RESUMEN
Study objectives were to evaluate the effects of mitoquinol (MitoQ) on production parameters, gastrointestinal tract (GIT; stomach and small and large intestines) weight, and circulating leukocytes during a 24-h acute heat stress (HS) challenge. Crossbred gilts [nâ =â 32; 49.1â ±â 2.4 kg body weight (BW)] were blocked by BW and randomly assigned to 1 of 4 environmental-therapeutic treatments: 1) thermoneutral (TN) control (nâ =â 8; TNCON), 2) TN and MitoQ (nâ =â 8; TNMitoQ), 3) HS control (nâ =â 8; HSCON), or 4) HS and MitoQ (nâ =â 8; HSMitoQ). Pigs were moved into individual pens and allowed to acclimate for 6 d. The study consisted of 2 experimental periods (P). During P1 (2 d), all pigs remained in TN conditions (20.6â ±â 1.5 °C) and were fed ad libitum. During P2 (24 h), pigs were fed ad libitum and exposed to either TN or constant HS (37.3â ±â 1.3 °C). Mitoquinol (40 mg/d) was orally administered twice daily (0700 and 1800 hours) during P1 and P2. As expected, pigs exposed to HS had increased rectal temperature, skin temperature, and respiration rate (+1.5 °C, +8.7 °C, and +86 bpm, respectively; Pâ <â 0.01) compared to their TN counterparts. Compared to TN, HS pigs had decreased feed intake (67%; Pâ <â 0.01) and significant BW loss (+1.5 vs. -1.9 kg, respectively; Pâ <â 0.01). Total GIT weight was decreased in HS relative to TN pigs (Pâ <â 0.01), and this was influenced by decreased luminal contents (2.43 vs. 3.26 kg, respectively; Pâ <â 0.01) and reduced empty GIT mass (3.21 vs. 3.48 kg, respectively; Pâ =â 0.03). Stomach contents remained similar between TN and HS pigs (Pâ >â 0.54) but tended to increase in MitoQ relative to CON pigs (0.90 vs. 0.63 kg, respectively; Pâ =â 0.08). Stomach content as a percentage of the previous 24 h feed intake was increased in HS compared to the TN controls (93% vs. 31%; Pâ <â 0.01). In contrast, small and large intestinal contents were decreased in HS compared to TN pigs (23% and 49%, respectively; Pâ <â 0.01). Liver weight decreased in HS relative to TN pigs (1.15 vs. 1.22 kg, respectively; Pâ =â 0.02), and was decreased in MitoQ compared to CON pigs (1.13 vs. 1.24 kg; Pâ <â 0.01). Circulating lymphocytes tended to be decreased in HS relative to TN pigs (16%; Pâ =â 0.07). In summary, acute HS increased all body temperature indices, negatively influenced animal performance, and differentially altered GIT motility as evidenced by decreased gastric emptying and increased intestinal transit. However, MitoQ supplementation did not appear to ameliorate these effects.
Heat stress (HS) causes enormous financial losses to animal agriculture due to its adverse effects on animal productivity. While the mechanisms behind HS-induced malaise are multifaceted and intricate, evidence points to intestinal barrier dysfunction and the ensuing immune response as a primary contributor. Presumably, HS induces oxidative stress (OS) within the intestinal epithelium, potentially leading to intestinal hyperpermeability. Mitochondria are the primary source of endogenous reactive oxygen species; thus, administering mitochondria-targeted antioxidants, such as mitoquinol (MitoQ), may be more effective at reducing OS than traditional dietary antioxidants (e.g., vitamin E, selenium). We have previously observed positive effects of MitoQ on growth performance in acutely heat-stressed barrows, which prompted our objective to determine if the results were repeatable with gilts. Herein, HS increased all body temperature indices, reduced feed intake, and caused severe body weight loss. Additionally, HS reduced gastrointestinal tract (GIT) weight and differentially altered GIT luminal contents, suggesting HS disparately affects GIT motility. However, contrary to our expectations, MitoQ did not alleviate these physiological and phenotypic responses to HS. Altogether, the beneficial results from our previous MitoQ experiment in barrows were not repeatable in gilts, and it remains unclear whether supplementing antioxidants during HS is beneficial for animal performance.
