Animals were used under the supervision of an approved institutional protocol. Adult female Yorkshire pigs (mean weight 30 kg) were purchased from E.M. Parsons and Sons (Hadley, MA). General anesthesia was induced with 4.4 mg/kg of intramuscular Telazol (Fort Dodge Labs, Fort Dodge, IA). Once sedated, animals were intubated with a cuffed endotracheal tube, and anesthesia was maintained with 2% isoflurane/balance O2. A lower midline abdominal incision was used to expose the uterus and fallopian tubes. A NIR fluorescent (800 nm emission) hysterosalpingogram was performed using 10 μM indocyanine green (ICG; Akorn, Decatur, IL) in saline injected in utero. NIR fluorescence (700 nm emission) angiography was performed by intravenous bolus injection of 1 mg/kg methylene blue (Akorn). Real-time NIR fluorescence imaging was performed as described in [4 (link)] except that each independent NIR fluorescence image, i.e., 700 nm emission and 800 nm emission, could be assigned different pseudo-colors from a multi-color palette, and could have its brightness, contrast, and gamma adjusted independently by the surgeon.
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Telazol
Telazol
Telazol is a veterinary anesthetic agent used for the sedation and immobilization of various animal species.
It is a combination of the dissociative anesthetic tiletamine and the benzodiazepine tranquillizer zolazepam.
Telazol provides rapid onset of action, effective muscle relaxation, and a wide safety margin.
It is commonly used in wildlife research and management to safely capture and handle animals for examinations, procedures, and transportation.
PubCompare.ai enhances the reproducibility and accuracy of Telazol research by helping researchers locate the best protocols from literature, pre-prints, and patents, providing side-by-side comparisons to optimize study design and achieve more reliable results.
It is a combination of the dissociative anesthetic tiletamine and the benzodiazepine tranquillizer zolazepam.
Telazol provides rapid onset of action, effective muscle relaxation, and a wide safety margin.
It is commonly used in wildlife research and management to safely capture and handle animals for examinations, procedures, and transportation.
PubCompare.ai enhances the reproducibility and accuracy of Telazol research by helping researchers locate the best protocols from literature, pre-prints, and patents, providing side-by-side comparisons to optimize study design and achieve more reliable results.
Most cited protocols related to «Telazol»
Abdomen
Anesthesia
Angiography
Animals
Fallopian Tubes
Fluorescence
Gamma Rays
General Anesthesia
Hysterosalpingography
Indocyanine Green
Isoflurane
Methylene Blue
Pigs
Saline Solution
Sons
Supervision
Surgeons
Telazol
Uterus
Woman
Anesthesia
Animals
Blood Vessel
Catheters
Copper
Femoral Artery
Fluoroscopy
Heparin
Irritants
Ketamine
Pressure
Renal Artery
Sus scrofa
Telazol
Telemetry
Transducers
Xylazine
Abdomen
Anesthesia
Animals
Asepsis
Betadine
Body Temperature
Cesarean Section
Chest
Hysterotomy
Infant
Infant, Newborn
Infant Formula
Institutional Animal Care and Use Committees
Isoflurane
Isopropyl Alcohol
Lidocaine
Milk
Mothers
Nipples
Obstetric Delivery
Operating Tables
Operative Surgical Procedures
Pigs
Pregnancy
Preterm Infant
Sterility, Reproductive
Telazol
Umbilical Cord
Uterus
Vagina
Abdominal Cavity
Abdominal Muscles
Alloderm
Anesthesia
Animals
Animals, Laboratory
Antibiotic Prophylaxis
Aponeurosis
Areola
Biopharmaceuticals
Bladder Detrusor Muscle
Cattle
Cells
Cephalexin
Creativity
