Organic Livestock and Poultry Farming

Organic Livestock and Poultry Farming

BY  CABMELA  ABAYGAR

Here’s an in-depth look at the world of organic farming for both livestock and organic.

Organic farmers should promote animal well-being throughout the farm. This may be done by minimizing physical and psychological stress on the animals and reducing the incidence of disease. Also, when animals are not stressed, veterinary bills are reduced and meat tenderness is maintained.

Pain  and stress relief Conventional farming practices such as castrating, marking and mulesing, if it cannot be avoided, should be kept to a minimum.

Physical alternations should be provided as needed to promote the animal’s welfare and in a manner that reduces pain and stress. Anesthetics lidocaine and procaine are allowed to be used for pain reduction. Chlorohexidine is also allowed for surgical procedures conducted by a veterinarian, as well as a number of other topical disinfectants.

Also, stress during handling can be minimized by reducing noise and not rushing stock through gateways.

Animals also experience stress when in transport going to market and during slaughter. Stress must be minimized during this period. Slaughter must be done quickly and without unnecessary stress. Animals should not be placed in an area where slaughter of other animals can be seen.

Living conditions

The farm should have living conditions for animals such that their needs for free movement, food, water, shelter and shade are provided. Also, the farmer must be aware of the animals’ specific natural behavior patterns. Living conditions that accommodate the health and natural behavior of the animals should be provided. Continue reading “Organic Livestock and Poultry Farming”

GMO Cabbage

GMO Cabbage:

One Component of Sustainable Pest Control

 

Bacillus thurengiensis (BT) is a natural bacterium that is widely used as a safe and effective pesticide.

 

Current approaches used by farmers to control pests in cabbage crops are failing. More pests are emerging, pesticide abuse is rampant, and pesticide residues are often detected on cabbage at the market. In response, the Indian Council of Agricultural Research (ICAR) called a meeting to discuss innovative and sustainable approaches to cabbage pest control. Representatives from environmental, regulatory, research and consumer communities in India attended.

            Dr. O.P. Dubey of ICAR presented the background to the issues faced. He reported that the number of pests attacking cabbage in India has increased from 10 to 38 since 1920. This is despite the use of pesticides, pheromone traps, trap crops, pest-resistant varieties, and other pest management strategies. Although the volume of pesticides used in India has declined from 75,000 MT in 1990-91 to 43,600 MT in 2001-01, pesticide abuse is rampant and pesticide residues persist as a major problem (12% of vegetables at the market have unacceptable levels of residues).

Continue reading “GMO Cabbage”

Agro-industrial waste enriches soil for corn

Agro-industrial waste enriches soil for corn
by Rita T. de la Cruz
January-March 2004
Bar Digest

There’ s money in waste. This is an old adage but for the farmers living in Northern Mindanao, this statement becomes a turning point in their agricultural activities as researchers from the Northern Mindanao Integrated Agricultural Research Center (NOMIARC) developed the most recent and effective balanced fertilization program that could turn corn soil from infertile to productive.

Corn is one of the most important agricultural products in Northern Mindanao but due to the infertile soil, most corn growers have to resort to chemical fertilizers to provide the nutrient needed throughout the crop’s growing period. These are expensive and destructive to health and the environment. Moreover, soil acidity has become the most serious constraints for corn growers in Northern Mindanao. Continue reading “Agro-industrial waste enriches soil for corn”

The potentials of Organic Pesticides

The potentials of Organic pesticides

By: O.Q. Ballesteros

Greenfields March 1993

Because of the high toxicity of chemical pesticides, alternative pest control methods should be explored.

Everyone agrees that chemical pesticides are necessary evil. We need these chemical compounds to protect our crops from pest. For instance, in irrigated rice fields that are not protected with pesticides, the insect pest damage could go up to as high it could. 

As far as unwanted plant or weeds are concerned, the estimated yield reduction is 34 percent in transplanted rice, 40 percent in direct-seeded, rainfall lowland rice; and 67 percent in upland rice.

The pesticide market.