Asunto(s)
Ubiquinona , Animales , Femenino , Porcinos/fisiología , Ubiquinona/análogos & derivados , Ubiquinona/farmacología , Ubiquinona/administración & dosificación , Compuestos Organofosforados/farmacología , Compuestos Organofosforados/administración & dosificación , Tracto Gastrointestinal/efectos de los fármacos , Calor , Respuesta al Choque Térmico/efectos de los fármacos , Enfermedades de los Porcinos/tratamiento farmacológico , Tamaño de los Órganos/efectos de los fármacos , Distribución AleatoriaRESUMEN
Study objectives were to determine the effects of mitoquinol (MitoQ, a mitochondrial-targeted antioxidant) on biomarkers of metabolism and inflammation during acute heat stress (HS). Crossbred barrows [nâ =â 32; 59.0â ±â 5.6 kg body weight (BW)] were blocked by BW and randomly assigned to 1 of 4 environmental-therapeutic treatments: 1) thermoneutral (TN) control (nâ =â 8; TNCon), 2) TN and MitoQ (nâ =â 8; TNMitoQ), 3) HS control (nâ =â 8; HSCon), or 4) HS and MitoQ (nâ =â 8; HSMitoQ). Pigs were acclimated for 6 d to individual pens before study initiation. The trial consisted of two experimental periods (P). During P1 (2 d), pigs were fed ad libitum and housed in TN conditions (20.6â ±â 0.8 °C). During P2 (24 h), HSCon and HSMitoQ pigs were exposed to continuous HS (35.2â ±â 0.2 °C), while TNCon and TNMitoQ remained in TN conditions. MitoQ (40 mg/d) was orally administered twice daily (0700 and 1800 hours) during P1 and P2. Pigs exposed to HS had increased rectal temperature, skin temperature, and respiration rate (+1.5 °C, +6.8 °C, and +101 breaths per minute, respectively; Pâ <â 0.01) compared to their TN counterparts. Acute HS markedly decreased feed intake (FI; 67%; Pâ <â 0.01); however, FI tended to be increased in HSMitoQ relative to HSCon pigs (1.5 kg vs. 0.9 kg, respectively; Pâ =â 0.08). Heat-stressed pigs lost BW compared to their TN counterparts (-4.7 kg vs. +1.6 kg, respectively; Pâ <â 0.01); however, the reduction in BW was attenuated in HSMitoQ compared to HSCon pigs (-3.9 kg vs. -5.5 kg, respectively; Pâ <â 0.01). Total gastrointestinal tract weight (empty tissue and luminal contents) was decreased in HS pigs relative to their TN counterparts (6.2 kg vs. 8.6 kg, respectively; Pâ <â 0.01). Blood glucose increased in HSMitoQ relative to HSCon pigs (15%; Pâ =â 0.04). Circulating non-esterified fatty acids (NEFA) increased in HS compared to TN pigs (Pâ <â 0.01), although this difference was disproportionately influenced by elevated NEFA in HSCon relative to HSMitoQ pigs (251 µEq/L vs. 142 µEq/L; Pâ <â 0.01). Heat-stressed pigs had decreased circulating insulin relative to their TN counterparts (47%; Pâ =â 0.04); however, the insulin:FI ratio tended to increase in HS relative to TN pigs (Pâ =â 0.09). Overall, circulating leukocytes were similar across treatments (Pâ >â 0.10). Plasma C-reactive protein remained similar among treatments; however, haptoglobin increased in HS relative to TN pigs (48%; Pâ =â 0.03). In conclusion, acute HS exposure negatively altered animal performance, inflammation, and metabolism, which were partially ameliorated by MitoQ.
Heat stress (HS) compromises animal health and productivity, and this causes major economic losses in almost every livestock sector. The negative consequences of HS are thought to originate from intestinal barrier dysfunction and subsequent immune activation. The underlying causes of lost intestinal integrity during HS are likely multifactorial; however, intestinal ischemia, increased accumulation of reactive oxygen species, and the ensuing epithelial oxidative damage might be potential causes. Mitochondria-targeted antioxidants, such as mitoquinol (MitoQ), are probably more effective than traditional dietary antioxidants (i.e., selenium, vitamin E) at alleviating oxidative stress, as they localize and accumulate within the mitochondria, potentiating their antioxidant activity. Thus, the present study aimed to investigate MitoQ's role during a thermal event in growing pigs. Herein, HS increased all body temperature indices, decreased feed intake (FI), and induced substantial body weight (BW) loss. Interestingly, the reduction in FI and BW was less dramatic in pigs receiving MitoQ. Changes in circulating metabolism and the acute phase response were observed due to the HS challenge; however, contrary to our expectations, these changes were not offset by MitoQ administration. Although our results suggest a positive MitoQ effect on growth performance, future studies are needed to corroborate the replicability of this response during HS.
