User:WAS 4.250/3

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Intensive agriculture is an agricultural production system characterized by the high inputs of capital or labour relative to land area.[1][2] This is in contrast to the concept of Extensive Agriculture which involves a low input of materials and labour with the crop yield depending largely on the naturally available soil fertility, water supply or other land qualities.[3]

A potato field
A potato field

Modern day forms of intensive crop based agriculture involve the use of mechanical ploughing, chemical fertilizers, herbicides, fungicides, insecticides, plant growth regulators and/or pesticides. It is associated with the increasing use of agricultural mechanization, which have enabled a substantial increase in production.[1]

Intensive animal farming practices can involve very large numbers of animals raised on limited land which require large amounts of food, water and medical inputs (required to keep the animals healthy in cramped conditions[citation needed]).[2]. Very large or confined indoor intensive livestock operations (particularly descriptive of common US farming practices) are often referred to as Factory farming[4][1][5] and are criticised by opponents for the low level of animal welfare standards[5][6] and associated pollution and health issues.[7][8]

Intensive agriculture significantly increases yield per available space.[9]

Intensive farming alters the environment in many ways.

  • Removal of buffers to make large fields for maximum efficiency leading to lower food costs and greater food availability to the poor. But it also limits the natural habitat of some wild creatures and can lead to soil erosion. [citation needed]
  • Use of fertilizers can alter the biology of rivers and lakes.[8] Some environmentalists attribute the hypoxic zone in the Gulf of Mexico as being encouraged by nitrogen fertilization of the algae bloom. [citation needed]
  • Pesticides can kill useful insects as well as the those that destroy crops.
  • Most farmers today, including farmers practicing intensive farming, use practices to improve the environment on and around their farming operation. This includes buffer strips, riparian buffers, land held in the Conservation Reserve Program (CRP), and use of best management practices.
  • Over the years, farmers have changed their practices to include soil saving management techniques such no-till, which limits the level of tillage on the ground and maintains a level of crop residue on the surface to minimize soil erosion.

Contents

[edit] Pre modern intensive farming

Pre modern intensive farming techniques and structures include terracing, rice paddies, and various forms of aquaculture.

[edit] Oysters

"Oysters were likely the first sea animal to be transported from one area to another and cultivated as food. The ancient world, while knowing little about the reproduction of oysters, knew much about the conditions necessary for their growth. Pliny the Elder, a noted Roman naturalist of the first century, has left an account of artificial oyster beds established in Lake Lucrinus near Naples by a Sergius Orata about 95 B.C. Orata's methods consisted of preparing the grounds by removing other forms of marine life, planting seed oysters, cultivating the oysters by keeping them separated in order to grow to a well-formed, mature size, and finally harvesting them when they were ready for market. Modern oyster farming, based on the knowledge of oyster biology, basically follows the Roman procedure."[10]

[edit] Terrace

Main article: Terrace (agriculture)

In agriculture, a terrace is a leveled section of a hilly cultivated area, designed as a method of soil conservation to slow or prevent the rapid surface runoff of irrigation water. Often such land is formed into multiple terraces, giving a stepped appearance. The human landscapes of rice cultivation in terraces that follow the natural contours of the escarpments like contour plowing is a classic feature of the island of Bali and the Banaue Rice Terraces in Benguet, Philippines. In Peru, the Inca made use of otherwise unusable slopes by drystone walling to create terraces.

[edit] Rice paddy

Main article: Paddy field

A paddy field is a flooded parcel of arable land used for growing rice and other semiaquatic crops. Paddy fields are a typical feature of rice-growing countries of east and southeast Asia including Malaysia, China, Sri Lanka, Myanmar, Thailand, Korea, Japan, Vietnam, Taiwan, Indonesia, India, and the Philippines. They are also found in other rice-growing regions such as Piedmont (Italy), the Camargue (France) and the Artibonite Valley (Haiti). They can occur naturally along rivers or marshes, or can be constructed, even on hillsides, often with much labor and materials. They require large quantities of water for irrigation, which can be quite complex for a highly developed system of paddy fields. Flooding provides water essential to the growth of the crop. It also gives an environment favourable to the strain of rice being grown, and is hostile to many species of weeds. As the only draft animal species which is adapted for life in wetlands, the water buffalo is in widespread use in Asian rice paddies. There are significant adverse environmental impacts from rice paddy cultivation due to the generation of large quantities of methane gas. World methane production due to rice paddies has been estimated in the range of 50 to 100 million tonnes per annum;[11] this level of greenhouse gas generation is a large component of the global warming threat and derives simply from an expanding human population.

Rice-farming and the use of paddies in Korea is ancient. Korean paddy-farming can provide cultural background on the use of paddies in Northeast Asia. A pit-house at the Daecheon-ni site yielded carbonized rice grains and radiocarbon dates indicating that rice cultivation may have begun as early as the Middle Jeulmun Pottery Period (c. 3500-2000 B.C.) in the Korean Peninsula (Crawford and Lee 2003). The earliest rice cultivation in the Korean Peninsula may have used dry-fields instead of paddies.

The earliest Mumun features were usually located in low-lying narrow gulleys that were naturally swampy and fed by the local stream system. Some Mumun paddies in flat areas were made of a series of squares and rectangles separated by bunds approximately 10 cm in height, while terraced paddies consisted of long irregularly shapes that followed natural contours of the land at various levels (Bale 2001; Kwak 2001).

Mumun Period rice farmers used all of the elements that are present in today's paddies such terracing, bunds, canals, and small reservoirs. We can grasp some paddy-farming techniques of the Middle Mumun (c. 850-550 B.C.) from the well-preserved wooden tools excavated from archaeological rice paddies at the Majeon-ni Site. However, iron tools for paddy-farming were not introduced until sometime after 200 B.C. The spatial scale of individual paddies, and thus entire paddy-fields, increased with the regular use of iron tools in the Three Kingdoms of Korea Period (c. A.D. 300/400-668).

[edit] Modern intensive farming

Industrial agriculture is a modern form of intensive farming that refers to the industrialized production of crops and livestock, including cattle, poultry (in "battery farms") and fish. Industrial agriculture's methods are technoscientific, economic, and political. They include innovation in agricultural machinery, farming methods, genetic technology, techniques for achieving economies of scale in production, the creation of new markets for consumption, patent protection of genetic information, and global trade. These methods are widespread in developed nations. Most of the meat, dairy, eggs, and crops available in supermarkets are produced by industrialized agriculture.

[edit] History

The practice of industrial agriculture is a relatively recent development in the history of agriculture, and the result of scientific discoveries and technological advances. Innovations in agriculture beginning in the late 1800s generally parallel developments in mass production in other industries that characterized the latter part of the Industrial Revolution. The identification of nitrogen and phosphorus as critical factors in plant growth led to the manufacture of synthetic fertilizers, making possible more intensive types of agriculture. The discovery of vitamins and their role in animal nutrition, in the first two decades of the 20th century, led to vitamin supplements, which in the 1920s allowed certain livestock to be raised indoors, reducing their exposure to adverse natural elements. The discovery of antibiotics and vaccines facilitated raising livestock in larger numbers by reducing disease. Chemicals developed for use in World War II gave rise to synthetic pesticides. Developments in shipping networks and technology have made long-distance distribution of agricultural produce feasible.

[edit] Sustainable agriculture

Sustainable agriculture is a subset of industrial agriculture that integrates three main goals: environmental stewardship, farm profitability, and prosperous farming communities. These goals have been defined by a variety of disciplines and may be looked at from the vantage point of the farmer or the consumer.

