Latta T: No. 3. Letter from DR. LATTA, of Leith, detailing Three Cases, of which one was successful, Lancet 18(460):370-373, 1832.
Maitland K, Kiguli S, Opoka RO, et al: Mortality after fluid bolus in African children with severe infection, N Engl J Med 364(26):2483-2495, 2011.
Malbrain ML, Marik PE, Witters I, et al: Fluid overload, de-resuscitation, and outcomes in critically ill or injured patients: a systematic review with suggestions for clinical practice, Anaesthesiol Intensive Ther 46(5):361-380, 2014.
Silverstein DC, Aldrich J, Haskins SC, et al: Assessment of changes in blood volume in response to resuscitative fluid administration in dogs, J Vet Emerg Crit Care 15(3):185-192, 2005.
Hopper K, Garcia Rojas A, Barter L: An online survey of small animal veterinarians regarding current fluid therapy practices in dogs and cats, J Am Vet Med Assoc 252(5):553-559, 2018.
Yozova ID, Howard J, Sigrist NE, Adamik KN: Current trends in volume replacement therapy and the use of synthetic colloids in small animals-an internet-based survey (2016), Front Vet Sci 4:140, 2017.
Glassford NJ, Ma˚rtensson J, Eastwood GM, et al: Defining the characteristics and expectations of fluid bolus therapy: a worldwide perspective, J Crit Care 35:126-132, 2016.
Gelbart B, Schlapbach L, Ganeshalingham A, et al: Fluid bolus therapy in critically ill children: a survey of practice among paediatric intensive care doctors in Australia and New Zealand, Crit Care Resusc 20(2):131-138, 2018.
Celeita-Rodríguez N, Teixeira-Neto FJ, Garofalo NA, et al: Comparison of the diagnostic accuracy of dynamic and static preload indexes to predict fluid responsiveness in mechanically ventilated, isoflurane anesthetized dogs, Vet Anaesth Analg 46(3):276-288, 2019.
Lilly CM: The ProCESS trial—a new era of sepsis management, N Engl J Med 370(18):1750-1751, 2014.
Cameron PA, Cooper DJ, Higgins AM, et al: Goal-directed resuscitation for patients with early septic shock, N Engl J Med 371(16):1496-1506, 2014.
Rabozzi R, Oricco S, Meneghiniet C, et al: Evaluation of the caudal vena cava diameter to abdominal aortic diameter ratio and the caudal vena cava respiratory collapsibility for predicting fluid responsiveness in a heterogeneous population of hospitalized conscious dogs, J Vet Med Sci 82(3):337-344, 2020.
Pickett JD, Bridges E, Kritek PA, Whitney JD: Passive leg-raising and prediction of fluid responsiveness: systematic review, Crit Care Nurse 37(2):32-47, 2017.
McGee S, Abernethy WB III, Simel DL: The rational clinical examination. Is this patient hypovolemic? JAMA 281(11):1022-1029, 1999.
Boscan P, Pypendop BH, Siao KT, et al: Fluid balance, glomerular filtration rate, and urine output in dogs anesthetized for an orthopedic surgical procedure, Am J Vet Res 71(5):501-507, 2010.
Saugel B, Ringmaier S, Holzapfel K, et al: Physical examination, central venous pressure, and chest radiography for the prediction of transpulmonary thermodilution-derived hemodynamic parameters in critically ill patients: a prospective trial, J Crit Care 26(4):402-410, 2011.
Zulauf D, Kaser-Hotz B, Hässig M, et al: Radiographic examination and outcome in consecutive feline trauma patients, Vet Comp Orthop Traumatol 21(1):36-40, 2008.
Lichtenstein D: Fluid administration limited by lung sonography: the place of lung ultrasound in assessment of acute circulatory failure (the FALLS-protocol), Expert Rev Respir Med 6(2):155-162, 2012.
Nelson NC, Drost WT, Lerche P, et al: Noninvasive estimation of central venous pressure in anesthetized dogs by measurement of hepatic venous blood flow velocity and abdominal venous diameter, Vet Radiol Ultrasound 51(3):313-323, 2010.
