Acute respiratory distress syndrome.

Several combination therapies have been described throughout this article: in all likelihood, it is combination therapy that will allow improved survival of ARDS patients. As medicine moves into the future, clinical trials evaluating the efficacy of therapies for ARDS will be performed. In human critical care medicine, a large forward step was taken when ALI and ARDS were clearly defined. Unfortunately. as good as the definition is, ALI and ARDS occur secondary to many different underlying pathologic processes,perhaps obscuring the benefits of certain therapies for ARDS based on the underlying condition, for example, trauma versus sepsis. Selection of patients entering any ARDS trial is crucial: not only must those patients meet the strict definition of ARDS but the underlying disease process should be clearly identified. Identification of patients suffering from different disease processes before the onset of ARDS will allow for stratification of outcomes according to the intervention and the underlying pathology--comparing apples to apples and not to oranges. We are in a unique position in veterinary medicine. Although frequently financially limited by our clients, we have the opportunity to achieve several goals. First, we need to clearly define what constitutes ALI and ARDS in veterinary medicine. Do we want to rely on the human definitions? Probably not; however, as a group, we need to determine what we will accept as definitions. For example, we may not be able perform right heart catheterizations on all our patients to meet the wedge pressure requirement of human beings of less than 18 mm Hg. Do we agree that a PAOP of less than 18 mmHg is appropriate for animals, and is it appropriate for all animals? Will we accept another measure, for example, pulmonary artery diameter increases with echocardiographic evidence of acceptable left heart function? What is acceptable left heart function? As veterinarians, what do we consider to be hypoxemia? Is it the same in all species that we work with? What do we define as acute onset? Most human ARDS cases occur while patients are in hospital being treated for other problems, whereas many of our patients present already in respiratory distress. If we are unable to ventilate patients for economic or practical reasons, what do we use as the equivalent of the Pao2/Flo, ratio'? Reliance on the pathologist is not reasonable, because many disease processes can look similar to ARDS under the microscope. If anything, ALI and ARDS are clinical diagnoses. It is time for veterinarians to reach a consensus on the definition for ALI and ARDS in our patients.Only when we have a consensus of definition can rational prospective clinical trials of therapies be designed.     

Acute respiratory distress syndrome (ARDS) in lambs. Hematology

Lambs suffering from Acute Respiratory Distress Syndrome (ARDS) showed elevated PCV, neutrophilia, a tendency towards lymphopenia, eosinopenia, hyperphosphatemia, hypoglycemia and extremely low serum Ca values during the first couple of days after the outbreak of symptoms. During the very early phase, plasma potassium values were mostly lowered (Figs. 1-3, Table I). The possible involvement of histamine is shortly discussed: either 1) through an atopic reaction, 2) because of acute ruminal acidosis and sudden histamine formation, or 3) involvement of endotoxins.     

Acute respiratory distress syndrome in an alpaca cria

A 7-hour-old alpaca was presented for lethargy and depression. The cria responded favorably to initial treatment but developed acute-onset dyspnea 48 hours later. Acute respiratory distress syndrome was diagnosed by thoracic imaging and blood gas analysis. The cria was successfully treated with corticosteroids and discharged from the hospital.     

Acute respiratory distress syndrome in a 10-year-old dog

A 10-year-old shih tzu was presented with lethargy, anorexia, coughing, and dyspnea of 2 days' duration. Despite treatment with parenteral fluids, corticosteroids, antibiotics, and diuretics, the dog died. Acute respiratory distress syndrome was diagnosed histologically.     

Acute respiratory distress syndrome (ARDS) in lambs. Clinical and pathoanatomical investigations