Asunto(s)
Ubiquinona , Animales , Ubiquinona/análogos & derivados , Ubiquinona/farmacología , Ubiquinona/administración & dosificación , Masculino , Porcinos , Compuestos Organofosforados/farmacología , Compuestos Organofosforados/administración & dosificación , Antioxidantes/farmacología , Calor/efectos adversos , Respuesta al Choque Térmico/efectos de los fármacos , Enfermedades de los Porcinos/tratamiento farmacológico , Trastornos de Estrés por Calor/veterinaria , Trastornos de Estrés por Calor/tratamiento farmacológico , Distribución Aleatoria , Temperatura Corporal/efectos de los fármacosRESUMEN
Study objectives were to characterize the effects of citrulline (CIT) on physiological and intestinal morphology metrics during heat stress (HS) and feed restriction. Forty crossbred gilts (30â ±â 2 kg body weight [BW]) were assigned to one of five treatments: (1) thermoneutral (TN) fed ad libitum (AL) with control (CON) supplement (TNAL; nâ =â 8), (2) TN pair-fed (PF) with CON (PF-CON; nâ =â 8), (3) TN PF with CIT (PF-CIT; nâ =â 8), (4) HS AL with CON (HS-CON; nâ =â 8), and (5) HS AL with CIT (HS-CIT; nâ =â 8). During the period (P) 1 (7 d), pigs were in TN conditions (23.6 °C) and fed AL their respective supplemental treatments. During P2 (2.5 d), HS-CON and HS-CIT pigs were fed AL and exposed to cyclical HS (33.6 to 38.3 °C), while TNAL, PF-CON, and PF-CIT remained in TN and were fed either AL or PF to their HS counterparts. Citrulline (0.13 g/kg BW) was orally administered twice daily during P1 and P2. HS increased rectal temperature (Tr), skin temperature (Ts), and respiration rate (RR) relative to TN pigs (0.8 °C, 4.7 °C, and 47 breaths/min, respectively; Pâ <â 0.01). However, HS-CIT had decreased RR (7 breaths/min, Pâ =â 0.04) and a tendency for decreased Tr (0.1 °C, Pâ =â 0.07) relative to HS-CON pigs. During P2, HS pigs had decreased feed intake (22%; Pâ <â 0.01) and a tendency for decreased average daily gain (Pâ =â 0.08) relative to TNAL pigs, and by experimental design, PF pigs followed this same pattern. Circulating lipopolysaccharide-binding protein tended to be decreased (29%; Pâ =â 0.08) in PF relative to TNAL pigs and was increased (41%; Pâ =â 0.03) in HS compared to PF pigs. Jejunum villus height was decreased in PF relative to TNAL pigs (15%; Pâ =â 0.03); however, CIT supplementation improved this metric during feed restriction (16%; Pâ =â 0.10). Jejunum mucosal surface area decreased in PF (16%; Pâ =â 0.02) and tended to decrease in HS (11%; Pâ =â 0.10) compared to TNAL pigs. Ileum villus height and mucosal surface area decreased in HS compared to TNAL pigs (10 and 14%, respectively; Pâ ≤â 0.04), but both parameters were rescued by CIT supplementation (Pâ ≤â 0.08). Intestinal myeloperoxidase and goblet cell area remained similar among treatments and intestinal segments (Pâ >â 0.24). In summary, CIT supplementation slightly improved RR and Tr during HS. Feed restriction and HS differentially affected jejunum and ileum morphology and while CIT ameliorated some of these effects, the benefit appeared dependent on intestinal section and stressor type.