[edit] Crops

[edit] Features

  • large scale — hundreds or thousands of acres of a single crop (much more than can be absorbed into the local or regional market);
  • monoculture — large areas of a single crop, often raised from year to year on the same land, or with little crop rotation;
  • agrichemicals — reliance on imported, synthetic fertilizers and pesticides to provide nutrients and to mitigate pests and diseases, these applied on a regular schedule; the use of fertilizer recycled from toxic waste and other hazardous industrial byproducts is common in the US.[12]
  • hybrid seed — use of specialized hybrids designed to favor large scale distribution (e.g. ability to ripen off the vine, to withstand shipping and handling);
  • genetically engineered crops — use of genetically modified varieties (GMOs) designed for large scale production (e.g. ability to withstand selected herbicides);
  • large scale irrigation — heavy water use, and in some cases, growing of crops in otherwise unsuitable regions by extreme use of water (e.g. rice paddies on arid land).
  • high mechanization — automated machinery sustain and harvest crops.

[edit] Criticism

Critics of intensively farmed crops cite a wide range of concerns. On the food quality front, it is held by critics that quality is reduced when crops are bred and grown primarily for cosmetic and shipping characteristics. Environmentally, factory farming of crops is claimed to be responsible for loss of biodiversity, degradation of soil quality, soil erosion, food toxicity (pesticide residues) and pollution (through agrichemical build-ups and runoff, and use of fossil fuels for agrichemical manufacture and for farm machinery and long-distance distribution).

[edit] History

Main article: Green Revolution

The projects within the Green Revolution spread technologies that had already existed, but had not been widely used outside of industrialized nations. These technologies included pesticides, irrigation projects, and synthetic nitrogen fertilizer.

The novel technological development of the Green Revolution was the production of what some referred to as “miracle seeds.” [13] Scientists created strains of maize, wheat, and rice that are generally referred to as HYVs or “high yielding varieties.” HYVs have an increased nitrogen-absorbing potential compared to other varieties. Since cereals that absorbed extra nitrogen would typically lodge, or fall over before harvest, semi-dwarfing genes were bred into their genomes. Norin 10 wheat, a variety developed by Orville Vogel from Japanese dwarf wheat varieties, was instrumental in developing Green Revolution wheat cultivars. IR8, the first widely implemented HYV rice to be developed by IRRI, was created through a cross between an Indonesian variety named “Peta” and a Chinese variety named “Dee Geo Woo Gen.”[14]

With the availability of molecular genetics in Arabidopsis and rice the mutant genes responsible (reduced height(rht), gibberellin insensitive (gai1) and slender rice (slr1)) have been cloned and identified as cellular signalling components of gibberellic acid, a phytohormone involved in regulating stem growth via its effect on cell division. Stem growth in the mutant background is significantly reduced leading to the dwarf phenotype. Photosynthetic investment in the stem is reduced dramatically as the shorter plants are inherently more stable mechanically. Assimilates become redirected to grain production, amplifying in particular the effect of chemical fertilisers on commercial yield.

HYVs significantly outperform traditional varieties in the presence of adequate irrigation, pesticides, and fertilizers. In the absence of these inputs, traditional varieties may outperform HYVs. One criticism of HYVs is that they were developed as F1 hybrids, meaning they need to be purchased by a farmer every season rather than saved from previous seasons, thus increasing a farmer’s cost of production.

[edit] Examples

[edit] Wheat (Modern management techniques)
Main article: Wheat

Wheat is a grass that is cultivated worldwide. Globally, it is the most important human food grain and ranks second in total production as a cereal crop behind maize; the third being rice. Wheat and barley were the first cereals known to have been domesticated. Cultivation and repeated harvesting and sowing of the grains of wild grasses led to the domestication of wheat through selection of mutant forms with tough ears which remained intact during harvesting, and larger grains. Because of the loss of seed dispersal mechanisms, domesticated wheats have limited capacity to propagate in the wild.[15]

Agricultural cultivation using horse collar leveraged plows (3000 years ago) increased cereal grain productivity yields, as did the use of seed drills which replaced broadcasting sowing of seed in the 18th century. Yields of wheat continued to increase, as new land came under cultivation and with improved agricultural husbandry involving the use of fertilizers, threshing machines and reaping machines (the 'combine harvester'), tractor-draw cultivators and planters, and better varieties (see green revolution and Norin 10 wheat). With population growth rates falling, while yields continue to rise, the acreage devoted to wheat may now begin to decline for the first time in modern human history.[16]

Organic wheat typically halves yield attainable but costs less as there are no fertiliser and pesticide costs. Seed costs are typically higher, however, and arguably labour and machinery costs are higher as the organic crop, and more importantly the whole rotation and cropping on such a farm, is more difficult to manage correctly.

While winter wheat lies dormant during a winter freeze, wheat normally requires between 110 and 130 days between planting and harvest, depending upon climate, seed type, and soil conditions. Crop management decisions require the knowledge of stage of development of the crop. In particular, spring fertilizers applications, herbicides, fungicides, growth regulators are typically applied at specific stages of plant development. For example, current recommendations often indicate the second application of nitrogen be done when the ear (not visible at this stage) is about 1 cm in size (Z31 on Zadoks scale).

[edit] Maize (Mechanical harvesting)
Main article: Maize

Maize was planted by the Native Americans in hills, in a complex system known to some as the Three Sisters: beans used the corn plant for support, and squashes provided ground cover to stop weeds. This method was replaced by single species hill planting where each hill 60–120 cm (2–4 ft) apart was planted with 3 or 4 seeds, a method still used by home gardeners. A later technique was checked corn where hills were placed 40 inches apart in each direction, allowing cultivators to run through the field in two directions. In more arid lands this was altered and seeds were planted in the bottom of 10–12 cm (4–5 in) deep furrows to collect water. Modern technique plants maize in rows which allows for cultivation while the plant is young, although the hill technique is still used in the cornfields of some Native American reservations.

A corn heap at the harvest site, India
A corn heap at the harvest site, India

In North America, fields are often planted in a two-crop rotation with a nitrogen-fixing crop, often alfalfa in cooler climates and soybeans in regions with longer summers. Sometimes a third crop, winter wheat, is added to the rotation. Fields are usually plowed each year, although no-till farming is increasing in use. Many of the maize varieties grown in the United States and Canada are hybrids. Over half of the corn acreage planted in the United States has been genetically modified using biotechnology to express agronomic traits such as pest resistance or herbicide resistance.

Before about World War II, most maize in North America was harvested by hand (as it still is in most of the other countries where it is grown). This often involved large numbers of workers and associated social events. Some one- and two-row mechanical pickers were in use but the corn combine was not adopted until after the War. By hand or mechanical picker, the entire ear is harvested which then requires a separate operation of a corn sheller to remove the kernels from the ear. Whole ears of corn were often stored in corn cribs and these whole ears are a sufficient form for some livestock feeding use. Few modern farms store maize in this manner. Most harvest the grain from the field and store it in bins. The combine with a corn head (with points and snap rolls instead of a reel) does not cut the stalk; it simply pulls the stalk down. The stalk continues downward and is crumpled in to a mangled pile on the ground. The ear of corn is too large to pass through a slit in a plate and the snap rolls pull the ear of corn from the stalk so that only the ear and husk enter the machinery. The combine separates the husk and the cob, keeping only the kernels.