Marik PE, Baram M, Vahid B: Does central venous pressure predict fluid responsiveness? A systematic review of the literature and the tale of seven mares, Chest 134(1):172-178, 2008.
Ferrada P, Vanguri P, Anand RJ, et al: Flat inferior vena cava: indicator of poor prognosis in trauma and acute care surgery patients, Am Surg 78(12):1396-1398, 2012.
Yanagawa Y, Nishi K, Sakamoto T, Okada Y: Early diagnosis of hypovolemic shock by sonographic measurement of inferior vena cava in trauma patients, J Trauma 58(4):825-829, 2005.
Yanagawa Y, Sakamoto T, Okada Y: Hypovolemic shock evaluated by sonographic measurement of the inferior vena cava during resuscitation in trauma patients, J Trauma 63(6):1245-1248, 2007.
Dipti A, Soucy Z, Surana A, Chandra S: Role of inferior vena cava diameter in assessment of volume status: a meta-analysis, Am J Emerg Med 30(8):1414-1419, 2012.
Cambournac M, Goy-Thollot I, Violé A, et al: Sonographic assessment of volaemia: development and validation of a new method in dogs, J Small Anim Pract 59(3):174-182, 2018.
Marshall KA, Thomovsky EJ, Brooks AC: Ultrasound measurements of the caudal vena cava before and after blood donation in 9 greyhound dogs, Can Vet J 59(9):973-980, 2018.
Herreria-Bustillo VJ, Fitzgerald E, Humm KR: Caval-aortic ratio and caudal vena cava diameter in dogs before and after blood donation, J Vet Emerg Crit Care 29(6):643-646, 2019.
Giraud L, Gommeren K, Merveille AC: Point of care ultrasound of the caudal vena cava in canine DMVD. Abstract, J Vet Intern Med 34(1):349, 2020.
Darnis E, Boysen S, Merveille AC, et al: Establishment of reference values of the caudal vena cava by fast-ultrasonography through different views in healthy dogs, J Vet Intern Med 32(4):1308-1318, 2018.
Spencer KT: Heart. In Soni NJ, Arntfield A, Kory P, editors: Point-of-care ultrasound, Philadelphia, 2015, Elsevier Saunders, pp 85-88.
Aitken JB, Freeman LA, Leicester D, et al: Questionnaire on cardiovascular point-of-care ultrasound application in first opinion emergency settings in the United Kingdom, J Vet Emerg Crit Care 29(S1):S2, 2019.
Pelchat J, Chalhoub S, Boysen S: The use of veterinary point of care ultrasound by veterinarians: a nationwide Canadian survey, Can Vet J 61(12):1278-1282, 2020.
Poelaert J: Assessment of loading conditions with cardiac ultrasound. In Malbrain ML, editor: CACU: a comprehensive book on critical and acute care ultrasound, Antwerp, Belgium, 2017, iMERiT.
Durkan SD, Rush J, Rozanski E, et al: Echocardiographic findings in dogs with hypovolemia, J Vet Emerg Crit Care 15(s1):S1-S13, 2005.
Campbell FE, Kittleson MD: The effect of hydration status on the echocardiographic measurements of normal cats, J Vet Intern Med 21(5):1008-1015, 2007.
Darnis E, Merveille AC, Desquilbet L, et al: Interobserver agreement between non-cardiologist veterinarians and a cardiologist after a 6-hour training course for echographic evaluation of basic echocardiographic parameters and caudal vena cava diameter in 15 healthy Beagles, J Vet Emerg Crit Care 29(5):495-504, 2019.
Silverstein DC, Kleiner J, Drobatz KJ: The effectiveness of intravenous fluid resuscitation for the treatment of emergency room hypotension in dogs, J Vet Emerg Crit Care 22:666-673, 2012.
Marik P, Bellomo R: A rational approach to fluid therapy in sepsis, Br J Anaesth 116(3):339-349, 2016.