Heat stress (HS) negatively affects animal health and production efficiency and is a significant economic burden to global animal agriculture. Although the mechanisms responsible for reduced animal productivity during HS are complex and multifaceted, increasing evidence points to decreased intestinal barrier function as an important mediator of this response. Furthermore, HS causes a voluntary reduction in feed intake, and feed restriction independently induces gastrointestinal hyperpermeability. Loss of intestinal barrier integrity facilitates bacteria translocation across the epithelium into local and systemic circulation, thus initiating an immune response. Dietary citrulline has been shown to support gut health by improving intestinal barrier integrity and modulating intestinal inflammation. Therefore, the current study investigated the effects of citrulline supplementation on physiological and intestinal morphology parameters in heat-stressed and feed-restricted growing pigs. Herein, citrulline supplementation reduced respiration rate and rectal temperature in pigs exposed to the thermal load. Heat stress and feed restriction compromised small intestinal morphology, and while supplementing citrulline improved some of these parameters, the effects depended on the intestinal region and stressor type. Additional research is needed to evaluate the potential effects of citrulline supplementation on gut health during HS or nutrient restriction.
Asunto(s)
Alimentación Animal , Citrulina , Suplementos Dietéticos , Animales , Citrulina/farmacología , Citrulina/administración & dosificación , Suplementos Dietéticos/análisis , Femenino , Alimentación Animal/análisis , Porcinos/fisiología , Dieta/veterinaria , Privación de Alimentos , Calor , Intestinos/efectos de los fármacos , Intestinos/anatomía & histología , Intestinos/fisiología , Temperatura Corporal/efectos de los fármacos , Respuesta al Choque Térmico/efectos de los fármacosRESUMEN
The influence of systemic immune activation on whole-body calcium (Ca) trafficking and gastrointestinal tract (GIT) physiology is not clear. Thus, the study objectives were to characterize the effects of lipopolysaccharide (LPS) on Ca pools and GIT dynamics to increase understanding of immune-induced hypocalcemia, ileus, and stomach hemorrhaging. Twelve crossbred pigs [44â ±â 3 kg body weight (BW)] were randomly assigned to 1 of 2 intramuscular treatments: (1) control (CON; 2 mL saline; nâ =â 6) or (2) LPS (40 µg LPS/kg BW; nâ =â 6). Pigs were housed in metabolism stalls to collect total urine and feces for 6 h after treatment administration, at which point they were euthanized, and various tissues, organs, fluids, and digesta were weighed, and analyzed for Ca content. Data were analyzed with the MIXED procedure in SAS 9.4. Rectal temperature and respiration rate increased in LPS relative to CON pigs (1.4 °C and 32%, respectively; Pâ ≤â 0.05). Inflammatory biomarkers such as circulating alkaline phosphatase, aspartate aminotransferase, and total bilirubin increased in LPS compared with CON pigs whereas albumin decreased (Pâ ≤â 0.02). Plasma glucose and urea nitrogen decreased and increased, respectively, after LPS (43% and 80%, respectively; Pâ <â 0.01). Pigs administered LPS had reduced circulating ionized calcium (iCa) compared to CON (15%; Pâ <â 0.01). Considering estimations of total blood volume, LPS caused an iCa deficit of 23 mg relative to CON (Pâ <â 0.01). Adipose tissue and urine from LPS pigs had reduced Ca compared to CON (39% and 77%, respectively; Pâ ≤â 0.05). There did not appear to be increased Ca efflux into GIT contents and no detectable increases in other organ or tissue Ca concentrations were identified. Thus, while LPS caused hypocalcemia, we were unable to determine where circulating Ca was trafficked. LPS administration markedly altered GIT dynamics including stomach hemorrhaging, diarrhea (increased fecal output and moisture), and reduced small intestine and fecal pH (Pâ ≤â 0.06). Taken together, changes in GIT physiology suggested dyshomeostasis and alimentary pathology. Future research is required to fully elucidate the etiology of immune activation-induced hypocalcemia and GIT pathophysiology.
Lipopolysaccharide (LPS) activates the immune system and this is accompanied with hypocalcemia and altered gastrointestinal tract (GIT) physiology. The study objectives were to characterize whole-body calcium (Ca) trafficking and evaluate GIT dynamics during LPS-induced immune activation. Ca concentrations were analyzed after intramuscular LPS injection. Administering LPS caused marked alterations in metabolic and inflammatory biomarkers and GIT dynamics, characterized by increased lower GIT motility and stomach hemorrhaging. Circulating Ca and adipose tissue and urine Ca output were decreased after LPS. Ca concentrations in other tissues and GIT contents were not detectably different. Thus, we were unable to account for about 110 mg Ca following LPS. Where and how circulating Ca is partitioned during immune activation remains unclear.
