Factory Farming: What It Is and Why It's a Problem

The model maximizes output and minimizes cost through mechanization, standardized genetics, and uniform diets. In the US, CAFOs are classified by the Environmental Protection Agency by animal numbers (for example, 1,000+ cattle, 2,500+ pigs, or 82,000+ laying hens).

Key features

• High-density confinement of animals including cows, pigs, chickens, and, in aquaculture, farmed fish
• Management systems optimized for speed and yield—often at the expense of animals’ health and behavior
• An industrial mindset that treats animals as units of production, raising persistent questions about transparency, ethics, and externalized costs

The scale and mindset of factory farming

Factory farming is more than a set of practices—it’s an industrial production philosophy. Cost-reduction and throughput are paramount, which has enabled unprecedented scale. That same scale, however, magnifies risks: biosecurity challenges, antibiotic resistance, environmental pollution, and chronic stress for animals that cannot express basic behaviors.

What happens on factory farms?

On factory farms, animals have little or no choice or opportunity to express natural behaviors. Their lives are shaped by systems designed for efficiency—rapid growth, restricted movement, and high-throughput slaughter.

Confinement and animal health

Across species, confinement in these intensive systems results in a high risk of injury, disease, and chronic stress. Broiler chickens bred for rapid growth suffer leg disorders and cardiovascular strain; breeding sows confined in metal crates exhibit stereotypic stress behaviors and are prone to infections and pressure sores; dairy cows in intensive housing show higher rates of lameness and mastitis. In less intensive, well-managed systems with enriched environments, animals can perform their normal natural behaviors, and these risks can be greatly reduced.

Routine mutilations

Physical alterations are widely used to manage stress-induced behaviors that arise under crowding. These procedures, often performed without anesthesia on young animals, include beak trimming in poultry, tail docking in pigs and cattle, and castration of males. Reviews consistently find acute pain responses and, in some cases, longer-term pain due to nerve damage. Crucially, these procedures don’t fix root causes—space constraints, barren environments, and genetic lines selected for maximum output.

Chickens are beak-trimmed

Beaks are sensory organs—chickens use them to explore and interact with their surroundings. In overcrowded, barren sheds, stress & boredom can result in injurious pecking behavior. Although hens will aggressively peck competitors, this kind of injurious pecking is not generally considered an aggressive behaviour but is, rather, a redirected foraging behavior. Instead of reducing stocking density or enriching environments, many operations trim or partially remove beak tissue with heated blades, which can cause chronic pain and impair normal behavior. These problems are rarely observed where birds have adequate space and stimulation—signaling that management conditions, not “chicken nature,” drive the behavior.

Cows and pigs are tail-docked

Tail docking remains common in intensive pig and dairy systems, largely as a management response to problems that arise under crowding and barren housing. In pigs, docking is intended to reduce tail‑biting—an abnormal behavior linked to stress, limited space, and lack of enrichment. The procedure usually occurs in the first days of life, often without anesthesia. Studies consistently document acute pain responses at the time of docking—vocalization, struggling, elevated stress hormones—and longer‑term sensitivity associated with traumatic neuroma formation at the tail stump. Crucially, docking treats the symptom, not the cause: when stocking density is lowered and enrichment (foraging materials, manipulable substrates) is provided, tail‑biting declines without resorting to amputation.

In dairy cattle, tail docking has historically been justified as improving udder hygiene and milking parlor cleanliness. Controlled trials, however, have not demonstrated meaningful improvements in milk quality or mastitis rates. What they do show is impaired welfare: docked cows exhibit increased fly‑avoidance behaviors and heightened sensitivity to touch, indicating persistent discomfort. Reflecting this evidence, many countries and industry bodies have prohibited or discouraged routine docking in cattle; yet in parts of North America, the practice persists, often due to habit or perceived labor savings rather than demonstrable animal‑health benefits. The direction of travel in policy and corporate standards is clear: where tail docking is still practiced, it is increasingly restricted to exceptional, veterinary‑justified cases—and even then, accompanied by analgesia.

Castration

Surgical castration is widely used for male pigs and cows to prevent unintended breeding and reduce aggression or, in pigs, to avoid “boar taint.” Performed without pain relief in many settings, it causes immediate pain—evidenced by struggling, cortisol spikes, and altered vocalizations—and can lead to longer‑term discomfort, particularly when done at older ages.

Research and practice offer alternatives. Local anesthesia and post‑operative analgesics reduce acute pain but add labor and cost. Immunocastration—a vaccine‑based approach generally for pigs and cows that suppresses testicular function—avoids surgery and its complications while addressing ‘boar taint’ in pigs; uptake is growing in some markets but remains limited due to perception, labeling, and trade‑standard barriers. As with tail docking, the broader welfare lesson is consistent: breeding, housing, and management choices that reduce aggression and stress lessen reliance on invasive procedures in the first place.