[edit] Soybean (Genetic modification)
Main article: Soybean

Soybeans are one of the "biotech food" crops that are being genetically modified, and GMO soybeans are being used in an increasing number of products. Monsanto is the world's leader in genetically modified soy for the commercial market. In 1995, Monsanto introduced "Roundup Ready" (RR) soybeans that have had a copy of a gene from the bacterium, Agrobacterium sp. strain CP4, inserted, by means of a gene gun, into its genome that allows the transgenic plant to survive being sprayed by this non-selective herbicide, glyphosate. Glyphosate, the active ingredient in Roundup, kills conventional soybeans. The bacterial gene is EPSP (= 5-enolpyruvyl shikimic acid-3-phosphate) synthase. Soybean also has a version of this gene, but the soybean version is sensitive to glyphosate, while the CP4 version is not.[17]

RR soybeans allow a farmer to reduce tillage or even to sow the seed directly into an unplowed field, known as 'no-till' or conservation tillage. No-till agriculture has many advantages, greatly reducing soil erosion and creating better wildlife habitat;[18] it also saves fossil fuels, and sequesters CO2, a greenhouse effect gas.[19]

In 1997, about 8% of all soybeans cultivated for the commercial market in the United States were genetically modified. In 2006, the figure was 89%. As with other "Roundup Ready" crops, concern is expressed over damage to biodiversity.[20] However, the RR gene has been bred into so many different soybean cultivars that the genetic modification itself has not resulted in any decline of genetic diversity.[21]

[edit] Tomato (Hydroponics)
Main article: Hydroponics

The largest commercial hydroponics facility in the world is Eurofresh Farms in Willcox, Arizona, which sold 125 million pounds of tomatoes in 2005.[22] Eurofresh has 256 acres under glass and represents about a third of the commercial hydroponic greenhouse area in the U.S. [23] Eurofresh does not consider their tomatoes organic, but they are pesticide-free. They are grown in rockwool with top irrigation.

Some commercial installations use no pesticides or herbicides, preferring integrated pest management techniques. There is often a price premium willingly paid by consumers for produce which is labeled "organic". Some states in the USA require soil as an essential to obtain organic certification. There are also overlapping and somewhat contradictory rules established by the US Federal Government. So some food grown with hydroponics can be certified organic. In fact, they are the cleanest plants possible because there is no environment variable and the dirt in the food supply is extremely limited. Hydroponics also saves an incredible amount of water; It uses as little as 1/20 the amount as a regular farm to produce the same amount of food. The water table can be impacted by the water use and run-off of chemicals from farms, but hydroponics may minimize impact as well as having the advantage that water use and water returns are easier to measure. This can save the farmer money by allowing reduced water use and the ability to measure consequences to the land around a farm.

The environment in a hydroponics greenhouse is tightly controlled for maximum efficiency and this new mindset is called Soil-less/Controlled Environment Agriculture (S/CEA). With this growers can make ultra-premium foods anywhere in the world, regardless of temperature and growing seasons. Growers monitor the temperature, humidity, and pH level constantly.

[edit] Animals

Industrial agriculture for animal production focuses on maximizing returns. Different methods may be used to meet the ideal end of maximum results. For example, factory farming, a subset of industrial agriculture[24] that is also known as confined animal feeding operations (CAFOs),[25], describes the raising of farm animals indoors under conditions of extremely restricted mobility[26] as part of a set of methods designed to produce the highest output at the lowest cost, using economies of scale, modern machinery, modern medicine, and global trade for financing, purchases and sales.[27][28] Concentrated animal feeding operations,[29] are general examples of factory farms. Industrial animal agriculture may also encompass intensive livestock operations (ILOs) and other practices.[30]

Industrial agriculture is widespread in developed nations. According to the Worldwatch Institute, 74 percent of the world's poultry, 43 percent of beef, and 68 percent of eggs are produced this way.[25] In the U.S., four companies produce 81 percent of cows, 73 percent of sheep, 60 percent of pigs, and 50 percent of chickens;[31] according to its National Pork Producers Council, 80 million of its 95 million pigs slaughtered each year are reared in industrial settings.[32] Proponents of industrial agriculture argue for the benefits of increased efficiencies, while opponents argue that it harms the environment,[33] creates health risks,[34][29][35] and abuses animals.[36][33]

"Confined animal feeding operations" or "intensive livestock operations" or "factory farms" can hold large numbers (some up to hundreds of thousands) of animals, often indoors. These animals are typically cows, hogs, turkeys, or chickens. The distinctive characteristics of such farms is the concentration of livestock in a given space. The aim of the operation is to produce as much meat, eggs, or milk at the lowest possible cost.

Food is supplied in place, and artificial methods are often employed to maintain animal health and improve production, such as therapeutic use of antimicrobial agents, vitamin supplements and growth hormones. In meat production, mechanical methods are also sometimes employed, such as de-beaking of chickens and physical restraints, to control undesirable behaviours.

The designation "confined animal feeding operation" in the U.S. resulted from that country's 1972 Federal Clean Water Act, which was enacted to protect and restore lakes and rivers to a "fishable, swimmable" quality. The United States Environmental Protection Agency (EPA) identified certain animal feeding operations, along with many other types of industry, as point source polluters of groundwater. These operations were designated as CAFOs and subject to special anti-pollution regulation.[37]

One challenge associated with CAFOs is waste management. In 24 states in the U.S., isolated cases of groundwater contamination has been linked to CAFOs.[citation needed] For example, the ten million hogs in North Carolina generate 19 million tons of waste per year.[citation needed] The U.S. federal government requires that animal waste be stored in lagoons rather than simply applied to land. Lagoons must be protected with an impermeable liner to prevent leakage of waste into groundwater. Lagoons must be maintained and managed, however; a lagoon that burst in 1995 released 25 million gallons of nitrous sludge in North Carolina's New River. The spill allegedly killed eight to ten million fish.[38]

The large concentration of animals, animal waste, and dead animals in a small space poses ethical issues.[citation needed] Animal rights and animal welfare activists have charged that intensive animal rearing is cruel to animals. As they become more common, so do concerns about air pollution and ground water contamination, and the effects on human health of the pollution and the use of antibiotics and growth hormones.

One particular concern with farms on which animals are intensively reared is the growth of antibiotic-resistant bacteria. Because large numbers of animals live in close proximity, any disease would spread quickly, and so antibiotics are used preventively. A small percentage of bacteria are not killed by the drugs, which may infect human beings if it becomes airborne.

According to the U.S. Centers for Disease Control and Prevention (CDC), some farms on which animals are intensively reared can cause adverse health reactions in farm workers.[citation needed] Workers may develop acute and chronic lung disease, musculoskeletal injuries, and may catch infections that transmit from animals to human beings.[citation needed]

The CDC writes that chemical, bacterial, and viral compounds from animal waste may travel in the soil and water.

Some residents near industrial farms report nuisances such as odors and insect concentrations.

The CDC has identified a number of pollutants associated with the discharge of animal waste into rivers and lakes, and into the air. The use of antibiotics may create antibiotic-resistant pathogens; parasites, bacteria, and viruses may be spread; ammonia, nitrogen, and phosphorus can reduce oxygen in surface waters and contaminate drinking water; pesticides and hormones may cause hormone-related changes in fish; animal feed and feathers may stunt the growth of desirable plants in surface waters and provide nutrients to disease-causing micro-organisms; trace elements such as arsenic and copper, which are harmful to human health, may contaminate surface waters.

[edit] Aquaculture

Main article: Aquaculture

Aquaculture is the cultivation of the natural produce of water (fish, shellfish, algae and other aquatic organisms). The term is distinguished from fishing by the idea of active human effort in maintaining or increasing the number of organisms involved, as opposed to simply taking them from the wild. Subsets of aquaculture include Mariculture (aquaculture in the ocean); Algaculture (the production of kelp/seaweed and other algae); Fish farming (the raising of catfish, tilapia and milkfish in freshwater And Brackish ponds or salmon in marine ponds); and the growing of cultured pearls. Extensive aquaculture is based on local photosynthetical production while intensive aquaculture is based on fish fed with an external food supply.