Cyanoacrylates
Dermis
Eosin
Euthanasia
Fascia
Feces
Fibrosis
Grafts
Grasp
Hernia
Herniorrhaphy
Homo sapiens
Inflammation
Innovativeness
Ketamine
Light Microscopy
Mesothelium
Microtomy
Operative Surgical Procedures
Paraffin Embedding
Pathologic Neovascularization
Pathologists
Pentobarbital
Pericardium
Peritoneum
Permacol
Pharmaceutical Preparations
Pigs
Polydioxanone
Postoperative Care
Potassium Chloride
Prolene
Sterility, Reproductive
Subcutaneous Fat
Sutures
Swine, Miniature
Telazol
Tissues
Transversus Abdominis
Wall, Abdominal
Woman
Xylazine
Acepromazine
ECHO protocol
Electricity
Monkeys
Telazol
Most recents protocols related to «Telazol»
Ticks were acquired from the Oklahoma State Tick Rearing Facility (OSU) (Stillwater, OK, USA). Equal numbers of each sex and species (I. scapularis and A. americanum) were obtained. For each lot of I. scapularis and A. americanum and prior to shipment to the study site, OSU screened a subsample of ticks (n = 10) for pathogens using standardized PCR assays. Ixodes scapularis were screened for B. burgdorferi and Anaplasma phagocytophilum. Amblyomma americanum were screened for the presence of Ehrlichia chaffeensis, Francisella tularensis and Rickettsia rickettsii. All PCR-screened ticks were negative for the above pathogens. Once ticks arrived at the study site, they were housed in an industry-standard desiccator with the relative humidity maintained at > 90% until enclosed in a feeding capsule for attachment to deer.
The feeding capsules utilized in this study were specifically designed for holding blood-feeding I. scapularis and A. americanum. Feeding capsules allow for the containment and localization of ticks and aid in facilitating blood-feeding [40 (link)]. The traditional stockinet sleeve method for feeding ticks on cattle [41 (link)–43 ] was determined to be inadequate for white-tailed deer. We instead developed a feeding capsule for deer application, which was in part based upon feeding capsules for ticks (referred to hereafter as tick feeding capsules) previously designed for tick-feeding on rabbits and sheep [44 ]. To make each capsule, sheets of ethylene–vinyl acetate foam were cut into three square pieces. Each square had a different outside area, allowing for flexibility (base, approx. 12 × 12 cm; middle, approx. 9 × 9 cm; top, approx. 7 × 7 cm), and had a combined depth of approximately 18 mm. The center of each square was cut away, creating an opening. The inner surface areas of the base and middle piece openings were each approximately 7 × 7 cm; the top piece had a smaller opening (approx. 1.5 × 1.5 cm) through which the ticks were to be inserted, which decreased the probability that ticks would escape through the top of the capsule (Additional file3 : Figure S2).
Deer were anesthetized using an intramuscular injection of telazol and xylazine at dosages of approximately 3 mg/kg and approximately 2.5 mg/kg, respectively. Once fully anesthetized, deer were weighed to the nearest 0.1 kg using a certified balance. Prior to blood collection and capsule attachment, large patches of fur on the neck were trimmed using electric horse clippers (Wahl®; Wahl Clipper Corp., Sterling, IL, USA). Prior to capsule attachment, 10 ml of blood was collected from the jugular vein of each deer using a 20-gauge needle. The blood from each individual deer was immediately placed into a vacutainer containing EDTA and was centrifuged for 10 min at 7000 revolutions/min. The plasma was transferred to 1.5-ml centrifuge tubes, which were then stored at − 20 °C until analysis.