Animals are confined

Confinement is the throughline of industrial systems, designed for labor efficiency and space utilization—but it constrains basic behaviors and elevates health risks.

Dairy cattle in tie‑stall systems are tethered for much of their lives, with movement largely restricted to standing up and lying down. Even in freestall barns, where cows can move between stalls and alleys, animals may spend nearly all their time indoors. Comparative studies find higher rates of lameness, mastitis, and stereotypic behaviors in confinement systems relative to pasture‑based systems; regular pasture access improves locomotion, reduces disease burden, and enables grazing and social choice—behaviors cows are highly motivated to perform.

Egg‑laying hens in battery cages receive floor space on the order of a sheet of notebook paper per bird—insufficient for wing‑flapping, perching, nesting, or dust‑bathing. Chronic spatial restriction and a barren environment contribute to muscle atrophy, brittle bones, feather loss, and fractures. Even so‑called enriched cages address only a fraction of hens’ behavioral needs. In contrast, cage‑free systems, when properly designed and managed, allow more movement and natural behaviors; they are not a panacea, but they do mitigate some of the most severe harms of caging.

Breeding sows housed in gestation crates are unable to turn around for months at a time. This level of immobilization is associated with elevated stereotypies (bar‑biting, sham‑chewing), pressure sores, urinary tract issues, and weakened musculoskeletal condition. Group housing with bedding and enrichment reduces these harms and is increasingly required by corporate policies and legislation in various jurisdictions.

Across species, the scientific pattern is consistent: as opportunities to express normal behavior increase, indicators of stress and injury decline.

Genetic manipulation

Genetic selection has turbocharged productivity—fast growth, heavier muscling, higher milk and egg output—but with well‑documented trade‑offs.

Modern broiler chickens reach slaughter weight in a fraction of the time of heritage lines, driven by selection for rapid breast‑muscle accretion. Skeletal and cardiovascular development lag behind, increasing lameness, leg deformities, and sudden cardiac death. Muscle myopathies such as “white striping” and “woody breast,” linked to extreme growth rates, impair meat quality and likely reflect underlying metabolic stress.

High‑yield dairy cows experience substantial metabolic strain early in lactation—negative energy balance, elevated risk of ketosis, displaced abomasum, mastitis, and reduced fertility.

In egg‑layer lines, relentless selection for egg number predisposes hens to osteoporosis and keel bone fractures, particularly in systems that already limit movement.

Selection can reduce some invasive practices—breeding cattle to be polled (naturally hornless) reduces the need for dehorning—and helps to improve some health outcomes, but in practice, genetic selection of commercial farmed-animal species is used to improve productivity. When millions of near‑identical animals are housed in dense networks, pathogens spread more readily—heightening both animal‑health and zoonotic risks. Recent avian influenza waves in large poultry complexes illustrate how industrial scale and genetic uniformity can amplify outbreaks with regional and even international consequences.

Antibiotic use and resistance

Crowded, stressful conditions elevate infectious‑disease risk; antibiotics have been widely used not only to treat illness but to prevent it across entire groups (“prophylaxis” or “metaphylaxis”). This practice creates strong selection pressure for bacteria that can survive treatment.

Public‑health authorities regard antimicrobial resistance as a major global threat, with projections of mounting human morbidity and mortality without coordinated action. Surveillance data indicate that a significant proportion of antibiotics produced globally are used in animal agriculture. In the US, estimates suggest that over half of all medically important antibiotics are sold for use in animals rather than humans. Studies have shown that bacteria resistant to multiple antibiotics are commonly isolated from meat products, farm environments, and even downstream water sources. The World Health Organization has described antimicrobial resistance as “one of the biggest threats to global health, food security, and development today.” Projections from the United Nations suggest that, without intervention, antibiotic resistance could result in as many as 10 million deaths annually by 2050 and push 24 million people into extreme poverty.

The technical playbook is clear: phase out non‑therapeutic use; tighten veterinary oversight; improve housing, hygiene, and biosecurity; vaccinate where feasible; and adopt farming practices that reduce disease pressure at the source. Some companies and countries have moved in this direction, demonstrating that lower‑resistance risk and profitable operations can coexist—yet progress remains uneven, particularly where regulatory oversight is fragmented and economic incentives still favor throughput over resilience.

Why does factory farming persist?

Despite well‑documented downsides, the industrial model endures because it fits the incentives embedded in today’s food economy.

