are to be stored. This technology also maintains the desired microbial count for 14-16 days. 

Other natural substitutes like honey, lemon juice can also be used for processing which help in preserving the taste and turgidity along with increasing its shelf-life. Also, Food grade certified nano-silver and Hydrogen Peroxide along with MAP packaging help in maintaining the desired microbial count. Honey, citric acid and ascorbic acid work as antioxidants, increase product shelf-life and help in maintaining the medicinal value of the product thus increasing its market value.  




Monday, August 22, 2016

Post-Harvest Ripening of Banana and Other Fruits

Post-Harvest Ripening of Banana and Other Fruits

By Sunil P Bhat
Managing Director
Advance Agro Ripe Pvt. Ltd., Pune (India )                     
www.agroripe.com

Mr. Sunil Bhat is a hard core Chartered Engineer with over 25 years of lofty experience in the field of Plant Engineering. He is equipped with domain knowledge in the field of post-harvest preservation of Fruits and Vegetables. He is member of Institution Of Engineers (India) and ISHRAE. He is also a certified Engineer by 'National Horticulture Board' (NHB) India for planning and designing cold chain infrastructure. 

Introduction:
Banana ranks third in cultivated area among fruits in India with 0.464 million hectare covering 12.46 per cent of the total area under fruit cultivation. However, it ranks first in total production (15.07 million tons), becoming nearly one- third (34.22%) of total fruit production. India occupies first position in banana production globally. Among Indian states, Tamilnadu ranks first in area and production while productivity is the highest in Maharashtra. Most of the banana is produced on a small scale basis in different production systems.

There has been a phenomenal increase in banana production due to adoption of high density planting, use of tissue-cultured seedlings and drip irrigation, which have significantly improved productivity.

The Need to Promote Bananas:
A banana has four times the proteins, twice the carbohydrates, three times the phosphorus, five times the vitamin A and iron, and twice other vitamins and minerals compared to an apple.  It is also rich in potassium and is one of the best value foods around. So maybe it is time to change the well-known phrase to: "A banana a day keeps the doctor away!"
There is no better snack than a banana as a quick fix for flagging energy levels. Containing three natural sugars – sucrose, fructose and glucose – combined with fiber, a banana gives an instant, sustained and substantial boost of energy. Research has proved that just two bananas provide enough energy for a strenuous 90-minute workout. No wonder the banana is the most favourite fruit of the world's leading athletes.    

Post-Harvest Losses:
According to National Botanical Research Institute (NBRI), due to improper handling and ripening techniques, bananas worth Rs.150 crores (25% to 30%) are lost every year in Maharashtra alone. Losses occur at the following stages:
  • Harvesting and pre-harvesting: Due to spoilage and trimming.
  • Transport: Due to bruising, breakage and infection as a result of dust, heat, rain and humidity.
  • Storage: Due to over ripening or under ripening.
  • Processing and packing: Due to inefficiency and contamination.
  • Marketing:  Due to loss of weight and quality during multi-level handling.
The problem is further complicated by the lack of storage facilities at the farm level, and farmers are forced to dispose off the entire produce immediately on harvesting. Thus, the margins of wholesalers and retailers are much higher than in the developed countries.

Scientific Ripening of Fruits – the Present Scenario:
Large quantities of fruits like mango, papaya, sapote, etc. are ripened using calcium carbide which emits harmful substances like phosphor, arsenic and lead, which are health hazards. As per the old Prevention of Food Adulteration (PFA) Act (Section 44AA), use of carbide is strictly banned.  The only safe method accepted worldwide is the use of ethylene, which is a natural hormone for ripening under controlled temperature and relative humidity conditions.

After getting cleaned, packaged and quality checked, banana needs to be ripened before it arrives at retail outlets for purchase by the consumers. The wholesaler would need ripening facility under controlled conditions for fresh green bananas of appropriate physiological maturity brought from the farm or cold room to the ripening chamber. There is a need for the establishment of substantial ripening facilities in India, owing to the large production of banana in different parts of the country.

Customers have a preference for bananas with spotless yellow colour that make them more presentable, apart from their size. Thus a proper ripening facility ensures good price realization for the producer.

Ripening Chambers at Consumption Points:
Ethylene gas is used for ripening most of the climacteric fruits like banana, mango and papaya under controlled condition of temperature, humidity and ethylene concentration in air tight, gas proof rooms. Ethylene, being a natural hormone, does not pose any health hazard for fruits; also, being a de-greening agent, it turns the peel from green to a perfect yellow and maintains the sweetness and aroma of the fruit. This adds value to the fruit. A ripening chamber does not require large investments and can be set up in the farm or at the trading point.