Magder S: Heart-Lung interaction in spontaneous breathing subjects: the basics, Ann Transl Med 6(18):348, 2018.
Endo Y, Tamura J, Ishizuka T, et al: Stroke volume variation (SVV) and pulse pressure variation (PPV) as indicators of fluid responsiveness in sevoflurane anesthetized mechanically ventilated euvolemic dogs, J Vet Med Sci 79(8):1437-1445, 2017.
Sano H, Seo J, Wightman P, et al: Evaluation of pulse pressure variation and pleth variability index to predict fluid responsiveness in mechanically ventilated isoflurane-anesthetized dogs, J Vet Emerg Crit Care 28(4):301-309, 2018.
Endo Y, Kawase K, Miyasho T, et al: Plethysmography variability index for prediction of fluid responsiveness during graded haemorrhage and transfusion in sevoflurane-anaesthetized mechanically ventilated dogs, Vet Anaesth Analg 44(6):1303-1312, 2017.
Drozdzynska MJ, Chang YM, Stanzani G, Pelligand L: Evaluation of the dynamic predictors of fluid responsiveness in dogs receiving goal-directed fluid therapy, Vet Anaesth Analg 45(1):22-30, 2018.
Klein AV, Teixeira-Neto FJ, Garofaloet NA, et al: Changes in pulse pressure variation and plethysmographic variability index caused by hypotension-inducing hemorrhage followed by volume replacement in isoflurane-anesthetized dogs, Am J Vet Res 77(3):280-287, 2016.
Pereira RM, Campelo da Silva AJL, Faller J, et al: Comparative analysis of the collapsibility index and distensibility index of the inferior vena cava through echocardiography with pulse pressure variation that predicts fluid responsiveness in surgical patients: an observational controlled trial, J Cardiothorac Vasc Anesth 34(8):2162-2168, 2020. doi:10.1053/j.jvca.2020.02.007.
Gui J, Guo J, Nong F, et al: Impact of individual characteristics on sonographic IVC diameter and the IVC diameter/aorta diameter index, Am J Emerg Med 33:1602-1605, 2015.
Preau S, Bortolotti P, Colling D, et al: Diagnostic accuracy of the inferior vena cava collapsibility to predict fluid responsiveness in spontaneously breathing patients with sepsis and acute circulatory failure, Crit Care Med 45(3):e290-e297, 2017.
Corl KA, George NR, Romanoff J, et al: Inferior vena cava collapsibility detects fluid responsiveness among spontaneously breathing critically-ill patients, J Crit Care 41:130-137, 2017.
Huang SJ, McLean AS: Appreciating the strengths and weaknesses of transthoracic echocardiography in hemodynamic assessments, Cardiol Res Pract 2012:894308, 2012. https://doi.org/10.1155/2012/894308.
Oricco S, Rabozzi R, Meneghini C, Franci P: Usefulness of focused cardiac ultrasonography for predicting fluid responsiveness in conscious, spontaneously breathing dogs, Am J Vet Res 80(4):369-377, 2019.
Similar publications
Sorry the service is unavailable at the moment. Please try again later.
This website uses cookies to improve user experience. Read more
Save & Close
Accept all
Decline all
Show detailsHide details
Cookie declaration
About cookies
Strictly necessary
Performance
Strictly necessary cookies allow core website functionality such as user login and account management. The website cannot be used properly without strictly necessary cookies.
This cookie is used by Cookie-Script.com service to remember visitor cookie consent preferences. It is necessary for Cookie-Script.com cookie banner to work properly.
Performance cookies are used to see how visitors use the website, eg. analytics cookies. Those cookies cannot be used to directly identify a certain visitor.
Used to store the attribution information, the referrer initially used to visit the website
Cookies are small text files that are placed on your computer by websites that you visit. Websites use cookies to help users navigate efficiently and perform certain functions. Cookies that are required for the website to operate properly are allowed to be set without your permission. All other cookies need to be approved before they can be set in the browser.
You can change your consent to cookie usage at any time on our Privacy Policy page.