Because of the importance of pesticides in crop production, the sale of synthetic or chemical pesticides increased yearly from 1977 to 1991, according to the Agricultural Pesticide Institute of the Philippines or APIP. In 1977, the total sale of insecticides, herbicides, fungicides and other “icides” amounted to 252.3 million pesos. Ten years later, the total sale was more than 1.5 billion pesos.

Significantly, more than 50 percent of the insecticides and herbicides purchased by farmers went to rice protection, while 60 percent of the fungicides was used to control the diseases of vegetables and fruit crops (bananas, mangoes and pineapple). Other pesticides used included, rodenticides, miticides , molluscicides and fumigants. Except for molluscicides (chemical used to control snails in ricefields and fishponds), other “icides” are generally used to protect plantation crops like sugarcane, pineapple and bananas.

Today, there is a growing awareness of the dangers posed by chemical or inorganic pesticides to the health of people and the safety of the environment. This situation has prompted government authorities to regulate and ban the use of hardly biodegradable pesticides like the chlorinated hydrocarbons (DDT, edrin) and the tin compounds. Other toxic chemicals will ultimately be banned for agricultural use pending the use of effective substitutes that originate from organic or synthetic sources.

It must  be stressed that crop protection can be attained by other methods, including proper cultural management, use of resistant crop varieties, us of beneficial insects and predators, and more effective implementation of the integrated pest management program (IPM) emphasizes the use of existing biological control agents and resistant crop varieties as well as combinations of compatible farm management practices which include the judicious use of pesticides based on the economic threshold level. Economic threshold level (ETL) refers to the level of insect population in a certain field situation at which the cost of control would roughly equal the value of crop loss.

Proper cultural management is another method of pest control. It is intended to make the environment less favorable for pest reproduction, dispersal and survival. Among these practices are thorough land preparation, adjustment of planting dates, good water management, field sanitation, and crop rotation.

Constraints of botanical pesticides. Because of the exceedingly high toxicity of chemical pesticides, alternative pesticide sources should be explored and biologically evaluated for their efficacy and economy. Among the potential plant sources are tobacco, derris, nami, or scientifically called Dioscorea hispida, neem or Azadirachta indica, mariold, chili and other plants with pesticidal properties.

Despite the hihly effective pesticidal properties of tobacco as a source of nicotine sulfate and derris because of its rotenone content, commercial production of these compounds are still not a reality. This may be attributed to inadequate raw material supply  (especially) derris which is not generally cultivated or produce), lack of incentives to processors and lack of competitiveness with regard to product quality compared with synthetic or chemical materials. Nevertheless, it may be worthwhile to assess the commercial value of these botanical sources. Limited technology is available but it may not be areal hindrance to commercialization since it requires sometime to produce large quantities or raw materials. Hopefully, the technology could be fully established by the time the material are available.

Producing the raw materials . Government efforts to develop the countryside can trigger enormous entrepreneurial interest in the production of botanical pesticides. A non-government organization may spearhead this livelihood project by entering into contract growing arrangements with farmers. The NGO could serve as the linkage or conduit of contract growers and processors, marketers and, ultimately, users. The government may provide both technical expertise and initial financing.

With certain pesticidal crops like neem, for example, commercial production could be coordinated with agroforestry projects since the neem tree can be planted on rolling hills, on unproductive lands or areas, and on steep slopes where cultivation of cash crops would accelerate soil erosion. The neem tree does not require much water. In fact, it is not advisable to plant it in waterlogged areas.

All parts of the neem tree are sources of pesticides , but the seed is the richest source, followed by the leaves, then the bark and finally the wood. It takes three to four years from germination to flowering. The tree flowers twice a year, i.e. March and September. The seeds can be harvested from June to July or four to five months after flowering. AN average tree can produce as much as 350 kilogram of green leaves annually and about 50 kilograms of fruit. From 50 kilograms of fruit about 30 kilograms of seeds and 60 % are recoverable. The 30 kilograms of oil could be extracted and 24 to 27 could be made into neem cake.

Neem extracts from leaves and fruits have strong insect repellant properties. Oil from the seed can repel termites and nematodes. It also affects the food intake of insects and cause abnormal insect molting. Because of its various uses, neem derived pesticides can be classified as “broad spectrum.” Continue reading “The potentials of Organic Pesticides”