Aquaculture has been used since ancient times and can be found in many cultures. Aquaculture was used in China circa 2500 BC. When the waters lowered after river floods, some fishes, namely carp, were held in artificial lakes. Their brood were later fed using nymphs and silkworm feces, while the fish themselves were eaten as a source of protein. The Hawaiian people practiced aquaculture by constructing fish ponds (see Hawaiian aquaculture). A remarkable example from ancient Hawaii is the construction of a fish pond, dating from at least 1,000 years ago, at Alekoko. According to legend, it was constructed by the mythical Menehune. The Japanese practiced cultivation of seaweed by providing bamboo poles and, later, nets and oyster shells to serve as anchoring surfaces for spores. The Romans often bred fish in ponds.

The practice of aquaculture gained prevalence in Europe during the Middle Ages, since fish were scarce and thus expensive. However, improvements in transportation during the 19th century made fish easily available and inexpensive, even in inland areas, causing a decline in the practice. The first North American fish hatchery was constructed on Dildo Island, Newfoundland Canada in 1889, it was the largest and most advanced in the world.

Americans were rarely involved in aquaculture until the late 20th century, but California residents harvested wild kelp and made legal efforts to manage the supply starting circa 1900, later even producing it as a wartime resource. (Peter Neushul, Seaweed for War: California's World War I kelp industry, Technology and Culture 30 (July 1989), 561-583)

Example of self made recirculation  Aquaculture system
Example of self made recirculation Aquaculture system

In contrast to agriculture, the rise of aquaculture is a contemporary phenomenon. According to professor Carlos M. Duarte About 430 (97%) of the aquatic species presently in culture have been domesticated since the start of the 20th century, and an estimated 106 aquatic species have been domesticated over the past decade. The domestication of an aquatic species typically involves about a decade of scientific research. Current success in the domestication of aquatic species results from the 20thcentury rise of knowledge on the basic biology of aquatic species and the lessons learned from past success and failure. The stagnation in the world's fisheries and overexploitation of 20 to 30% of marine fish species have provided additional impetus to domesticate marine species, just as overexploitation of land animals provided the impetus for the early domestication of land species

In the 1960s, the price of fish began to climb, as wild fish capture rates peaked and the human population continued to rise. Today, commercial aquaculture exists on an unprecedented, huge scale. In the 1980s, open-netcage salmon farming also expanded; this particular type of aquaculture technology remains a minor part of the production of farmed finfish worldwide, but possible negative impacts on wild stocks, which have come into question since the late 1990s, have caused it to become a major cause of controversy.[6]

In 2003, the total world production of fisheries product was 132.2 million tonnes of which aquaculture contributed 41.9 million tonnes or about 31% of the total world production. The growth rate of worldwide aquaculture is very rapid (> 10% per year for most species) while the contribution to the total from wild fisheries has been essentially flat for the last decade.

In the US, approximately 90% of all shrimp consumed is farmed and imported.[7] In recent years salmon aquaculture has become a major export in southern Chile, especially in Puerto Montt and Quellón, Chile's fastest-growing city.

Farmed fish are kept in concentrations never seen in the wild (e.g. 50,000 fish in a two-acre area.[39]) with each fish occupying less room than the average bathtub. This can cause several forms of pollution. Packed tightly, fish rub against each other and the sides of their cages, damaging their fins and tails and becoming sickened with various diseases and infections.[40]

Some species of sea lice have been noted to target farmed coho and farmed Atlantic salmon specifically.[41] Such parasites may have an effect on nearby wild fish. For these reasons, aquaculture operators frequently need to use strong drugs to keep the fish alive (but many fish still die prematurely at rates of up to 30%[42]) and these drugs inevitably enter the environment.

The lice and pathogen problems of the 1990's facilitated the development of current treatment methods for sea lice and pathogens. These developments reduced the stress from parasite/pathogen problems. However, being in an ocean environment, the transfer of disease organisms from the wild fish to the aquaculture fish is an ever-present risk factor.[43].

The very large number of fish kept long-term in a single location produces a significant amount of condensed feces, often contaminated with drugs, which again affect local waterways. However, these effects are very local to the actual fish farm site and are minimal to non-measurable in high current sites.

[edit] Shrimp
Main article: Shrimp farm

A shrimp farm is an aquaculture business for the cultivation of marine shrimp or prawns1 for human consumption. Commercial shrimp farming began in the 1970s, and production grew steeply, particularly to match the market demands of the USA, Japan and Western Europe. The total global production of farmed shrimp reached more than 1.6 million tonnes in 2003, representing a value of nearly 9,000 million U.S. dollars. About 75% of farmed shrimp is produced in Asia, in particular in China and Thailand. The other 25% is produced mainly in Latin America, where Brazil is the largest producer. The largest exporting nation is Thailand.

Shrimp farming has changed from traditional, small-scale businesses in Southeast Asia into a global industry. Technological advances have led to growing shrimp at ever higher densities, and broodstock is shipped world-wide. Virtually all farmed shrimp are penaeids (i.e., shrimp of the family Penaeidae), and just two species of shrimp—the Penaeus vannamei (Pacific white shrimp) and the Penaeus monodon (giant tiger prawn)—account for roughly 80% of all farmed shrimp. These industrial monocultures are very susceptible to diseases, which have caused several regional wipe-outs of farm shrimp populations. Increasing ecological problems, repeated disease outbreaks, and pressure and criticism from both NGOs and consumer countries led to changes in the industry in the late 1990s and generally stronger regulation by governments. In 1999, a program aimed at developing and promoting more sustainable farming practices was initiated, including governmental bodies, industry representatives, and environmental organizations.

[edit] Chickens

Main article: chicken
Free range chickens
Free range chickens

In the United States, chickens were raised primarily on family farms until roughly 1960. Originally, the primary value in poultry was eggs, and meat was considered a byproduct of egg production. Its supply was less than the demand, and poultry was expensive. Except in hot weather, eggs can be shipped and stored without refrigeration for some time before going bad; this was important in the days before widespread refrigeration.

Farm flocks tended to be small because the hens largely fed themselves through foraging, with some supplementation of grain, scraps, and waste products from other farm ventures. Such feedstuffs were in limited supply, especially in the winter, and this tended to regulate the size of the farm flocks. Soon after poultry keeping gained the attention of agricultural researchers (around 1896), improvements in nutrition and management made poultry keeping more profitable and businesslike.

Prior to about 1910, chicken was served primarily on special occasions or Sunday dinner. Poultry was shipped live or killed, plucked, and packed on ice (but not eviscerated). The "whole, ready-to-cook broiler" wasn't popular until the Fifties, when end-to-end refrigeration and sanitary practices gave consumers more confidence. Before this, poultry were often cleaned by the neighborhood butcher, though cleaning poultry at home was a commonplace kitchen skill.

Two kinds of poultry were generally used: broilers or "spring chickens;" young male chickens, a byproduct of the egg industry, which were sold when still young and tender (generally under 3 pounds live weight), and "stewing hens," also a byproduct of the egg industry, which were old hens past their prime for laying. [44]

The major milestone in 20th century poultry production was the discovery of vitamin D, which made it possible to keep chickens in confinement year-round. Before this, chickens did not thrive during the winter (due to lack of sunlight), and egg production, incubation, and meat production in the off-season were all very difficult, making poultry a seasonal and expensive proposition. Year-round production lowered costs, especially for broilers.

At the same time, egg production was increased by scientific breeding. After a few false starts (such as the Maine Experiment Station's failure at improving egg production[45], success was shown by Professor Dryden at the Oregon Experiment Station[46].