Two identical tick feeding capsules were attached to opposing sides of the neck of each deer using a liberal amount of fabric glue (Tear Mender, St. Louis, MO, USA). Each capsule was held firmly in place for > 3 min to allow it to adhere to the skin and fur. For each deer, 20 I. scapularis mating pairs were placed within one capsule, and 20 A. americanum mating pairs were placed within the second capsule. Prior to tick attachment, 20 ticks (all same species and sex) were placed into a modified 5-ml syringe. Ticks were chilled in ice for approximately 5–10 min to slow movement. The 20 mating pairs were then carefully plunged into the capsules and a fine mesh lid was applied and reinforced with duct tape. Representative photos and video of the tick attachment process are presented in Fig.2 and Additional file 4 : Video S1, respectively. The capsules were further secured to deer by wrapping the neck with a veterinary bandage (3 M Company, St. Paul, MN, USA).![]()
The feeding capsules utilized in this study were specifically designed for holding blood-feeding I. scapularis and A. americanum. Feeding capsules allow for the containment and localization of ticks and aid in facilitating blood-feeding [40 (link)]. The traditional stockinet sleeve method for feeding ticks on cattle [41 (link)–43 ] was determined to be inadequate for white-tailed deer. We instead developed a feeding capsule for deer application, which was in part based upon feeding capsules for ticks (referred to hereafter as tick feeding capsules) previously designed for tick-feeding on rabbits and sheep [44 ]. To make each capsule, sheets of ethylene–vinyl acetate foam were cut into three square pieces. Each square had a different outside area, allowing for flexibility (base, approx. 12 × 12 cm; middle, approx. 9 × 9 cm; top, approx. 7 × 7 cm), and had a combined depth of approximately 18 mm. The center of each square was cut away, creating an opening. The inner surface areas of the base and middle piece openings were each approximately 7 × 7 cm; the top piece had a smaller opening (approx. 1.5 × 1.5 cm) through which the ticks were to be inserted, which decreased the probability that ticks would escape through the top of the capsule (Additional file
Deer were anesthetized using an intramuscular injection of telazol and xylazine at dosages of approximately 3 mg/kg and approximately 2.5 mg/kg, respectively. Once fully anesthetized, deer were weighed to the nearest 0.1 kg using a certified balance. Prior to blood collection and capsule attachment, large patches of fur on the neck were trimmed using electric horse clippers (Wahl®; Wahl Clipper Corp., Sterling, IL, USA). Prior to capsule attachment, 10 ml of blood was collected from the jugular vein of each deer using a 20-gauge needle. The blood from each individual deer was immediately placed into a vacutainer containing EDTA and was centrifuged for 10 min at 7000 revolutions/min. The plasma was transferred to 1.5-ml centrifuge tubes, which were then stored at − 20 °C until analysis.
Two identical tick feeding capsules were attached to opposing sides of the neck of each deer using a liberal amount of fabric glue (Tear Mender, St. Louis, MO, USA). Each capsule was held firmly in place for > 3 min to allow it to adhere to the skin and fur. For each deer, 20 I. scapularis mating pairs were placed within one capsule, and 20 A. americanum mating pairs were placed within the second capsule. Prior to tick attachment, 20 ticks (all same species and sex) were placed into a modified 5-ml syringe. Ticks were chilled in ice for approximately 5–10 min to slow movement. The 20 mating pairs were then carefully plunged into the capsules and a fine mesh lid was applied and reinforced with duct tape. Representative photos and video of the tick attachment process are presented in Fig.
Tick capsule attachment and tick attachment.
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Amblyomma americanum
Anaplasma phagocytophilum
Anesthetic Effect
ARID1A protein, human
Bandage
Biological Assay
BLOOD
Capsule
Cattle
Deer
Edetic Acid
Ehrlichia chaffeensis
Electricity
Equus caballus
Ethylenes
Females
Francisella tularensis
Humidity
Intramuscular Injection
Ixodes scapularis
Jugular Vein
Movement
Neck
Needles
Odocoileus virginianus
Oryctolagus cuniculus
pathogenesis
Plasma
Rickettsia rickettsii
Sheep
Skin
Syringes
Tears
Telazol
Ticks
vinyl acetate
Xylazine
Protocol full text hidden due to copyright restrictions
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Anesthesia
Animals
Cells
Copper
Disinfection
Fascia
Gelatins
Glutaral
Hemostasis
Ilium
Infection
Injuries
Laminectomy
Muscle Tissue
Needles
Normal Saline
Operative Surgical Procedures
Penicillins
Phosphotungstic Acid
Pigs
Porifera
Povidone Iodine
Propofol
Punctures, Lumbar
Skin
Spinal Canal
Spinal Cord
Telazol
Transmission Electron Microscopy
TSG101 protein, human
Vertebra
Western Blot
Wounds
Xylazine
Protocol full text hidden due to copyright restrictions
Open the protocol to access the free full text link
Animals
Anorexia
Biopsy
BLOOD
Body Weight
Cells
Centrifugation
Edetic Acid
Feces
Ficoll
Forceps
Freezing
Human Body
Intestines
Intubation
Isoflurane
Ketamine Hydrochloride
Movement
Neoplasms
Nutrients
Palliative Care
Plasma
Rectum
Sterility, Reproductive
Supervision
Telazol
Tissues
trizol
All procedures on pigs were approved by the Johns Hopkins University Animal Care and Use Committee and by the Animal Care and Use Review Office of the US Army Medical Research and Materiel Command for Award Number W81XWH-19-C-0022 (Fort Detrick, MD). In conducting research using animals, the investigators adhered to the Animal Welfare Act Regulations and other Federal statutes relating to animals and experiments involving animals and the principles set forth in the current version of the Guide for the Care and Use of Laboratory Animals, National Research Council.