Economic and structural drivers

Scale delivers lower per‑unit costs: uniform genetics, automated feeding, climate‑controlled housing, and just‑in‑time logistics compress labor and fixed costs into a steady stream of low‑priced products. Feed subsidies—especially for corn and soy—further reduce inputs, making animal protein appear cheap at retail while shifting environmental and health costs onto the public ledger. In commodity markets where margins are thin and demand is price‑sensitive, these advantages crowd out smaller, diversified operations.

Corporate consolidation

A handful of multinationals dominate meat, egg, and dairy processing and distribution. Consolidation concentrates bargaining power over growers and suppliers, shapes contract terms, and affords significant sway in regulatory and trade forums. The result is a system optimized for standardized, high‑volume throughput—reinforced by lobbying that preserves permissive line speeds, weak transparency requirements, and limited liability for environmental externalities.

Policy and regulatory frameworks

From crop insurance to marketing loans, many programs disproportionately benefit large producers. Environmental and animal‑health oversight is often under‑resourced and siloed, with exemptions that treat agriculture differently from other polluting industries. In some states, “ag‑gag” statutes curtail documentation of on‑farm conditions, limiting the flow of information to consumers, investors, and regulators who might otherwise drive change through markets or policy.

Global demand and market forces

Rising incomes and urbanization have increased demand for animal‑based foods. Major producers have scaled industrial systems and expanded exports to meet that demand, locking in infrastructure—buildings, breeding programs, processing plants—that has a multi‑decade lifespan. Once regions specialize around feed, production, and processing, switching costs rise and path dependence sets in.

Transparency and consumer awareness

Marketing and labels can obscure production realities. Where credible transparency improves—through corporate reporting, third‑party auditing, or investigative journalism—attitudes and purchasing patterns shift toward products and policies that spare animals the most severe confinement and reduce environmental harms. That shift signals a market for alternatives, but information remains uneven and fragmented.

Why is factory farming bad?

The harms span animals, ecosystems, human health, and rural economies—and they are additive at scale.

Animal welfare

Confinement systems make it difficult for animals to meet the widely used “Five Freedoms” of welfare. Battery cages prevent basic movement and nesting; gestation crates immobilize sows for months; tie‑stalls limit cows’ ability to walk, graze, and socialize. Routine procedures—beak trimming, tail docking, castration—layer acute and sometimes chronic pain on top of environmental stress. Where housing allows natural behaviors and stocking densities are lower, indicators of stress and injury improve—underscoring that many problems are design choices, not inevitabilities of farming.

Environmental impact

Factory farming is a substantial contributor to a range of environmental problems. Manure and fertilizer run‑off from industrial livestock and feed production drive pollution in rivers and lakes, fueling harmful algal blooms and oxygen‑depleted “dead zones.” According to a report from Food and Water Watch, a single hog produces around one and a half tons of manure every year, and all the hog farms in the US produce a total of about 167 million pounds of waste—equivalent to the waste produced by half the country’s human population. Hog waste is particularly dangerous since it is generally not treated before being released into the environment, leading to surface and groundwater contamination.

Large operations emit ammonia and fine particulates that harm respiratory health downwind. Greenhouse gases from enteric fermentation, manure storage, and fertilized croplands add substantially to climate change. Global feed demand ties intensive livestock systems to deforestation and habitat loss abroad—particularly where soy and corn cultivation accelerates frontier clearing.

Human health issues

Communities near CAFOs experience higher exposure to airborne irritants, odors, and pathogens, with elevated rates of respiratory symptoms. Workers in farms and processing plants face some of the highest injury rates in the US and globally. Overuse of antibiotics in livestock contributes to resistant infections in people, via multiple environmental and food‑borne pathways. While food safety systems mitigate risk, contamination with Salmonella and other pathogens remains a persistent challenge in industrial supply chains.

Rural communities

Industrialization has reshaped rural economies. CAFOs and large plants produce more with fewer workers, reducing jobs per unit of output and eroding the customer base for local businesses. Research shows that when farms are locally owned and operated, more money stays in the community, fostering local economic development and social capital. Because CAFOs can produce a surplus of product and artificially lower prices, smaller operations often can’t compete, hollowing out rural communities and causing notable economic decline. The number of farms in the US has dramatically decreased since the early 1960s, while the total number of animals raised on the remaining farms has increased steadily.

Contracts can leave growers bearing capital risk while capturing a small share of value. Many frontline jobs are filled by immigrants and people of color who face hazardous conditions and limited bargaining power. The COVID‑19 pandemic laid these vulnerabilities bare—crowded plants became disease hotspots—with consequences for workers’ families and the broader community.

The COVID-19 pandemic highlighted the vulnerabilities of this system. Workers at meatpacking plants were designated as “essential” and required to continue working in crowded conditions. As a result, thousands of workers contracted COVID-19, and many brought infections back to their families and communities. Studies and investigative reporting have since found that CAFOs and processors did little to mitigate these health risks, underscoring broader public health and occupational safety concerns.

