湿喂法在断奶仔猪生产中的应用

断奶仔猪采用湿喂法能提高仔猪的生产性能 ,改善其健康状况。一方面 ,液体日粮容易被仔猪接受 ,这样可以防止仔猪断奶后采食量的急速下降。另一方面 ,加水后成液态的饲料在自然条件下会发酵 ,这导致饲料中的乳酸菌数量增加、乳酸浓度上升、pH值下降。与喂干粉饲料相比 ,给断奶后仔猪喂液体日粮能够改善仔猪消化道的内环境 ,减少疾病 ,提高干物质采食量和日增重。     

Central nervous system intoxications other than lead

Other than lead, organophosphates and carbamates are probably the most important classes of toxicants affecting the central nervous system in food animals. Chlorinated hydrocarbons continue to present problems from time to time, as do certain poisonous plants. Less frequently encountered substances such as nitrofurans, certain rodenticides, herbicides, and other miscellaneous poisons are also discussed.     

Posthatch growth of the digestive system in wild and domesticated ducks

1. Our study was designed to test the hypothesis that domestication and artificial selection have influenced the posthatch growth and functioning of the gastrointestinal (GI) tract of ducks. The mass and length of the GI tract organs, the growth of intestinal villi, the intestinal surface area and the activities of brush border digestive enzymes were measured in a commercial strain of Pekin duck and its wild ancestor, the mallard (Anas platyrhynchos), at regular intervals between hatch and 16 weeks of age. 2. The growth of the digestive organs, with respect to body mass, was described using allometry. Allometric mass exponents were then used to calculate body 'mass-corrected', or 'relative' organ masses, relative surface areas and relative enzyme activities. There were appreciable differences between data presented on a mass-specific (g/kg) and a mass-corrected (g/kg(b)) basis, which highlighted the importance of correcting for the complete effects of body mass when comparing the growth and function of the digestive system between strains. 3. While the process of domestication has induced major changes in the absolute characteristics of the GI tract, it has failed to have the same effect on the relative characteristics. During the first 2 weeks posthatch, the relative masses of the majority of digestive organs, and the GI tract as a whole, were the same in both strains. During weeks 3 to 5, domesticated ducks maintained higher absolute growth rates of the body and the GI tract, with the support of relatively smaller digestive organs. The relative masses of the small intestine and the GI tract as a whole were 45 and 66% higher respectively in mallards than in Pekin ducks during this period. 4. Domesticated ducks had elevated digestive enzyme activity and a greater absorptive surface area than mallards throughout development, both in absolute and relative terms. This appears to compensate for the failure of the relative masses of digestive organs in domesticated ducks to accompany the increased body mass and growth rate. 5. At 5 weeks posthatch, the absolute mass of the small intestine in domesticated ducks declined by 38%. There is no obvious explanation for this decline because the masses of other digestive organs, daily feed intake and body mass continued to rise.     

The advantages and disadvantages of endoscopy

Endoscopy is generally a very safe and effective tool in the diagnosis and therapy of various gastrointestinal (GI) disorders, and must be used in conjunction with other diagnostic modalities. Endoscopy should not be a substitute for a complete work-up. There are many advantages of endoscopy, including minimal morbidity and mortality, and the sensitivity of this modality in the diagnosis of mucosal disorders of the GI tract. However, complications may occur, and there are limitations to endoscopy. This article will provide an overview of when to choose GI endoscopy and when other procedures might provide more information.     

Pulmonary aspergillosis in horses: 29 cases (1974-1997)