Improvements in production and quality were accompanied by lower labor requirements. In the Thirties through the early Fifties, 1,500 hens was considered to be a full-time job for a farm family. In the late Fifties, egg prices had fallen so dramatically that farmers typically tripled the number of hens they kept, putting three hens into what had been a single-bird cage or converting their floor-confinement houses from a single deck of roosts to triple-decker roosts. Not long after this, prices fell still further and large numbers of egg farmers left the business.

Robert Plamondon[47] reports that the last family chicken farm in his part of Oregon, Rex Farms, had 30,000 layers and survived into the Nineties. But the standard laying house of the current operators is around 125,000 hens.

This fall in profitability was accompanied by a general fall in prices to the consumer, allowing poultry and eggs to lose their status as luxury foods.

The vertical integration of the egg and poultry industries was a late development, occurring after all the major technological changes had been in place for years (including the development of modern broiler rearing techniques, the adoption of the Cornish Cross broiler, the use of laying cages, etc.).

By the late Fifties, poultry production had changed dramatically. Large farms and packing plants could grow birds by the tens of thousands. Chickens could be sent to slaughterhouses for butchering and processing into prepackaged commercial products to be frozen or shipped fresh to markets or wholesalers. Meat-type chickens currently grow to market weight in six to seven weeks whereas only fifty years ago it took three times as long.[48] This is due to genetic selection and nutritional modifications (and not the use of growth hormones, which are illegal for use in poultry in the US and many other countries). Once a meat consumed only occasionally, the common availability and lower cost has made chicken a common meat product within developed nations. Growing concerns over the cholesterol content of red meat in the 1980s and 1990s further resulted in increased consumption of chicken.

Today, eggs are produced on large egg ranches on which environmental parameters are well controlled. Chickens are exposed to artificial light cycles to stimulate egg production year-round. In addition, it is a common practice to induce molting through careful manipulation of light and the amount of food they receive in order to further increase egg size and production.

On average, a chicken lays one egg a day, but not on every day of the year. This varies with the breed and time of year. In 1900, average egg production was 83 eggs per hen per year. In 2000, it was well over 300. In the United States, laying hens are butchered after their second egg laying season. In Europe, they are generally butchered after a single season. The laying period begins when the hen is about 18-20 weeks old (depending on breed and season). Males of the egg-type breeds have little commercial value at any age, and all those not used for breeding (roughly fifty percent of all egg-type chickens) are killed soon after hatching. The old hens also have little commercial value. Thus, the main sources of poultry meat 100 years ago (spring chickens and stewing hens) have both been entirely supplanted by meat-type broiler chickens.

[edit] Pigs

Main article: Intensive pig farming
Intensively farmed pigs in batch pens
Intensively farmed pigs in batch pens

Intensive piggeries (or hog lots) are a type of concentrated animal feeding operation specialized for the raising of domestic pigs up to slaughterweight. In this system of pig production grower pigs are housed indoors in group-housing or straw-lined sheds, whilst pregnant sows are confined in sow stalls (gestation crates) and give birth in farrowing crates.

The use of sow stalls (gestation crates) has resulted in lower production costs, however, this practice has led to more significant animal welfare concerns. Many of the world’s largest producers of pigs (U.S., Canada, Denmark) use sow stalls, but some nations (e.g. the UK) and some US States (e.g. Florida and Arizona) have banned them.

Intensive piggeries are generally large warehouse-like buildings. Indoor pig systems allow the pig’s condition to be monitored, ensuring minimum fatalities and increased productivity. Buildings are ventilated and their temperature regulated. Most domestic pig varieties are susceptible to heat stress, and all pigs lack sweat glands and cannot cool themselves. Pigs have a limited tolerance to high temperatures and heat stress can lead to death. Maintaining a more specific temperature within the pig-tolerance range also maximizes growth and growth to feed ratio. In an intensive operation pigs will lack access to a wallow (mud), which is their natural cooling mechanism. Intensive piggeries control temperature through ventilation or drip water systems (dropping water to cool the system).

Pigs are naturally omnivorous and are generally fed a combination of grains and protein sources (soybeans, or meat and bone meal). Larger intensive pig farms may be surrounded by farmland where feed-grain crops are grown. Alternatively, piggeries are reliant on the grains industry. Pig feed may be bought packaged or mixed on-site. The intensive piggery system, where pigs are confined in individual stalls, allows each pig to be allotted a portion of feed. The individual feeding system also facilitates individual medication of pigs through feed. This has more significance to intensive farming methods, as the close proximity to other animals enables diseases to spread more rapidly. To prevent disease spreading and encourage growth, drug programs such as antibiotics, vitamins, hormones and other supplements are preemptively administered.

Indoor systems, especially stalls and pens (i.e. ‘dry,’ not straw-lined systems) allow for the easy collection of waste. In an indoor intensive pig farm, manure can be managed through a lagoon system or other waste-management system. However, odor remains a problem which is difficult to manage.

The way animals are housed in intensive systems varies. Breeding sows will spend the bulk of their time in sow stalls (also called gestation crates) during pregnancy or farrowing crates, with litter, until market.

Piglets often receive range of treatments including castration, tail docking to reduce tail biting, teeth clipped (to reduce injuring their mother's nipples and prevent later tusk growth) and their ears notched to assist identification. Treatments are usually made without pain killers. Weak runts may be slain shortly after birth.

Piglets also may be weaned and removed from the sows at between two and five weeks old[8] and placed in sheds. However, grower pigs - which comprise the bulk of the herd - are usually housed in alternative indoor housing, such as batch pens. During pregnancy, the use of a stall may be preferred as it facilitates feed-management and growth control. It also prevents pig aggression (e.g. tail biting, ear biting, vulva biting, food stealing). Group pens generally require higher stockmanship skills. Such pens will usually not contain straw or other material. Alternatively, a straw-lined shed may house a larger group (i.e. not batched) in age groups.

Many countries have introduced laws to regulate treatment of farmed animals. In the USA, the federal Humane Slaughter Act[9] requires pigs to be stunned before slaughter, although compliance and enforcement is questioned[citation needed].[10].

[edit] Cattle

Main article: Cattle

Cattle, colloquially referred to as cows, are domesticated ungulates, a member of the subfamily Bovinae of the family Bovidae. They are raised as livestock for meat (called beef and veal), dairy products (milk), leather and as draught animals (pulling carts, plows and the like). In some countries, such as India, they are honored in religious ceremonies and revered. It is estimated that there are 1.4 billion head of cattle in the world today.[49]

Cattle are often raised by allowing herds to graze on the grasses of large tracts of rangeland called ranches. Raising cattle in this manner allows the productive use of land that might be unsuitable for growing crops. The most common interactions with cattle involve daily feeding, cleaning and milking. Many routine husbandry practices involve ear tagging, dehorning, loading, medical operations, vaccinations and hoof care, as well as training for agricultural shows and preparations. There are also some cultural differences in working with cattle- the cattle husbandry of Fulani men rests on behavioural techniques, whereas in Europe cattle are controlled primarily by physical means like fences.[50]

Breeders can utilise cattle husbandry to reduce M. bovis infection susceptibility by selective breeding and maintaining herd health to avoid concurrent disease.[51] Cattle are farmed for beef, veal, dairy, leather and they are sometimes used simply to maintain grassland for wildlife- for example, in Epping Forest, England. They are often used in some of the most wild places for livestock. Depending on the breed, cattle can survive on hill grazing, heaths, marshes, moors and semi desert. Modern cows are more commercial than older breeds and having become more specialised are less versatile. For this reason many smaller farmers still favour old breeds, like the dairy breed of cattle Jersey.