Asunto(s)
Calcio , Tracto Gastrointestinal , Lipopolisacáridos , Animales , Femenino , Masculino , Calcio/metabolismo , Tracto Gastrointestinal/efectos de los fármacos , Tracto Gastrointestinal/metabolismo , Lipopolisacáridos/farmacología , Distribución Aleatoria , Porcinos , Enfermedades de los Porcinos/inducido químicamenteRESUMEN
Objectives were to examine the temporal pattern of intestinal mast cell dynamics and the effects of a mast cell stabilizer (ketotifen [Ket]) during acute heat stress (HS) in growing pigs. Crossbred barrows (nâ =â 42; 32.3â ±â 1.9 kg body weight [BW]) were randomly assigned to 1 of 7 environmental-therapeutic treatments: (1) thermoneutral (TN) control (TNCon; nâ =â 6), (2) 2 h HS control (2 h HSCon; nâ =â 6), (3) 2 h HSâ +â Ket (2 h HSKet; nâ =â 6); (4) 6 h HSCon (nâ =â 6), (5) 6 h HSKet (nâ =â 6), (6) 12 h HSCon (nâ =â 6), or (7) 12 h HSKet (nâ =â 6). Following 5 d of acclimation to individual pens, pigs were enrolled in two experimental periods (P). During P1 (3 d), pigs were housed in TN conditions (21.5â ±â 0.8 °C) for the collection of baseline measurements. During P2, TNCon pigs remained in TN conditions for 12 h, while HS pigs were exposed to constant HS (38.1â ±â 0.2 °C) for either 2, 6, or 12 h. Pigs were euthanized at the end of P2, and blood and tissue samples were collected. Regardless of time or therapeutic treatment, pigs exposed to HS had increased rectal temperature, skin temperature, and respiration rate compared to their TNCon counterparts (1.9 °C, 6.9° C, and 119 breaths/min; Pâ <â 0.01). As expected, feed intake and BW gain markedly decreased in HS pigs relative to their TNCon counterparts (Pâ <â 0.01). Irrespective of therapeutic treatment, circulating corticotropin-releasing factor decreased from 2 to 12 h of HS relative to TNCon pigs (Pâ <â 0.01). Blood cortisol increased at 2 h of HS (2-fold; Pâ =â 0.04) and returned to baseline by 6 h. Plasma histamine (a proxy of mast cell activation) remained similar across thermal treatments and was not affected by Ket administration (Pâ >â 0.54). Independent of Ket or time, HS increased mast cell numbers in the jejunum (94%; Pâ <â 0.01); however, no effects of HS on mast cell numbers were detected in the ileum or colon. Jejunum and ileum myeloperoxidase area remained similar among treatments (Pâ >â 0.58) but it tended to increase (12%; Pâ =â 0.08) in the colon in HSCon relative to TNCon pigs. Circulating lymphocytes and basophils decreased in HSKet relative to TN and HSCon pigs (Pâ ≤â 0.06). Blood monocytes and eosinophils were reduced in HS pigs relative to their TNCon counterparts (Pâ <â 0.01). In summary, HS increased jejunum mast cell numbers and altered leukocyte dynamics and proinflammatory biomarkers. However, Ket administration had no effects on mast cell dynamics measured herein.
Heat stress (HS) affects various physiological, metabolic, and endocrine parameters, ostensibly due to reduced intestinal barrier integrity and the ensuing immune response. Evidence indicates that generalized "stress" may be a critical component of HS-induced leaky gut, a mechanism likely mediated by mast cells. Mast cell activation has been extensively associated with various stress-related intestinal inflammatory conditions; however, its contribution to intestinal barrier dysfunction during HS remains unclear. Thus, this study was designed to evaluate mast cell dynamics during an acute HS challenge and to assess the effects a mast cell stabilizer on biomarkers of intestinal inflammation. Herein, HS induced a rapid increase in circulating cortisol, increased jejunum mast cell numbers, and altered metabolism, leukocyte dynamics, and proinflammatory biomarkers. Contrary to our hypothesis, HS did not alter circulating histamine (a biomarker of mast cell activation), and mast cell stabilization did not affect mast cell numbers nor altered histamine concentrations. Altogether, our observations support a connection between HS and intestinal mast cell infiltration that may contribute to the pathophysiology of intestinal dysfunction during a heat load.