How are animals killed on factory farms?

Slaughter systems are engineered for speed and cost control. When stunning and handling are done correctly, suffering can be minimized; when equipment fails or line speeds outpace oversight, animals experience avoidable pain and distress.

Slaughter of chickens

Live‑shackle lines suspend birds upside‑down by their legs, a stressful position that can cause fractures. An electrified water bath is intended to stun birds before their throats are cut and carcasses are scalded for feather removal. Audits and investigations have documented ineffective stunning in some plants—meaning birds may be conscious during cutting or scalding.

Because poultry are not covered by the federal Humane Slaughter Act, regulatory levers are weaker; some companies have adopted gas‑based controlled atmosphere stunning, which can reduce handling stress and improve consistency, but adoption remains partial.

Slaughter of cattle and pigs

Cattle are typically stunned with a captive‑bolt device that should render them insensible before bleeding. Pigs are stunned electrically or with high‑concentration carbon dioxide gas. In practice, operator error, equipment issues, and high line speeds can lead to incomplete stunning. Electrical stunning can be highly effective when applied correctly; CO₂ stunning, widely used for pigs, induces aversive sensations prior to loss of consciousness. The Animal Welfare Council, an independent advisory body to the British government, published a report on this, recommending: “To prevent pigs experiencing avoidable pain, distress or suffering at slaughter associated with high concentration CO2 its use should be prohibited as a method of stunning for pigs.” Training, maintenance, and enforceable line‑speed limits are central to reducing welfare failures.

Regulatory oversight

The Humane Slaughter Act in the US requires effective stunning for livestock (excluding poultry) before slaughter and is enforced by USDA’s Food Safety and Inspection Service. Oversight resources and consistency vary, and documented violations have led to calls for tighter enforcement, better data transparency, and modernization of equipment and training. Incremental improvements here can reduce suffering at a very large scale, given the throughput of industrial plants.

Where is factory farming most common?

In the United States, CAFOs cluster where feed, infrastructure, and processing capacity co‑locate—especially the Midwest (Iowa, Minnesota, Illinois, Nebraska), parts of the Southeast (North Carolina), and California’s Central Valley. Iowa alone houses tens of millions of pigs and produces a substantial share of the nation’s pork and eggs, with well‑documented implications for water quality, air emissions, and rural quality of life.

US states with the greatest concentration of factory farms

• Alabama
• Arkansas
• California
• Delaware
• Illinois
• Indiana
• Iowa
• Kansas
• Maryland
• Michigan
• Minnesota
• Mississippi
• Missouri
• Nebraska
• New York
• North Carolina
• Ohio
• Wisconsin

According to the 2017 USDA Census of Agriculture and geospatial analyses by Food & Water Watch, the concentration of factory farms is especially high in the Midwest (Iowa, Minnesota, Illinois, Nebraska), the Southeast (North Carolina), and the Central Valley of California. For example, Iowa alone houses more than 20 million hogs—more than the human population of the entire state—and produces a significant share of the nation’s eggs and pork.

The rise of CAFOs in these states has been linked to local economic and environmental changes, including the decline of small family farms, increased nutrient pollution in waterways, and changes in rural demographics. These trends are well documented in both government and academic reports. The high density of animals per county is a key risk factor for environmental challenges, including groundwater contamination, surface water impairment, and ammonia emissions.

Globally, the United States, China, Brazil, and the European Union are the largest markets for factory‑farmed animals. Industrialization in China and Brazil has accelerated consolidation and export capacity; within the EU, large poultry, swine, and dairy operations are common in the Netherlands, Germany, Spain, and Denmark.

Factory farming facts and statistics

• The number of US farms fell by roughly 50% between 1960 and 2002, even as total animals raised increased—evidence of consolidation and scale.
• In 2020, an estimated 1.6 billion animals were confined within approximately 25,000 factory farms—in the US alone.
• Roughly 99% of US farmed animals live on factory farms.

How can we stop factory farming?

There is no single fix, but the evidence points to practical priorities: phase out the most extreme confinement; adopt breeds and housing that prioritize health over sheer speed; strengthen antibiotic stewardship and biosecurity; improve transparency; and align incentives so prices better reflect real costs to animals, communities, and ecosystems. Individuals and institutions can accelerate progress by asking credible questions of suppliers, supporting time‑bound corporate commitments to animals, and backing policies that reduce suffering at scale.

Ways to get involved

• Join the Fast Action Network (FAN)
• Volunteer with The Humane League
• Learn more about our current campaigns

A food system that spares animals the worst harms—and reduces collateral damage to people and the planet—is within reach. Progress takes persistence, but each step toward transparency, accountability, and better standards matters now.