[edit] History

The practice of factory farming is a relatively recent development in the history of agriculture, and the result of scientific discoveries and technological advances. Early examples include terracing, rice paddies, and various forms of aquaculture.

Innovations in agriculture beginning in the late 1800s generally parallel developments in mass production in other industries that characterized the latter part of the Industrial Revolution. The identification of nitrogen and phosphorus as critical factors in plant growth led to the manufacture of synthetic fertilizers, making possible more intensive types of agriculture. The discovery of vitamins and their role in animal nutrition, in the first two decades of the 20th century, led to vitamin supplements, which in the 1920s allowed certain livestock to be raised indoors, reducing their exposure to adverse natural elements. The discovery of antibiotics and vaccines facilitated raising livestock in larger numbers by reducing disease. Chemicals developed for use in World War II gave rise to synthetic pesticides. Developments in shipping networks and technology have made long-distance distribution of agricultural produce feasible.

[edit] Current status

Warehouses in which chickens are confined in a "concentrated animal feeding operation (CAFO).
Warehouses in which chickens are confined in a "concentrated animal feeding operation (CAFO).
Interior of a hog confinement barn
Interior of a hog confinement barn
Cows in a CAFO in the U.S.
Cows in a CAFO in the U.S.
The entrance to a dairy barn
The entrance to a dairy barn

"Confined animal feeding operations" (U.S.) or "intensive livestock operations",[30] can hold large numbers (some up to hundreds of thousands) of animals, often indoors. These animals are typically cows, hogs, turkeys, or chickens. The distinctive characteristics of such farms is the concentration of livestock in a given space. The aim of the operation is to produce as much meat, eggs, or milk at the lowest possible cost.

[edit] Example: Carrolls' Farms

F.J. "Sonny" Faison, the CEO of Carrolls Foods in North Carolina, the second-largest hog producer in the U.S. (recently purchased by Smithfield Foods) has said: "It's all a supply-and-demand price question ... The meat business in this country is just about perfect, uncontrolled supply-and-demand free enterprise. And it continues to get more and more sophisticated, based on science. Only the least-cost producer survives in agriculture."[52] At one of Carrolls's farms, Farm 2105, twenty pigs are kept per pen, each pen is 7.5 square feet, and each confinement building or "hog parlor" holds 25 pens.[53] As of 2002, the company kills one million pigs every 12 days.[54]

Carrolls' Farms switched to the total confinement of animals in 1974. The animals are better off, according to Faison:

They're in state-of-the-art confinement facilities. The conditions that we keep these animals in are much more humane than when they were out in the field. Today they're in housing that is environmentally controlled in many respects. And the feed is right there for them all the time, and water, fresh water. They're looked after in some of the best conditions, because the healthier and [more] content that animal, the better it grows. So we're very interested in their well-being — up to an extent.[54]

[edit] Methods

Food is supplied in place, and artificial methods are often employed to maintain animal health and improve production, such as therapeutic use of antimicrobial agents, vitamin supplements and growth hormones. Growth hormones are not used in chicken meat production. In meat production, mechanical methods are also sometimes employed, such as de-beaking of chickens and physical restraints, to control undesirable behaviours.

[edit] Challenges and issues

While the point of industrial agriculture is lower cost products to create greater productivity thus a higher standard of living as measured by available goods and services, industrial methods have side effects both good and bad. Further, industrial agriculture is not some single indivisible thing, but instead is comprised of numerous separate elements, each of which can be modified, and in fact is modified in response to market conditions, government regulation, and scientific advances. So the question then becomes for each specific element that goes into an industrial agriculture method or technique or process: What bad side effects are bad enough that the financial gain and good side effects are outweighed? Different interest groups not only reach different conclusions on this, but also recommend differing solutions, which then become factors in changing both market conditions and government regulations.[55]


According to the Australian Bureau of Agricultural and Resource Economics, the major issues faced are:

  • marketing challenges and consumer tastes
  • international trading environment (world market conditions, barriers to trade, quarantine and technical barriers, maintenance of global competitiveness and market image, and management of biosecurity issues affecting imports and the disease status of exports)
  • biosecurity (pests and diseases such as bovine spongiform encephalopathy (BSE), avian influenza, foot and mouth disease, citrus canker, and sugar smut)
  • infrastructure (auch as transport, ports, telecommunications, energy and irrigation facilities)
  • management skills and labor supply (With increasing requirements for business planning, enhanced market awareness, the use of modern technology such as computers and global positioning systems and better agronomic management, modern farm managers will need to become increasingly skilled. Examples: training of skilled workers, the development of labor hire systems that provide continuity of work in industries with strong seasonal peaks, modern communication tools, investigating market opportunities, researching customer requirements, business planning including financial management, researching the latest farming techniques, risk management skills)
  • coordination (a more consistent national strategic agenda for agricultural research and development; more active involvement of research investors in collaboration with research providers developing programs of work; greater coordination of research activities across industries, research organisations and issues; and investment in human capital to ensure a skilled pool of research personnel in the future.)
  • technology (research, adoption, productivity, genetically modified (GM) crops, investments)
  • water (access rights, water trade, providing water for environmental outcomes, assignment of risk in response to reallocation of water from consumptive to environmental use, accounting for the sourcing and allocation of water)
  • resource access issues (management of native vegetation, the protection and enhancement of biodiversity, sustainability of productive agricultural resources, landholder responsibilities)[56]

[edit] Challenges and issues for the individual farm

The challenges and issues for individual farmers includes:

  • integrated farming systems
  • crop sequencing
  • water use efficiency
  • nutrient audits
  • herbicide resistance
  • financila instruments (such as futures and options)
  • collect and understand own farm information;
  • compare one paddock with another on your own farm. Identify the limiting factors on bottom paddocks, fix them up or get rid of them;
  • knowing your products
  • knowing your markets
  • knowing your customers
  • satisfying customer needs
  • securing an acceptable profit margin
  • cost of servicing debt;
  • ability to earn and access off-farm income;
  • management of machinery and stewardship investments.

[edit] Overall evaluation

[edit] Positives
Dairy cattle on an industrial farm.[5]
Dairy cattle on an industrial farm.[5]

Proponents say that large-scale intensive farming is a useful and proven agricultural advance. The argued benefits include:

  • Low cost — Intensive agriculture tends to produce food that can be sold at lower cost to consumers.
  • Efficiency — Animals in confinement can be supervised more closely than free-ranging animals, and diseased animals can be treated faster. Further, more efficient production of meat, milk, or eggs results in a need for fewer animals to be raised, thereby limiting the impact of agriculture on the environment.
  • Economic contribution — The high input costs of agricultural operations result in a large influx and distribution of capital to a rural area from distant buyers rather than simply recirculating existing capital. A single dairy cow contributes over $1300 US to a local rural economy each year, each beef cow over $800, meat turkey $14, and so on. As Pennsylvania Secretary of Agriculture Dennis Wolff states, “Research estimates that the annual economic impact per cow is $13,737. In addition, each $1 million increase in PA milk sales creates 23 new jobs. This tells us that dairy farms are good for Pennsylvania's economy.” [57]
  • Industry is responsible and self-regulating — Organizations representing factory farm operators claim to be proactive and self-policing when it comes to improving practices according to the latest food safety and environmental findings.
  • Food safety — Reducing number and diversity of agricultural production facilities results in easier management. Smaller facility numbers permit easier government oversight and regulation of food quality. Processing foodstuffs through centralized mediums leads to standardization, which protects general food safety, removing unsafe rogue elements.
  • Animal health — Larger farms have greater resources and abilities to maintain a high level of animal health. Larger farms can make use of expert veterinarians, while smaller non-industrial farms are limited to farmer's ability to care for his livestock. Under certain definitions of industrial agriculture, industrial agriculture also permits the use of antibiotics to prevent and treat diseases, while non-industrial agriculture, to minimize cost and meet certain other goals, often will not prevent or treat bacterial diseases but will instead hope illness clears up without intervention.
  • Pollution control — Large farms can maintain and operate sophisticated systems to control waste products. Smaller farms are unable to maintain the same standards of pollution control. By consolidating waste products, farmers can efficiently manage waste.