Asunto(s)
Trastornos de Estrés por Calor , Enfermedades de los Porcinos , Porcinos , Animales , Dieta , Mastocitos , Respuesta al Choque Térmico , Temperatura Cutánea , Recto , Calor , Trastornos de Estrés por Calor/veterinariaRESUMEN
Study objectives were to determine the effects of dietary live yeast (Saccharomyces cerevisiae strain CNCM I-4407; ActisafHR+; 0.25g/kg of feed; Phileo by Lesaffre, Milwaukee, WI) on growth performance and biomarkers of metabolism and inflammation in heat-stressed and nutrient-restricted pigs. Crossbred barrows (n = 96; 79 ± 1 kg body weight [BW]) were blocked by initial BW and randomly assigned to one of six dietary-environmental treatments: 1) thermoneutral (TN) and fed ad libitum the control diet (TNCon), 2) TN and fed ad libitum a yeast containing diet (TNYeast), 3) TN and pair-fed (PF) the control diet (PFCon), 4) TN and PF the yeast containing diet (PFYeast), 5) heat stress (HS) and fed ad libitum the control diet (HSCon), or 6) HS and fed ad libitum the yeast diet (HSYeast). Following 5 d of acclimation to individual pens, pigs were enrolled in two experimental periods (P). During P1 (7 d), pigs were housed in TN conditions (20 °C) and fed their respective dietary treatments ad libitum. During P2 (28 d), HSCon and HSYeast pigs were fed ad libitum and exposed to progressive cyclical HS (28-33 °C) while TN and PF pigs remained in TN conditions and were fed ad libitum or PF to their HSCon and HSYeast counterparts. Pigs exposed to HS had an overall increase in rectal temperature, skin temperature, and respiration rate compared to TN pigs (0.3 °C, 5.5 °C, and 23 breaths per minute, respectively; P < 0.01). During P2, average daily feed intake (ADFI) decreased in HS compared to TN pigs (30%; P < 0.01). Average daily gain and final BW decreased in HS relative to TN pigs (P < 0.01); however, no differences in feed efficiency (G:F) were observed between HS and TN treatments (P > 0.16). A tendency for decreased ADFI and increased G:F was observed in TNYeast relative to TNCon pigs (P < 0.10). Circulating insulin was similar between HS and TN pigs (P > 0.42). Triiodothyronine and thyroxine levels decreased in HS compared to TN treatments (~19% and 20%, respectively; P < 0.05). Plasma tumor necrosis factor-alpha (TNF-α) did not differ across treatments (P > 0.57) but tended to decrease in HSYeast relative to HSCon pigs (P = 0.09). In summary, dietary live yeast did not affect body temperature indices or growth performance and had minimal effects on biomarkers of metabolism; however, it tended to improve G:F under TN conditions and tended to reduce the proinflammatory mediator TNF-α during HS. Further research on the potential role of dietary live yeast in pigs during HS or nutrient restriction scenarios is warranted.