Because there can be sex differences in the response to TBI (43 (link), 44 (link)) and TBI in the young and in military personnel is more prevalent in males (45 (link)), the study was conducted in male pigs. A total of 48 pigs weighing 28 ± 2 kg and approximately 3 months of age were used in the overall study. The experimental protocols for the TBI + HS experiment and the TBI alone experiment are delineated inFigure 1 . The pigs were sedated with intramuscular injection of Telazol (50 mg/ml tiletamine and 50 mg/ml zolazepam, 4.4 mg/kg each component), ketamine 2.2 mg/kg and xylazine 2.2 mg/kg. Isoflurane (4% in 30% O2) was administered via face mask to produce an anesthetic depth for oral intubation of the trachea. After a surgical plane of anesthesia was achieved, as assessed by the lack of limb withdrawal to hoof pinching and by looseness of muscle tone in the jaw, anesthesia was maintained with 2% isoflurane in approximately 30% O2 with mechanical ventilation of the lungs. The antibiotic Baytril 10 mg/kg (100 mg/ml) was injected intramuscularly. Surgery was conducted using aseptic techniques. Through a 5-cm neck incision, an external jugular vein was isolated by blunt dissection. The vein was ligated and a catheter was advanced toward the heart and secured with another ligature. For arterial catheterization, we chose the axillary artery because occlusion of the carotid artery could limit cerebral blood flow after TBI and catheterization of the femoral artery can limit use of the hindlimb. An incision was made in the axilla, and the axillary artery was isolated, ligated, and cannulated with a flexible polyvinyl catheter that minimized kinking. The arterial and venous catheters were tunneled subcutaneously to the back of the neck, where they exited through a small incision. Pigs were able to bear weight on the forelimb and ambulate on the day after surgery.
Because there can be sex differences in the response to TBI (43 (link), 44 (link)) and TBI in the young and in military personnel is more prevalent in males (45 (link)), the study was conducted in male pigs. A total of 48 pigs weighing 28 ± 2 kg and approximately 3 months of age were used in the overall study. The experimental protocols for the TBI + HS experiment and the TBI alone experiment are delineated in
Full text: Click here
Anesthesia
Anesthetics
Animals
Animals, Laboratory
Antibiotics
Arterial Occlusion
Arteries
Asepsis
Axilla
Axillary Artery
Baytril
Bears
Carotid Arteries
Catheterization
Catheters
Cerebrovascular Circulation
Common Carotid Artery
Dental Occlusion
Dissection
Face
Femoral Artery
Heart
Hindlimb
Hoof
Intramuscular Injection
Intubation, Intratracheal
Isoflurane
Jugular Vein
Ketamine
Ligature
Males
Mechanical Ventilation
Military Personnel
Muscle Tonus
Neck
Operative Surgical Procedures
Pigs
Polyvinyls
Telazol
Tiletamine
Upper Extremity
Veins
Xylazine
Zolazepam
The weight of each animal was acquired when sedated, after administrations of Telazol and Methohexatol and prior to intubation. Once intubated, arterial pressures were monitored while under anesthesia to ensure that there were no adverse cardiac events prior to organ explantation.