OBJECTIVE: To analyze medical records and identify factors that veterinarians can use to prevent pulmonary aspergillosis in horses or that would enable them to diagnose it as early as possible. DESIGN: Retrospective study. ANIMALS: 29 horses. PROCEDURE: Medical records were reviewed for horses with pulmonary aspergillosis diagnosed on the basis of characteristic postmortem findings. Information on history, clinical signs, disease progression, and postmortem findings was obtained. RESULTS: 25 of 29 (86.2%) horses had primary (n = 20) or secondary (5) disease compatible with loss of integrity of the gastrointestinal (GI) tract. The remaining 4 horses had a non-GI tract disorder; only 1 of these 4 had clinical signs associated with the respiratory tract (i.e., pleuropneumonia). Although 22 (75.9%) horses had various signs of respiratory tract disorders, an antemortem diagnosis of Aspergillus pneumonia was made in only 1 horse and was suspected in only 1 other. Fungal organisms were seen histologically in tissues other than the lung in 12 (41.4%) horses. CLINICAL IMPLICATIONS: Horses with enteritis, colitis, typhlitis, or other diseases of the GI tract that result in mucosal compromise, and horses with clinical signs of respiratory tract disease, particularly if the horse's condition is unresponsive to treatment with antimicrobial agents; should be considered at high risk of having pulmonary aspergillosis. Immunosuppression from debilitating disease may also predispose horses to aspergillosis. Because invasive pulmonary aspergillosis can be difficult to diagnose, clinicians should be aware of clinical and epidemiologic settings in which this disease would develop.     

The effect of natural toxins on reproduction in livestock.

Reproductive efficiency is the most important economic factor in livestock production. Thus, the hypothalamo-pituitary-gonadal regulatory axis, accessory sexual organ functionality, and the complex events involved in fertilization, implantation, and embryonic and fetal development may be sensitive to therapeutic agents, environmental pollutants, and natural toxicants. There are many factors that adversely affect reproduction, one of which is toxic substances in the diets of animals. Toxic materials can affect reproductive success by causing abortions, interfering with libido, estrus, oogenesis, or spermatogenesis, causing emaciation and subsequent abnormal mating behavior, birth defects, and increasing the time between parturition and rebreeding. Examples of natural toxicants in poisonous plants interfering with reproduction are numerous. Abortion in livestock from locoweeds, ponderosa pine needles, broom snakeweeds, fescue, and others are reported in studies. Selenium and seleniferous forage inhibit estrus in cattle and swine. Emaciation and temporary illness from sneezeweeds, bitterweed, locoweed, larkspur, lupines, and others may interfere with mating. Embryonic loss and birth defects from Veratrum, lupines, locoweeds, poison hemlock, and so on, may occur. As suggested, toxins have many diverse and economically adverse effects on reproductive performance in livestock.     

Gastrointestinal Disease in Exotic Small Mammals

Exotic small mammal medicine is a relatively new specialty area within veterinary medicine. Ferrets, rabbits, and rodents have long been used as animal models in human medical research investigations, resulting in a body of basic anatomic and physiologic information that can be used by veterinarians treating these species. Unfortunately, there is a paucity of veterinary articles that describe clinical presentation, diagnosis, and treatment options of gastrointestinal (GI) disease as it affects exotic small mammals. Although there is little reference material relating to exotic small mammal GI disease, patients are commonly presented to veterinary hospitals with digestive tract disorders. This article provides the latest information available for GI disease in ferrets (Helicobacter mustelae gastritis, inflammatory bowel disease [IBD], GI lymphoma, systemic coronavirus, coccidiosis, and liver disease), rabbits (GI motility disorders, liver lobe torsion, astrovirus, and coccidiosis), guinea pigs (gastric dilatation volvulus [GDV]), rats (Taenia taeniaeformis), and hamsters (Clostridium difficile). Both noninfectious diseases and emerging infectious diseases are reviewed as well as the most up-to-date diagnostics and treatment options.     

Interplay between rumen digestive disorders and diet-induced inflammation in dairy cattle

In this review, an overview is provided on the current achievements regarding the interplay between rumen digestive disorders and diet-induced inflammation in dairy cattle. It starts with a review of factors favoring the disturbances in the rumen metabolism, which culminate with development of sub-acute rumen acidosis (SARA). The latter digestive disorder is often linked to greater metabolic stress of gastrointestinal (GI) microbiota and lowered fiber digestion, as well as with disruption of the barrier functions of the GI epithelia, which open the route of deleterious molecules to translocate from the GI lumen into the portal system. A model is suggested to illustrate the mechanisms of the involvement of digestive disorders in the disruption of the host's inner homeostasis leading to activation of acute phase response (APR). The latter is part of multifaceted innate immune and metabolic responses of the host. According to this model, endotoxin, its toxicity, and other metabolic compounds of microbial origin are regarded as important immunogenic components of GI tract, which when favored by disruption of host barriers triggers a systemic APR. Although the activation of an APR is viewed as a protective reaction aiming to reestablish the disturbed homeostasis, the presence of inflammatory state over long periods might be associated with negative consequences for the host. The review concludes that prolonged systemic inflammation can: (1) cause significant changes in the energy and lipid metabolism in different body tissues, (2) lead to the development of refractory states associated with immune suppression and increased susceptibility to various diseases, and (3) artificially increase host's requirements in energy and nutrients, lowering the efficiency of energy and feed use by the animal. The paper emphasizes the critical role that formulation of healthy diets plays for curbing down inflammation and enhancing metabolic health of dairy cows.     