RESUMEN
Study objectives were to determine the effects of continuously infusing glucose (GLC) or casein (CAS) into the terminal ileum on biomarkers of metabolism, inflammation, and intestinal morphology in growing pigs. Crossbred gilts (n = 19; 81 ± 3 kg body weight [BW]) previously fitted with T-cannulas at terminal ileum were used in the current experiment. Following 4 d of acclimation, pigs were enrolled in 2 experimental 4-d periods (P). During P1, pigs were housed in individual pens and fed ad libitum for collection of baseline parameters. At the beginning of P2, pigs were assigned to 1 of 3 infusion treatments: 1) control (CON; water; 3 liters/d; n = 7), 2) GLC (dextrose 50%; 500 g/d; n = 6;), or 3) CAS (casein sodium salt; 300 g/d; n = 6). Water, GLC, and CAS solutions were continuously infused at a rate of 125 mL/h for the entirety of P2. Animals were euthanized at the end of P2, and intestinal tissue was collected. During P2, average daily feed intake differed across treatments and was reduced in GLC compared with CON pigs (14%), while CAS pigs consumed an intermediate amount (P = 0.05). Average daily gain and final BW were similar across treatments. A treatment by time interaction was observed for blood urea nitrogen (BUN; P < 0.01), as it decreased in GLC (21%) while it gradually increased in CAS (76%) pigs relative to CON pigs. Mild hyperthermia occurred with both GLC and CAS infusions relative to CON (+0.3 and 0.2 °C, respectively; P < 0.01). Blood neutrophils increased in CAS relative to CON pigs (26%) but remained similar between CON and GLC treatments (P < 0.01). Blood monocytes decreased in GLC relative to CON pigs (24%) while CAS pigs had an intermediate value (P = 0.03). Circulating lipopolysaccharide binding protein tended to decrease in GLC (29%) relative to CON pigs but remained similar between CON and CAS pigs (P = 0.10). Plasma tumor necrosis factor-alpha was similar across treatments. Ileum villus height:crypt depth was increased in CAS compared with CON pigs (33%; P = 0.05) while GLC pigs had an intermediate value. Colon myeloperoxidase-stained area increased in CAS compared with CON pigs (45%; P = 0.03) but remained similar between GLC and CON pigs. In summary, continuously infusing GLC or CAS into the terminal ileum appeared to stimulate a mild immune response and differently altered BUN patterns but had little or no effects on blood inflammatory markers, intestinal morphology, or key production parameters.
Asunto(s)
Glucosa , Enfermedades de los Porcinos , Alimentación Animal/análisis , Animales , Biomarcadores , Caseínas , Dieta , Femenino , Íleon , Inflamación/veterinaria , PorcinosRESUMEN
Study objectives were to determine the effects of rapamycin (Rapa) on biomarkers of metabolism and inflammation during acute heat stress (HS) in growing pigs. Crossbred barrows (n = 32; 63.5 ± 7.2 kg body weight [BW]) were blocked by initial BW and randomly assigned to 1 of 4 environmental-therapeutic treatments: 1) thermoneutral (TN) control (n = 8; TNCon), 2) TN and Rapa (n = 8; TNRapa), 3) HS control (n = 8; HSCon), or 4) HS and Rapa (n = 8; HSRapa). Following 6 d of acclimation to individual pens, pigs were enrolled in two experimental periods (P). During P1 (10 d), pigs were fed ad libitum and housed in TN conditions (21.3 ± 0.2°C). During P2 (24 h), HSCon and HSRapa pigs were exposed to constant HS (35.5 ± 0.4°C), while TNCon and TNRapa pigs remained in TN conditions. Rapamycin (0.15 mg/kg BW) was orally administered twice daily (0700 and 1800 hours) during both P1 and P2. HS increased rectal temperature and respiration rate compared to TN treatments (1.3°C and 87 breaths/min, respectively; P < 0.01). Feed intake (FI) markedly decreased in HS relative to TN treatments (64%; P < 0.01). Additionally, pigs exposed to HS lost BW (4 kg; P < 0.01), while TN pigs gained BW (0.7 kg; P < 0.01). Despite marked changes in phenotypic parameters caused by HS, circulating glucose and blood urea nitrogen did not differ among treatments (P > 0.10). However, the insulin:FI increased in HS relative to TN treatments (P = 0.04). Plasma nonesterified fatty acids (NEFA) increased in HS relative to TN treatments; although this difference was driven by increased NEFA in HSCon compared to TN and HSRapa pigs (P < 0.01). Overall, circulating white blood cells, lymphocytes, and monocytes decreased in HS compared to TN pigs (19%, 23%, and 33%, respectively; P ≤ 0.05). However, circulating neutrophils were similar across treatments (P > 0.31). The neutrophil-to-lymphocyte ratio (NLR) was increased in HS relative to TN pigs (P = 0.02); however, a tendency for reduced NLR was observed in HSRapa compared to HSCon pigs (21%; P = 0.06). Plasma C-reactive protein tended to differ across treatments (P = 0.06) and was increased in HSRapa relative to HSCon pigs (46%; P = 0.03). Circulating haptoglobin was similar between groups. In summary, pigs exposed to HS had altered phenotypic, metabolic, and leukocyte responses; however, Rapa administration had limited impact on outcomes measured herein.