Once isolated and perfused, perfusate flow through the abdominal aorta and renal arteries was delivered via the pulsatile pump and the arterial pressure of the given kidney block was acquired using pressure transducers on a custom EMKA system (EMKA Technologies) to ensure an average systolic pressure of 120 mm Hg. Temperature of the kidney capsule was monitored using a temperature probe (Fluke Corporation) and maintained at 37 ± 0.5°C. Once perfused, urinary flow was measured every 15 min for up to 3 h, using a graduated cylinder and a stopwatch. Concurrently, urinary and perfusate samples were taken and analyzed using an ABL90 Flex Plus blood gas analyzer (Radiometer) to compare urine and perfusate compositions.
While most of the data were acquired in real time, dimensions of the renal arteries were postprocessed from renal angiograms. Images of the left and right renal angiograms were taken immediately after perfusion was started using an Isovue® contrast agent. The images were imported into ImageJ (National Institutes of Health) where the 6F (2 mm diameter) guide catheter used to deliver the contrast was used as a reference to calibrate the measuring tool. Once calibrated, the measuring tool was used to measure the length and takeoff angles of the main renal arteries as well as the diameter of the proximal, middle, and distal main segments (see Figure3 ). All statistical analysis for this study was performed via Minitab software (State College).
Once isolated and perfused, perfusate flow through the abdominal aorta and renal arteries was delivered via the pulsatile pump and the arterial pressure of the given kidney block was acquired using pressure transducers on a custom EMKA system (EMKA Technologies) to ensure an average systolic pressure of 120 mm Hg. Temperature of the kidney capsule was monitored using a temperature probe (Fluke Corporation) and maintained at 37 ± 0.5°C. Once perfused, urinary flow was measured every 15 min for up to 3 h, using a graduated cylinder and a stopwatch. Concurrently, urinary and perfusate samples were taken and analyzed using an ABL90 Flex Plus blood gas analyzer (Radiometer) to compare urine and perfusate compositions.
While most of the data were acquired in real time, dimensions of the renal arteries were postprocessed from renal angiograms. Images of the left and right renal angiograms were taken immediately after perfusion was started using an Isovue® contrast agent. The images were imported into ImageJ (National Institutes of Health) where the 6F (2 mm diameter) guide catheter used to deliver the contrast was used as a reference to calibrate the measuring tool. Once calibrated, the measuring tool was used to measure the length and takeoff angles of the main renal arteries as well as the diameter of the proximal, middle, and distal main segments (see Figure
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Anesthesia
Angiography
Animals
Aortas, Abdominal
BLOOD
Capsule
Cardiac Events
Catheters
Diuresis
Intubation
Isovue
Kidney
Perfusion
Renal Artery
Systolic Pressure
Telazol
Transducers, Pressure
Trematoda
Urine
Top products related to «Telazol»
Sourced in United States
Telazol is a sterile, injectable anesthetic agent composed of equal parts of the active ingredients tiletamine hydrochloride and zolazepam hydrochloride. It is intended for use in veterinary medicine as a general anesthetic and for the chemical restraint of animals.
Sourced in United States, Germany, Sweden, France, Denmark, United Kingdom, Canada, Italy, Norway, Austria, Switzerland, Poland, Puerto Rico, Belgium, Australia, Spain, Finland
Isoflurane is a volatile anesthetic agent used in the medical field. It is a clear, colorless, and nonflammable liquid that is vaporized and administered through inhalation. Isoflurane is primarily used to induce and maintain general anesthesia during surgical procedures.
Sourced in United States
Telazol is a sterile injectable anesthetic agent used in veterinary medicine. It contains the active ingredients tiletamine and zolazepam. Telazol is primarily used to induce and maintain general anesthesia in animals.
Sourced in United States
The Avanti is a compact laboratory centrifuge designed for general-purpose applications. It provides consistent and reliable performance for a variety of sample preparation and separation tasks. The Avanti features a brushless motor and a sturdy construction to ensure efficient and quiet operation.