Nonruminant Nutrition Symposium: Involvement of gut neural and endocrine systems in pathological disorders of the digestive tract

The functioning of the gastrointestinal tract is under the control of the most extensive system of peripheral neurons in the body, the enteric nervous system, and the largest endocrine system of the body, the GEP endocrine system. The enteric nervous system in large mammals contains 500 million neurons, and the GEP endocrine system produces more than 30 hormones. Numerous enteric neuropathies affecting both humans and animals have been described and digestive disorders affect commercially important species, such as horses and cattle. The most severe enteric neuropathies (e.g., lethal white syndrome in horses or Hirschsprung's disease in humans) can be fatal. Also, horses with ileus or other digestive disorders are commonly euthanized. In this review we discuss examples of enteric neuropathies that affect agricultural animals and humans: prion disease, postoperative ileus, distal enteric aganglionosis, and infective diarrhea. Enteric neurons and glia are a location of prion proteins and are involved in transmission of the infection from gut to brain and brain to gut. Postoperative ileus is a complex disorder involving the local inhibitory effects of sympathetic nervous system activation and the release of opioids, presumably from enteric neurons. Intestinal inflammation, especially of the external muscle that includes enteric ganglia, also occurs in ileus. Congenital distal bowel aganglionosis, responsible for lethal white syndrome in horses, Hirschsprung's disease in humans, and similar conditions in mice and rats, is a fatal condition if untreated. Mutations of the same genes can cause the condition in each of these species. The only effective current treatment is surgical removal of the aganglionic bowel. Infectious diarrheas involve activation of enteric secretomotor neurons by pathogens and the toxins they produce, which causes substantial fluid loss. Strategies to target enteric neurons in the treatment of secretory diarrheas have not been developed. Disorders of enteroendocrine cells, other than GEP endocrine tumors, are less well documented. However, evidence for the involvement of gut endocrine cells in a subset of patients with irritable bowel syndrome, and in the symptomology of celiac disease, has been demonstrated. Further investigation of the involvement of enteric neural and endocrine signaling systems in digestive disorders, especially in agricultural and companion animals, may lead to diagnostic and therapeutic advances.     

睡眠剥夺对哺乳动物消化系统的影响

睡眠剥夺对动物和人体的生理结构和功能产生多方面的负面影响，可引发多种疾病甚至死亡，尤其与机体的消化吸收和新陈代谢等过程密切相关。作者主要围绕睡眠剥夺对胃、肠、肝脏等器官的结构和功能所造成的影响进行了归纳和总结，并针对睡眠剥夺对机体氧化应激水平、细胞因子浓度和激素分泌等产生影响，进而引起消化系统紊乱的可能机制进行了分析。除此之外，食物摄入等对睡眠剥夺动物的状态也有所影响。睡眠剥夺对消化系统的影响包括使消化道黏膜及肝细胞遭受损伤、胃运动功能下降、肠道菌群紊乱及胃肠激素、胰岛素分泌异常等，进而影响机体能量代谢，减缓其从损伤中恢复的速度，患各种恶性疾病的概率也增加。睡眠剥夺作为一种应激原，会显著提升机体的氧化应激水平，令细胞的代谢负担加大，多种生物大分子，特别是DNA被破坏；细胞因子如肿瘤坏死因子α（TNF-α）的释放增加则使炎症反应广泛发生；激素分泌也是这些损伤过程中的一环，若损伤不断发展，则导致患恶性肿瘤风险加剧。在实践也发现了一些可对睡眠剥夺状态产生影响的食物和药物，但其机制尚不明确。目前，针对睡眠剥夺对机体消化系统乃至全身范围内的损伤机制研究尚有许多空白，未来仍需进行广泛、深入的研究。     