These chambers are multipurpose. During off-season, no ripening load period, they can be used for storing and preserving fresh vegetables and other fruits as well, ensuring maximum utilization of the cold chamber. This way of ripening not only increases the cosmetic value, sweetness and aroma of fruit but also increases its post ripening shelf life substantially. The same chamber and set-up can also be used for ripening mango, papaya and citrus fruits by minor adjustment in temperature and ethylene concentrations.

Post-Harvest Processing of Bananas:
Pre-cooling and Storage
The optimum transport and storage conditions for mature green bananas are 13-14°C and 90-95% relative humidity. Although pre-cooling is not generally carried out, it is advisable to cool down fruit exposed to temperatures above 30°C soon after harvesting to remove field heat. Failure to do so can irreversibly inhibit ripening and result in heat damage indicated by failure to de-green properly, excessive pulp softening of green fruit, boiled appearance of the pulp and incomplete starch-to-sugar conversion. In addition, insufficient field heat removal or failure to precool can result in failure to reach the desired storage temperature, heat accumulation in the cold room and thus reduced life.

Pre-cooling is done by forced-air or evaporative cooling. Different banana cultivars respond differently to Controlled Atmosphere (CA) conditions. Generally, storage in CA at 2-5% O2, 2-5% CO2, 90-95% RH and 12-15°C in the absence of ethylene can extend the post-harvest life of mature green bananas to 4-6 weeks. After storage, such fruit can still be ripened to good quality by treating it with ethylene. Excessively high CO2 concentrations can be toxic to bananas and cause pulp softening of green fruit, internal browning and off flavor. The use of CA during ocean transport has made it possible to harvest bananas at full mature stage. Bananas also respond well to Modified Atmosphere Packaging (MAP), and green bananas can be stored in MAP at 13-14°C for more than 30 days. Ripe bananas can be stored in MAP at 13-14°C for up to 7 days.

Ethylene and Ripening:
Bananas, mangos, papaya, sapote, etc. are climacteric fruit that exhibit typical climacteric patterns in both their respiration and ethylene production rates during ripening. Since exposure to ethylene accelerates ripening in these fruit, bananas must be kept away from other ethylene-producing fruit such as mangoes and melons. Bananas are harvested when mature but still green and ripened at the destination market by treatment with 100-150 μL L-1 (ppm) ethylene at 15-20°C (depending on the required ripening rate) and 90-95% RH. Careful attention should be paid to temperature and CO2 management during ethylene treatment and ripening. To avoid suppression of ethylene action, CO2 levels should never be allowed to exceed 1%.
In CA, the low O2 and high CO2 levels suppress ethylene production by the fruit.

As soon as the product has reached the desired ripening temperature, ethylene is released into the ripening room from pressurized gas cylinders (Figure 1) or a generator that converts ethanol to ethylene. Ethylene stimulates fruit ripening at concentrations ranging from 0.1 to 1.0 ppm. However, ethylene concentration in the ripening room is set at around 100 ppm to ensure that all the fruit are constantly saturated with ethylene for the duration of the exposure period, and to make a provision for possible leakages from the room. After the product has been exposed to ethylene for 24 hours, the ripening room is ventilated to get rid of excess CO2 in the atmosphere, since ethylene action is inhibited by high levels of CO2. Levels higher than 1% inhibit the effect of ethylene in initiating ripening. After ethylene exposure, the room is ventilated continuously at a rate of 1 room volume every 2 to 6 hours to maintain the CO2 levels below 1%. If the room is not equipped with a continuous ventilation system, ventilation can be achieved by opening the door for 10 to 20 minutes once or twice a day while the refrigeration fans are running. However, this practice can result in undesirable temperature fluctuations that can interfere with the precise control of the ripening process. Once the product has reached the desired colour or stage of ripening, the room temperature is lowered again to normal storage temperature before the product is removed to storage, transported to the market or processed.
Banana or other fruit ripening rooms must be cleaned and disinfected regularly to prevent infection of the fruit. Room surfaces must be scrubbed down with a suitable disinfectant.

General Ripening Procedure:
·         Quickly load produce in the ripening room and gradually raise or reduce the flesh temperature to the ripening level.
·         Temperature monitoring is critical. Flesh temperature must be accurately maintained during ripening.
·         Treat with ethylene for 24 hours.
·         After this, ventilate continuously.
·         Lower the flesh temperature to storage temperature when the desired ripening stage is reached.

Ethylene (C₂H₄)
Fruit ripening is a genetically programmed process that is controlled by plant hormones and accelerated or retarded by certain environmental factors. Plant hormones control the expression or suppression of specific genes involved in these processes. Some plant hormones delay ripening, while others such as ethylene accelerate the process in climacteric commodities such as bananas, mango, papaya, sapota etc. Ethylene is a unique gaseous plant hormone. It stimulates respiration, accelerates fruit softening as a result of cell wall hydrolysis due to the stimulation of the transcription of cell wall degrading enzymes such as polygalacturonase, causes de-greening (yellowing) due to the stimulation of chlorophyll breakdown, causes de-compartmentation of the cell due an increase in membrane permeability, changes the metabolism of organic compounds such as carbohydrates, organic acids and proteins and stimulates the production of aroma volatiles.