In the South-Western part of Norway, lambs of the Old Norwegian short tailed breed (Spael) and crosses with the Dala breed sometimes develop an Acute Respiratory Distress Syndrome (ARDS) shortly after they have been moved onto lush aftermath grazings from mountain pastures. This article covers the symptoms and pathoanatomical findings in lambs affected with ARDS (Table I). The lambs acquired ARDS 18-72 hours after change of pasture. Heavy dysphne, frothing at the mouth, elevated temperature (greater than 41 degrees C), tachycardia, urination and ruminal atony were striking symptoms (Table II). In the early phase of the disease the lambs were often in a tranquil state, depressed, sometimes atactic, and it seemed that they went into the overt dysphneic phase on exposure to physical stress. Morbidity was 1.4%, mortality 36%. Post mortem findings included frothy contents in the airways, heavy congestion and oedema in the lungs which also had emphysematous areas, subepicardial petechiae, varying degree of mottling of the myocardium, and also varying degree of paleness and spottyness of renal cortices. The lungs showed extensive focal alveolar and interstitial emphysema, septal congestion, alveolar oedema, partial collapse, and accumulations of polymorphonuclear leucocytes in vascular beds. Later, fibrillar material was found in the alveoli, alveolar macrophages accumulated, and interalveolar septa thickened because of increased fibromuscular tissue and mononuclear cells (Fig. 1, A-D). Alveolar epithelial hyperplasia was not seen in any stage. Four lambs were moderately infected with lungworms (D. filaria), three in the prepatent, one in the patent phase. Histopathological changes in other organs included granular degenerations of myocardial threads, and development of a glomerulonephritis and focal interstitial nephritis (Fig. 1, E-F). This disease entity (ARDS) in lambs seems to be unknown in literature. The disease is compared with other known diseases in ruminants. Etiology is so far unknown. Possibilities of sudden ruminal histamine formation coinciding with a hypersensitivity reaction is discussed.     

Acute lung injury/acute respiratory distress syndrome in 15 foals

REASONS FOR PERFORMING STUDY: Few reports exist in the veterinary medical literature describing clinical and pathological findings resembling conditions described as (ALI) and acute respiratory distress syndrome (ARDS) in man. OBJECTIVES: To document history, clinical, laboratory and diagnostic findings, treatment and outcome of foals age 1-12 months diagnosed with ALI/ARDS at a referral hospital. METHODS: Medical records, including radiographic, cytological, microbiological, serological and post mortem findings, were reviewed in a retrospective manner to identify foals with acute onset of respiratory distress, a partial pressure of arterial oxygen (PaO2) to fraction of oxygen in inspired gases (FiO2) ratio of < or = 300 mmHg, pulmonary infiltrates on thoracic radiographs or post mortem findings consistent with ALI/ARDS. RESULTS: Fifteen foals age 1.5-8 months were included in the study. Seven foals had previously been treated for respiratory disease, and all foals developed acute respiratory distress <48 h prior to presentation. Findings on presentation included tachycardia and tachypnoea in all foals, with fever recorded in 8 cases. Eight cases met the criteria for ALI and 7 for ARDS. Radiographic findings demonstrated diffuse bronchointerstitial pattern with focal to coalescing alveolar radiopacities. An aetiological agent was identified in foals ante mortem (n = 6) and post mortem (n = 4). All foals were treated with intranasal oxygen and antimicrobial drugs; 13 received corticosteroids. Nine patients survived, 4 died due to respiratory failure and 2 were subjected to euthanasia in a moribund state. Follow-up was available for 7 foals; all performed as well as age mates or siblings, and one was racing successfully. CONCLUSIONS: A condition closely meeting the human criteria for ALI/ARDS exists in foals age 1-12 months and may be identical to previously described acute bronchointerstitial pneumonia in young horses. POTENTIAL RELEVANCE: ALI/ARDS should be suspected in foals with acute severe respiratory distress and hypoxaemia that is minimally responsive to intranasal oxygen therapy. Treatment with systemic corticosteroids, intranasal oxygen and antimicrobials may be beneficial in foals with clinical signs compatible with ALI/ARDS.     

Acute phase proteins in naturally occurring respiratory disease of feedlot cattle

The aim of this study was to evaluate three acute phase proteins (APP) [haptoglobin (HPT), lipopolysaccharide binding protein (LBP) and transferrin (Tf)] in feedlot cattle with naturally occurring respiratory disease diagnosed by a calf health scoring chart (CHSC). Seventy-seven beef calves were observed for signs of Bovine Respiratory Disease (BRD) during the first 28 days after arrival at the feedlot. Fourteen cases and pen matched controls were selected based on the CHSC. BRD cases were defined as a score of ≥5, while controls were defined as a score ≤4. The mean CHSC score in cases was 6.9 which was significantly greater than the controls 2.8 (P < 0.01). Mean plasma LBP and HPT concentrations were significantly greater in cases than controls (P < 0.01). Our study results show that measurement of HPT and LBP could be useful in detecting respiratory disease in feedlot conditions. Transferrin concentrations between the two groups were not statistically different.     