Clinical Update and Treatment of Selected Infectious Gastrointestinal Diseases in Avian Species

The anatomy of the avian gastrointestinal (GI) tract is unique and significantly different from that of other animals. The characteristics of the avian GI tract allow the different species to adapt and thrive in their habitats. Infectious diseases of bacterial, viral, fungal, and parasitic origin commonly affect avian species. The significance and the nature of these pathologies vary with species and if they live in the wild or a captive environment. This review compiles information available in the literature on specific infectious processes that were considered relevant and clinically significant by the authors. Clinicians should be knowledgeable and aware of the infectious agents, clinical signs associated with disease, diagnostic techniques, and treatment methodologies currently available regarding diseases that affect the avian GI tract. Recent information that provides new insight to these infectious processes is the focus of this article.     

Nutritional management of gastrointestinal disease

The gastrointestinal (GI) tract is primarily responsible for acquiring and digesting food, absorbing nutrients and water, and expelling wastes from the body as feces. A proper diet and normally functioning GI tract are integral for the delivery of nutrients, prevention of nutrient deficiencies and malnutrition, repair of damaged intestinal epithelium, restoration of normal luminal bacterial populations, promotion of normal GI motility, and maintenance of normal immune functions (eg, both tolerance and protection from pathogens). The amount of food, its form, the frequency of feeding, and the composition of diet each have important effects on GI function and may be used to help ameliorate signs of GI disease. Although both nutrients and nonnutritional components of a diet are important to GI health, they also may cause or influence the development of GI pathology (eg, antibiotic responsive diarrhea, inflammatory bowel disease, dietary intolerance, or sensitivity and/or allergy). The appropriate diet may have a profound effect on intestinal recovery and successful management of chronic or severe GI disease.     

Gastrointestinal ultrasonography of the dog: a review of 265 cases (1996-1998)

The findings of ultrasonography of the gastrointestinal (GI) tract of 265 dogs with GI disorders were analysed retrospectively. The sonographic changes associated with various inflammatory and neoplastic conditions and mechanical obstruction of the GI system were recorded and discussed. Sonographic alterations of the pancreas and the tissues adjacent to the GI tract were also included in the study. Ultrasonographic alterations of the GI tract were classified into three main categories: thickening of the GI wall, changes in peristalsis and dilation of the lumen. Localised thickening of the GI wall with disruption of its structure was caused by both neoplastic diseases and by inflammatory disorders. However, diffuse thickening with retained wall structure was generally associated with inflammatory diseases. The criteria previously established for the ultrasonographic diagnosis of intestinal obstruction were successfully applied to a large number of GI disorders. Pancreatitis was most often associted with hyperchoic mesentery and hypoechoic pancreas mass, but similar alterations were encountered in some cases of gastric or duodenal ulceration. Except in cases of invaginations and intestinal obstructions, the observed ultrasonographic changes were not specific enough for a definitive diagnosis. Nevertheless, ultrasonography proved to be a valuable technique in the diagnostic process of GI disorders of the dog.     

GASTROINTESTINAL NUCLEAR MEDICINE

Nuclear medicine has achieved an important role in the diagnosis of gastrointestinal (GI) disease in humans. Esophageal and gastric motility problems, gastroesophageal reflux, abnormal gastric secretory function, GI bleeding, and inflammatory diseases of the GI tract can all be evaluated using nuclear scintigraphy. The use of these techniques in human medicine, their advantages and disadvantages relative to other available diagnostic tests, and their potential application to veterinary medicine are discussed. Examples of esophageal and gastric motility studies performed on normal and abnormal dogs are included.     

Effects of pharmacological agents on gastrointestinal motility

The control mechanisms of gastrointestinal motility are complex. Extrinsic neurohormonal effects modulate an intrinsic system, often called the "gut brain," composed of nervous and neuropeptide components. To exert pharmacologic influence on GI motility, use is made of agents that mimic the external control system. Agents that stimulate opioid receptors, block adrenoceptors, block or facilitate acetylcholine action, or antagonize the action of prostaglandins are used to effect changes in GI motility. The major indications for pharmacologic intervention are to increase motility in constipation, to reduce it in most cases of diarrhea, and to restore propulsive coordination in postoperative ileus. In cases of clinical colic the primary requirement is control of pain. Agents used for this purpose may adversely affect motility, and choice requires knowledge of their actions in this respect. In addition, drugs used for other purposes, anthelmintics for instance, may also influence gut motility. A synopsis of the actions of the agents commonly employed in GI motility control and some associated drugs are displayed in Table 3. Recent advances in the understanding of drug action on the gut should help in the selection of drugs for clinical use.     