Bananas, mango, papaya, etc. should preferably be ripened in a forced air room to prevent heat build-up and facilitate even distribution of ethylene gas. The refrigeration equipment must be adequate to raise or lower the temperature between 14˚C and 18˚C in a few hours. Air circulating fans must be strong enough to provide an air flow rate of 0.02-0.06 m3 per minute per kg fruit in the room. Although fruits can be ripened in non-forced air store rooms, it is best to use forced air rooms for this purpose since they provide for more accurate temperature control and even distribution of ethylene in the room. When ordinary cold stores are used, boxes should be stacked in an open stacking pattern such as pigeonhole stacking where open spaces are left in the stack to improve air flow during ripening and storage . It is also important to leave adequate space between the pallets and the cold room walls to allow for unrestricted air circulation since cooling of the pallet is mostly by conduction.

Ripening Protocol:
Upon arrival in the ripening room, boxes should be selected from the middle of each pallet and the pulp temperature of a fruit from each box checked. (It should be around 16˚C). The stage of maturity should be determined visually or with a pair of calipers. Individual fingers should be between light three-quarter and full three-quarter size. Over-sized fruit ripens rapidly and should be handled with great care because the peel can easily split during handling, while under-sized fruit will not ripen normally.

After determining the maturity, pallets are placed in the ripening room and the air circulation system turned on. The fruit is heated or cooled to the desired ripening temperature (14˚C-18˚C; do not exceed 20˚C pulp temperature during the ripening cycle). Temperature controls the rate of ripening and high temperatures will result in ‘green’ ripening, i.e. softening of the pulp without de-greening of the peel. As soon as the pulp has reached the set temperature, ethylene is introduced into the ripening room with an ethylene generator or bottled ethylene to maintain the levels at 100 ppm for a duration of 24 hours. After ethylene treatment, the room should be vented to get rid of excess ethylene and CO2. Thereafter, the rooms should be vented at least twice per day for 20 minutes or continuously with exhaust fans to keep the CO2 levels below 1%. CO2 levels above 1% will inhibit the ripening process.

The fruit should be kept at the required temperature until it has reached the desired stage of ripeness (firmness). Pulp temperatures must be recorded throughout the room on a daily basis and the relative humidity should be kept at 90-95% throughout the ripening cycle. Once the fruit has reached the desired ripeness, it should be cooled down to 14˚C to slow down ripening, and placed in a cold store at 14˚C. Ripened fruit are less prone to chilling injury than unripe fruit. Further ripening after storage can be controlled by time and temperature. The higher the pulp temperature, the shorter is the time required to reach eat ripeness. The pulp temperature should never be allowed to rise above 20˚C during ripening. Please see Table 1.

Table 1: Fruit pulp temperature (⁰C)

Days in the ripening room
Ripening Schedule
First
Second
Third
Fourth
Fifth
Sixth
Seventh
Eighth
Ninth
4 days
18 ethylene
18
16.5
15.5
Store at 14.5




5 days
16.5 ethylene
16.5
16.5
16.5
16.5
Store at 14.5



6 days
16.5 ethylene
16.5
15.5
15.5
15.5
14.5
Store at 14.5


7 days
15.5 ethylene
15.5
15.5
15.5
15.5
14.5
14.5
Store at 14.5

8 days
14.5 ethylene
14.5
14.5
14.5
14.5
14.5
14.5
14.5
14.5

Uneven Ripening:
Uneven ripening in a box, pallet or load is a common problem encountered in fruit that are ripened after harvesting. The most common causes of uneven ripening are improper ripening techniques, insufficient ethylene levels, incorrect exposure time, incorrect ripening temperature, RH below 90%, temperatures above 21˚C during ripening, improper air circulation, excessive holding periods before the start of the ripening cycle, variable fruit age, variable fruit maturity, wide variations in pulp temperature upon arrival at the ripening room, exposure to temperatures below 12˚C prior to ripening and exposure to extreme high temperatures prior to ripening (heat damage).

Conclusion:
Fruit ripening chambers are proliferating throughout the country as the fruit handler community has realized the importance of deploying a scientific method for ripening in a cold room, exercising control over temperature, RH and gas levels of ethylene, CO2 and oxygen. A revolution has taken place in this sector during last the five years, as ripening chambers have reached even the smallest villages and farms. Refrigeration engineers play an important role in setting up these facilities.
This sector has a vast potential for rural employment generation. National Horticulture Board (NHB) India offers handsome incentives of 35% to 50 % for setting up ripening and cold preservation chambers for all fruits and vegetables and other agricultural produce.