Asunto(s)
Trastornos de Estrés por Calor , Enfermedades de los Porcinos , Animales , Temperatura Corporal , Trastornos de Estrés por Calor/tratamiento farmacológico , Trastornos de Estrés por Calor/veterinaria , Respuesta al Choque Térmico , Calor , Frecuencia Respiratoria , Sirolimus/farmacología , Estrés Fisiológico , PorcinosRESUMEN
Objectives were to determine the effects of a product containing electrolytes, osmolytes, and energetic compounds (EOEC) on body temperature indices in heat-stressed (HS) Holstein cows. Lactating cows were assigned to 1 of 2 treatments: 1) a control diet (n = 10) or 2) a control diet supplemented with 113 g/d of EOEC (n = 10; Bovine BlueLite® Pellets; TechMix LLC, Stewart, MN). The trial consisted of 2 experimental periods (P). During P1 (4 d), cows were fed their respective treatments and housed in thermoneutral conditions. During P2 (4 d), HS was artificially induced using an electric heat blanket (EHB). Overall, HS markedly increased vaginal temperature (Tv), rectal temperature (Tr), skin temperature (Ts), and respiration rate (RR) (P < .01). There were no dietary treatment differences in Tv, Tr, or RR; however, during P2 EOEC-supplemented cows had increased Ts (0.8 °C; P = .04). Compared to P1, HS decreased DMI and milk yield (45 and 27%, respectively, P < .01) similarly amongst treatments. Relative to P1, circulating insulin decreased (41%; P = .04) in CON cows, whereas it remained unaffected in EOEC-supplemented cows, resulting in a 2-fold increase in EOEC compared with CON-fed cows (P < .01) during P2. Relative to P1, HS increased circulating non-esterified fatty acids (NEFA; 63%; P < .01). During P2, there tended to be a treatment by day interaction on circulating NEFA, as concentrations decreased from d 2 to 4 of P2 in EOEC-fed cows but continued to increase in CON cows. In summary, feeding EOEC altered some key aspects of energetic metabolism and increased Ts.
Asunto(s)
Temperatura Corporal/efectos de los fármacos , Dieta/veterinaria , Electrólitos/metabolismo , Respuesta al Choque Térmico/efectos de los fármacos , Lactancia/efectos de los fármacos , Alimentación Animal/análisis , Animales , Bovinos , Suplementos Dietéticos/análisis , Electrólitos/administración & dosificación , Femenino , Distribución AleatoriaRESUMEN
Objectives were to evaluate the effects of an oral supplement containing soluble Ca, and live yeast in LPS-challenged dairy cows. The trial consisted of 2 experimental periods (P). During P1 (3 d), cows (n = 12) were fed ad libitum and baseline data was collected. At the beginning of P2 (which lasted 96 h), all cows were i.v. challenged with 0.375 µg/kg BW LPS. Cows were assigned randomly to 1 of 2 treatments: 1) control (CON; no bolus; n = 6) or 2) an oral bolus containing Ca and live yeast (CLY; YMCP Vitall® 44.718 g of elemental Ca; TechMix, LLC., Stewart, MN; n = 6), administered -0.5 and 6.5 h relative to LPS infusion. Following LPS administration, circulating Ca decreased in both treatments but supplemental CLY ameliorated the hypocalcemia (48 h area under the curve: -10.8 vs. -1.9 mmol/L × h; P < .01). Lipopolysaccharide decreased dry matter intake (DMI; 60%) similarly for both treatments on d 1, but overall (d 1-4) DMI tended to be reduced less (14 vs. 30%; P = .06) in CLY supplemented vs CON cows. Lipopolysaccharide reduced milk yield (70%; P < .01) from 12 to 24 h, but throughout P2, milk yield from CLY supplemented cows was increased (38%; P = .03) relative to CON cows. Overall during P2, circulating LPS-binding protein and serum amyloid A increased post LPS (3- and 4-fold, respectively, P < .01), but were unaffected by treatment (P ≥ .68). In conclusion, providing an oral supplement containing Ca and live yeast prior to and following LPS administration markedly ameliorated LPS-induced hypocalcemia and improved DMI and milk yield.