Dissecting aneurysm of the carotid artery as a cause of respiratory distress in adult cattle

A two-and-a-half-year-old Friesian cow and a five-year-old Charolais cow developed severe respiratory distress and palpable swellings to the left of the larynx as a result of a dissecting aneurysm of the common carotid artery. Neither cow responded to medical treatment. The underlying pathogenesis of the condition was uncertain, but direct trauma to the carotid artery was a possible contributory factor. Aneurysms of the common carotid artery should be considered when swelling occurs in the region of the larynx or when respiratory distress is due to laryngeal compression.     

Recent advances in respiratory conditions in cattle.

The study of cattle respiratory diseases during the last decade show that several observations made in the late 1960s are still relevant today. Many of these diseases are shared with other countries in Europe, but the developments discussed will be examined with the respiratory disease problems that occur in Britain in mind. The new information is dealth with as it applies to (i) structure, function and immunology of the lungs (ii) diseases of calves indoors (iii) diseases of young animals grazing, (iv) diseases of adult animals indoors and (v) diseases of adult animals grazing.     

Approach to the patient with respiratory distress.

Respiratory emergencies are common presentations to emergency clinicians. Appropriate assessment and timely interventions may be crucial in the stabilization of dyspneic patients. The emergency clinician should be fully prepared and equipped to correctly ascertain and treat the most likely cause of respiratory compromise of a patient. Based on history, signalment, clinical presentation, and brief physical examination findings, the clinician should be able to formulate a plan of action to relieve respiratory distress and communicate with the owner about the diagnostic and therapeutic strategies and overall prognosis of the patient. Prompt recognition of the underlying respiratory disease and complete familiarity with emergency diagnostic and therapeutic procedures can lead to the successful management of many emergency respiratory patients.     

Acute respiratory distress syndrome in dogs and cats: a review of clinical findings and pathophysiology

Objective: To review the clinical and pathophysiologic aspects of acute respiratory distress syndrome (ARDS) in dogs and cats. Data sources: Data from human and veterinary literature were reviewed through Medline and CAB as well as manual search of references listed in articles pertaining to acute lung injury (ALI)/ARDS. Human data synthesis: Since the term ARDS was first coined in 1967, there has been a abundance of literature pertaining to this devastating syndrome in human medicine. More complete understanding of the complex interactions between inflammatory cells, soluble mediators (e.g., tumor necrosis factor, interleukin (IL)‐6, IL‐8, platelet activating factor) and the clinical patient has provided for timely recognition and mechanistically based protective strategies decreasing morbidity and mortality in human patients with ARDS. Veterinary data synthesis: Although little is known, ARDS is becoming a more commonly recognized sequela in small animals. Initial case reports and retrospective studies have provided basic clinical characterization of ARDS in dogs and cats. Additionally, information from experimental models has expanded our understanding of the inflammatory mechanisms involved. It appears that the inflammatory processes and pathologic changes associated with ARDS are similar in dogs, cats, and humans. Conclusions: Unfortunately, current mortality rates for ARDS in small animals are close to 100%. As our capability to treat patients with advanced life‐threatening disease increases, it is vital that we develop a familiarity with the pathogenesis of ARDS. Understanding the complex inflammatory interactions is essential for determining effective preventative and management strategies as well as designing novel therapies for veterinary patients.     

Acute anaplasmosis in imported cattle

Of 18 Hereford cattle imported into Quebec from the eastern U.S.A., five exhibited acute hemolytic anemia, icterus, depression, fever, anorexia and died; 11 were killed because they had positive or suspicious anaplasma titers and two were quarantined. Anaplasma marginale organisms were found in the erythrocytes of the sick animals by light and electron microscopy. The partial absence of erythrocytic plasmalemma on several electron photomicrographs suggested exit of the anaplasma bodies. Titers up to 1:320 in infected animals were found by the complement fixation test.