Toxic feed constituents in the horse.

Poisoning cases in horses associated with dietary exposures can encompass a wide variety of etiologies that can be caused by natural or man-made components. Feed mixing errors and ingestion of feed formulated for other species are the most common means by which poisonings from man-made materials occur. Ionophore feed additives and antibacterial agents are especially toxogenic to horses. Effects of ionophores in horses include clinical, clinicopathologic, and pathologic changes associated with cardiac, muscular, and neurologic tissues involvement. The acute effects of ionophores, however, can result in long-term cardiac dysfunction. Antibacterial effects are associated with changed microbial populations in the digestive tract that results in bacterial toxin liberation. These bacterial toxins damage the mucosa, and they result in systemic effects. For either type of feed-associated poisoning, it is critical that samples be analyzed for an accurate diagnosis.     

Management of toxicoses

This article provides information on the detoxification of and supportive care for poisoned animals. Involved are measures to control life-threatening manifestations of toxicoses, to remove agents from the digestive tract, skin, or eyes, and to promote removal of systemically absorbed toxicants. The use of these methods is often of paramount importance in an effort to limit organ damage and to enable a poisoned animal to survive.     

合成氨基酸对肉鸡肠道功能的改善作用

鸡球虫病、坏死性肠炎等肠道感染可能对消化道内源性氨基酸损失产生较大影响。虽然对这一课题的了解不多，但相关文献报道了这些疾病对氨基酸表观回肠消化率的影响。在确定肠内氨基酸流动时必须考虑多种因素，包括肉鸡的年龄、是否有病原体、肠内氨基酸代谢等。胃肠道和肝脏共同承担向外周血释放氨基酸的任务，这些氨基酸是支持蛋白质合成所必需的。一般来说，肠道是氨基酸代谢反应的一个非常活跃的器官系统，它首先会满足自身对氨基酸的需求，然后才会将氨基酸输送到机体其他部分。因此，本综述旨在讨论影响肠内氨基酸流动的因素及日粮氨基酸和肠道感染对氨基酸利用和代谢的影响。     

羊消化道寄生虫种类及防治措施

羊消化道的寄生虫病较多,不仅能不同程度地影响羊只的生长发育,降低生产性能,严重的还能造成羊只死亡,对养羊业危害较为严重。笔者概述了羊消化道寄生虫种类及不同地区、季节、年龄羊消化道寄生虫的感染情况,并介绍不同羊消化道寄生虫常用的驱虫药及防治策略。     

Subclinical infection with the nematode Trichostrongylus colubriformis increases gastrointestinal tract leucine metabolism and reduces availability of leucine for other tissues

Gastrointestinal (GI) tract leucine metabolism was measured in 6- to 9-mo-old lambs subjected to trickle infection with Trichostrongylus colubriformis larvae and in separate animals that were not infected. Animals prepared with a jejunal catheter and with indwelling catheters into the aorta and the portal- (PDV) and mesenteric- (MDV) drained viscera were infused simultaneously with [1-13C] and [5,5,5-2H3] leucine to determine GI tract sequestration of leucine from arterial and luminal amino acid pools by tracer and tracee arteriovenous concentration differences. Leucine oxidative losses and net fluxes were also determined across the GI tract. Infection had no detectable effect on whole-body leucine flux, but it increased total GI tract leucine sequestration by 24% (P<.05) and GI tract oxidative losses of leucine by 22 to 41% (P<.01). Net PDV fluxes of leucine were decreased by 20 to 32% during the infection. The infection did not alter either the proportion of precursor leucine used by GI tract metabolism that was derived from the arterial leucine pool (.84 to .88) or the proportional sequestration of digesta-derived leucine during "first pass" absorptive metabolism (.12 to .18). These findings help to elucidate the metabolic basis for the reduced growth rates and nitrogen retention observed when animals are subjected to subclinical nematode infection.