Proponents also dispute the food borne illness argument. They note the fact that E. coli grows naturally in most mammals, including humans, and that only a few strains of E. coli are potentially hazardous to humans. They also note that diseases naturally occur among chickens and other animals. Properly cooking food can effectively remove risk factors by killing bacteria. Proponents argue that there is widespread demand for a cheap, reliable source of meat.

[edit] Negatives
These sows are confined most of their lives in 2 ft by 7 ft gestation crates. Pork producers and many veterinarians say that sows are prone to fighting if housed together in pens. The largest pork producer in the U.S. said in January 2007 that it will phase out gestation crates from its 187 pig nurseries over the next ten years, because of concerns from its customers, including McDonalds. They are also being phased out in the European Union, with a ban effective in 2013 after the fourth week of pregnancy.
These sows are confined most of their lives in 2 ft by 7 ft gestation crates.[58][36] Pork producers and many veterinarians say that sows are prone to fighting if housed together in pens. The largest pork producer in the U.S. said in January 2007 that it will phase out gestation crates from its 187 pig nurseries over the next ten years, because of concerns from its customers, including McDonalds.[36] They are also being phased out in the European Union, with a ban effective in 2013 after the fourth week of pregnancy.[59]

Opponents say that what they refer to as factory farming is cruel,[60][61][62] that it poses health risks, and that it causes environmental damage.

In 2003, a Worldwatch Institute publication stated that "factory farming methods are creating a web of food safety, animal welfare, and environmental problems around the world, as large agribusinesses attempt to escape tighter environmental restrictions in the European Union and the U.S. by moving their animal production operations to less developed countries." [63]

Arguments include:

  • Mad Cow Disease — Factory farming techniques may lead to a higher incidence of Bovine spongiform encephalopathy, also known as mad cow disease, which in turn is claimed to cause Creutzfeldt-Jakob disease in humans.[34] In light of recently discovered cases of mad cow disease, Germany's chancellor, Dr Gerhard Schroeder, called for a stop of the practice of factory farming, asking instead for a more 'consumer-friendly' policy,[24] while British scientists called for farmers move away from intensive agriculture, saying the end of factory farming was the only way to kill mad cow disease.[24]
  • Other diseasesOverpopulation may lead to disease. In natural environments, animals are seldom crowded into as high a population density. Disease spreads rapidly in densely populated areas. Animals raised on antibiotics are breeding antibiotic resistant strains of various bacteria ("superbugs").[64] Use of animal vaccines can create new viruses that kill people and cause flu pandemic threats. H5N1 is an example of where this might have already occurred.[65]
  • Air and water pollution — Large quantities and concentrations of waste are produced.[66] Lakes, rivers, and groundwater are at risk when animal waste is improperly recycled. Pollutant gases are also emitted. Contaminants such as dust or foul smells can pollute air.
  • EthicsCruelty to animals: Crowding, drugging, and performing surgery on animals. Chicks are debeaked hours after hatching, commonly by slicing off the beak. Confining hens and pigs in barren environments leads to physical problems such as osteoporosis and joint pain, and also boredom and frustration, as shown by repetitive or self-destructive actions known as stereotypes.[67]
  • Resource overuse — Concentrated populations of animals require a commensurately large amount of water and are depleting water resources in some areas. [citation needed]
  • Destruction of Biodiversity — Industrial farming wipes out large areas of land to house a single variation of one species, usually foreign to the region, thus eliminating the entire local ecosystem.
  • Tracking — With the intensive farming system it is difficult to track the source of food, let alone food borne disease, back to particular animals. Sometimes food purchased on one side of the country may have been produced on the other side. Hamburger meat may contain the meat of as many as 1000 cows.[68] This causes concern among consumers concerning the origin of foods and among government officials concerning the origin of disease. The National Animal Identification System is one proposed way the USDA is attempting to remedy this problem. With "traditional" farming techniques this problem is eliminated because the consumer can buy directly from the producer. [69][70]This can lead to other problems, however, as food purchased directly from farmers does not have to be processed according to industrial standards and undergoes no official quality evaluation.

[edit] See also

Wikimedia Commons has media related to:

[edit] Sources and notes

  1. ^ a b c Encyclopaedia Britannica's definition of Intensive Agriculture
  2. ^ a b BBC School fact sheet on intensive farming
  3. ^ Encyclopaedia Britannica's definition of Extensive Agriculture
  4. ^ Factory farming. Webster's Dictionary definition of Factory farming
  5. ^ a b Encyclopaedia Britannica's definition of Factory farm
  6. ^ The Welfare of Intensively Kept Pigs
  7. ^ Commissioner points to factory farming as source of contamination
  8. ^ a b Rebuilding Agriculture - EPA of UK
  9. ^ Encyclopaedia Britannica - Intensive Agriculture
  10. ^ Fisheries and Oceans Canada article American Oyster
  11. ^ Methane gas generation from rice paddies
  12. ^ Duff, Wilson. "Fear In The Fields -- How Hazardous Wastes Become Fertilizer ...", The Seattle Times: July 3, 1997.
  13. ^ Brown, 1970.
  14. ^ Rice Varieties: IRRI Knowledge Bank. Accessed Aug. 2006. [1]
  15. ^ Smith, C. Wayne. (1995) Crop Production. John Wiley and Sons. pp. 60-62. ISBN 0-471-07972-3.
  16. ^ The Economist, 2005
  17. ^ Padgette SR, Kolacz KH, Delannay X, Re DB, LaVallee BJ, Tinius CN, Rhodes WK, Otero YI, Barry GF, Eichholz DA, Peschke VM, Nida DL, Taylor NB, Kishore GM (1995) Development, identification, and characterization of a glyphosate-tolerant soybean line. Crop Sci 35:1451-1461
  18. ^ Conservation Technology Information Center, http://www.conservationinformation.org/
  19. ^ Brookes G and Barfoot P (2005) GM crops: The global economic and environmental impact—the first nine years 1996–2004. AgBioForum 8:187-195
  20. ^ Liu, KeShun (1997-05-01). Soybeans : Chemistry, Technology, and Utilization (Hardcover), Springer, 532. ISBN 0-8342-1299-4. 
  21. ^ Sneller CH (2003) Impact of transgenic genotypes and subdivision on diversity within elite North American soybean germplasm. Crop Sci 43:409-414.
  22. ^ Kenney, Brad P. 2006. Success under glass. American Vegetable Grower. May, pages 12-13.[2]
  23. ^ Sorenson, Dan. 2006. Hydroponic tomatoes. Arizona Daily Star [3]
  24. ^ a b c "Scientists: factory farming drop could end mad cow", CNN/Reuters, December 4, 2000.
  25. ^ a b "State of the World 2006," Worldwatch Institute, p. 26.
  26. ^ Online source of McGraw-Hill Dictionary of Scientific and Technical Terms definition of "Factory farming" - McGraw-Hill Dictionary of Scientific and Technical Terms, 6th edition, published by The McGraw-Hill Companies, Inc.
  27. ^ "Is factory farming really cheaper?" in New Scientist, Institution of Electrical Engineers, New Science Publications, University of Michigan, 1971, p. 12.
  28. ^ "Factory farming," Encyclopaedia Britannica concise, 2007.
  29. ^ a b "Concentrated animal feeding operations", Centers for Disease Control and Prevention, United States Department of Health and Human Services.
  30. ^ a b Comparative Standards for Intensive Livestock Operations in Canada, Mexico, and the United States
  31. ^ Testimony by Leland Swenson, president of the U.S. National Farmer's Union, before the House Judiciary Committee, September 12, 2000, cited in Scully, Matthew. Dominion, St. Martin's Griffin, p. 29.
  32. ^ Scully, Matthew. Dominion, St. Martin's Griffin, p. 29.
  33. ^ a b "Commissioner points to factory farming as source of contamination", CBC, July 28, 2000.
  34. ^ a b Blaine Harden. "Supplements used in factory farming can spread disease", The Washington Post, December 28, 2003. 
  35. ^ A. Dennis McBride, MD, MPH (December 7, 1998). The Association of Health Effects with Exposure to Odors from Hog Farm Operations. North Carolina Department of Health and Human Services.
  36. ^ a b c Kaufmann, Mark. "Largest Pork Processor to Phase Out Crates", The Washington Post, January 26, 2007.
  37. ^ Sweeten, John et al. "Fact Sheet #1: A Brief History and Background of the EPA CAFO Rule". MidWest Plan Service, Iowa State University, July 2003.
  38. ^ Orlando, Laura. McFarms Go Wild, Dollars and Sense, July/August 1998, cited in Scully, Matthew. Dominion, St. Martin's Griffin, p. 257.
  39. ^ [ http://www.gi.alaska.edu/ScienceForum/ASF9/984.html “Fuss Over Farming Fish”, Alaska Science Forum, June 27, 1990]
  40. ^ This also causes stress.“Facts about Fish and Fish Farming”, Advocates for Animals.
  41. ^ University of Maine, Department of Animal, Veterinary and Aquaculture Sciences, "Sea Lice Information".
  42. ^ [Lymbery, P. CIWF Trust report, "In Too Deep - The Welfare of Intensively Farmed Fish" (2002)]
  43. ^ [BULLETIN OF THE EUROPEAN ASSOCIATION OF FISH PATHOLOGISTS 22 (2): 117-125 2002]
  44. ^ "The Dollar Hen", Milo Hastings, (1909)
  45. ^ "The Dollar Hen", Milo Hastings, (1909)
  46. ^ Dryden, James. Poultry Breeding and Management. Orange Judd Press, 1916.
  47. ^ http://www.plamondon.com
  48. ^ Havenstein, G.B., P.R. Ferket, and M.A. Qureshi, 2003a. Growth, livability, and feed conversion of 1957 versus 2001 broilers when fed representative 1957 and 2001 broiler diets. Poult. Sci. 82:1500-1508
  49. ^ http://cattle-today.com/
  50. ^ Lott, Dale F.; Hart, Benjamin L. (October 1979). "Applied ethology in a nomadic cattle culture". Applied Animal Ethology 5 (4): 309-319. Elsevier B.V.. doi:10.1016/0304-3762(79)90102-0. 
  51. ^ Krebs JR, Anderson T, Clutton-Brock WT, et al. (1997). "Bovine tuberculosis in cattle and badgers: an independent scientific review" (PDF). . Ministry of Agriculture, Fisheries and Food Retrieved on 2006-09-04.
  52. ^ Scully, Matthew. Dominion, St. Martin's Griffin, 2002, pp. 255-256.
  53. ^ Scully, Matthew. Dominion, St. Martin's Griffin, pp. 259.
  54. ^ a b Scully, Matthew. Dominion, St. Martin's Griffin, 2002, p. 258.
  55. ^ Australian Bureau of Agricultural and Resource Economics article Agricultural Economies of Australia and New Zealand
  56. ^ Australian Bureau of Agricultural and Resource Economics article Agricultural Economies of Australia and New Zealand
  57. ^ Dairy in Pennsylvania: A VITAL ELEMENT FOR ECONOMIC DEVELOPMENT[4]
  58. ^ "Photo gallery", factoryfarming.com.
  59. ^ "An HSUS Report: Welfare Issues with Gestation Crates for Pregnant Sows", The Humane Society of the United States, January 6, 2006.
  60. ^ "Cruelty to Animals: Mechanized Madness", PETA
  61. ^ Comis, Don, USDA Agricultural Research Service. "Settling Doubts about Livestock Stress." in Agricultural Research. March 2005. p. 4-7.
  62. ^ Smith, Lewis W., USDA Agricultural Research Service. “Forum – Helping Industry Ensure Animal Well-Being.” in Agricultural Research. March 2005. p. 2.
  63. ^ Nierenberg, Danielle. Factory Farming in the Developing World World Watch Magazine: May/June 2003.
  64. ^ "Agricultural Antibiotic Use Contributes To 'Super-bugs' In Humans", ScienceDaily, July 5, 2005.
  65. ^ According to the CDC article H5N1 Outbreaks and Enzootic Influenza by Robert G. Webster et. al.:"Transmission of highly pathogenic H5N1 from domestic poultry back to migratory waterfowl in western China has increased the geographic spread. The spread of H5N1 and its likely reintroduction to domestic poultry increase the need for good agricultural vaccines. In fact, the root cause of the continuing H5N1 pandemic threat may be the way the pathogenicity of H5N1 viruses is masked by co-circulating influenza viruses or bad agricultural vaccines."(CDC H5N1 Outbreaks and Enzootic Influenza by Robert G. Webster et. al.) Dr. Robert Webster explains: "If you use a good vaccine you can prevent the transmission within poultry and to humans. But if they have been using vaccines now [in China] for several years, why is there so much bird flu? There is bad vaccine that stops the disease in the bird but the bird goes on pooping out virus and maintaining it and changing it. And I think this is what is going on in China. It has to be. Either there is not enough vaccine being used or there is substandard vaccine being used. Probably both. It’s not just China. We can’t blame China for substandard vaccines. I think there are substandard vaccines for influenza in poultry all over the world."(MSNBC quoting Reuters quoting Robert G. Webster) In response to the same concerns, Reuters reports Hong Kong infectious disease expert Lo Wing-lok saying, "The issue of vaccines has to take top priority," and Julie Hall, in charge of the WHO's outbreak response in China, saying China's vaccinations might be masking the virus."(Reuters) The BBC reported that Dr Wendy Barclay, a virologist at the University of Reading, UK said: "The Chinese have made a vaccine based on reverse genetics made with H5N1 antigens, and they have been using it. There has been a lot of criticism of what they have done, because they have protected their chickens against death from this virus but the chickens still get infected; and then you get drift - the virus mutates in response to the antibodies - and now we have a situation where we have five or six 'flavours' of H5N1 out there."(BBC Bird flu vaccine no silver bullet 22 February 2006)
  66. ^ Facts about Pollution from Livestock Farms. National Resource Defense Council. Retrieved on 2006-05-30.
  67. ^ "The Welfare of Intensively Kept Pigs - Report of the Scientific Veterinary Committee - Adopted 30 September 1997, European Commission, and "Opinion of the AHAW Panel related to the welfare aspects of various systems of keeping laying hens", European Food Safety Authority (7-Mar-2005)
  68. ^ Scholosser, Eric, interview with Morgan Spurlock;
  69. ^ Schlosser, Eric, Fast Food Nation;
  70. ^ Eisnitz, Gail, Slaughterhouse: The Shocking Story of Greed, Neglect, and Inhumane Treatment Inside the U.S. Meat Industry

[edit] Further reading

Government regulation
Commissions assessing industrial agriculture
Proponent, neutral, and industry-related
Criticism of factory farming

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