Sourced in United States, Germany, United Kingdom, Macao
Ketamine is a dissociative anesthetic used in veterinary medicine. It is a fast-acting medication that can be administered by injection to induce anesthesia and provide pain relief in animals. Ketamine is primarily used for sedation, analgesia, and the induction and maintenance of general anesthesia in various animal species.
Sourced in United States
Fatal Plus is a specialized laboratory instrument designed for performing precise chemical analyses. It features advanced detection capabilities and is capable of accurately measuring a wide range of chemical compounds. The core function of Fatal Plus is to provide researchers and scientists with a reliable tool for conducting in-depth analysis of various substances.
Sourced in United States
Xylazine is a laboratory animal sedative used in veterinary medicine. It is a centrally-acting alpha-2 adrenergic agonist that produces sedation, analgesia, and muscle relaxation in various animal species.
Sourced in Germany, United States, Australia, United Kingdom, Canada
The 32-channel head coil is a key component in magnetic resonance imaging (MRI) systems. It is designed to acquire high-quality images of the human head, enabling detailed visualization and analysis of brain structure and function.
Sourced in Germany, Italy, United States, United Kingdom, Canada, China, Japan
Male CD-1 mice are a commonly used outbred mouse strain that exhibit genetic diversity. They are suitable for a variety of research applications.
Sourced in Sao Tome and Principe
The PhysioTel® telemetry system is a wireless data acquisition system designed for monitoring physiological parameters in animal research. It enables continuous and remote collection of data from animals during normal activities without the need for physical connections. The system allows for the transmission of data from implanted or externally mounted sensors to a receiver for further analysis.
More about "Telazol"
Telazol is a versatile veterinary anesthetic agent that has been widely used in wildlife research and management.
It is a combination of the dissociative anesthetic tiletamine and the benzodiazepine tranquilizer zolazepam, providing rapid onset of action, effective muscle relaxation, and a wide safety margin.
Telazol is commonly employed to safely capture and handle various animal species, including those encountered in field studies, for examinations, procedures, and transportation.
The use of Telazol is often compared to other anesthetic agents such as Isoflurane, a commonly used inhalation anesthetic, and Ketamine, another dissociative anesthetic.
Avanti, a related compound, and Fatal Plus, a euthanasia solution, may also be considered in certain contexts.
Xylazine, a sedative and muscle relaxant, is sometimes used in conjunction with Telazol to enhance the desired effects.
To ensure the reproducibility and accuracy of Telazol research, PubCompare.ai, an AI-driven platform, can be utilized to locate the best protocols from literature, pre-prints, and patents.
By providing side-by-side comparisons, PubCompare.ai helps researchers optimize their study design and achieve more reliable results.
The platform's capabilities extend beyond Telazol, as it can also assist with research involving other techniques, such as the use of a 32-channel head coil for neuroimaging studies and the integration of PhysioTel® telemetry systems for physiological monitoring in animal studies, particularly in Male CD-1 mice.
It is a combination of the dissociative anesthetic tiletamine and the benzodiazepine tranquilizer zolazepam, providing rapid onset of action, effective muscle relaxation, and a wide safety margin.
Telazol is commonly employed to safely capture and handle various animal species, including those encountered in field studies, for examinations, procedures, and transportation.
The use of Telazol is often compared to other anesthetic agents such as Isoflurane, a commonly used inhalation anesthetic, and Ketamine, another dissociative anesthetic.
Avanti, a related compound, and Fatal Plus, a euthanasia solution, may also be considered in certain contexts.
Xylazine, a sedative and muscle relaxant, is sometimes used in conjunction with Telazol to enhance the desired effects.
To ensure the reproducibility and accuracy of Telazol research, PubCompare.ai, an AI-driven platform, can be utilized to locate the best protocols from literature, pre-prints, and patents.
By providing side-by-side comparisons, PubCompare.ai helps researchers optimize their study design and achieve more reliable results.
The platform's capabilities extend beyond Telazol, as it can also assist with research involving other techniques, such as the use of a 32-channel head coil for neuroimaging studies and the integration of PhysioTel® telemetry systems for physiological monitoring in animal studies, particularly in Male CD-1 mice.