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Query: UMLS:C0038187 (
starvation
)
24,951
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Respiratory muscles are essential to alveolar ventilation. These muscles work against increased mechanical loads due to airflow limitation and geometrical changes of the thorax derived from pulmonary hyperinflation. Respiratory muscle fibres show several degrees of impairment in cellular and subcellular structures which, in many cases, are proportional to the severity of the disease and accompanying conditions (ageing, deconditioning,
starvation
, comorbidity). This structural impairment translates, from the functional point of view, to a loss of strength (capacity to generate tension) and an increased susceptibility to failure in the face of a particular load (early onset of fatigue). On the other hand, there is accumulating evidence that the diaphragm and other respiratory muscles are also able to express adaptive changes in response to the chronic mechanical load imposed by the disease. In most cases, impairment and adaptation of the respiratory muscles reaches a balance that permits enough ventilation for patients' survival. However, this balance can be altered for additional increments of the mechanical or metabolic load on the muscles (e.g. abdominal or thoracic surgeries, pneumonia,
pulmonary embolism
, etc.). Moreover, loss of balance is not always associated with extreme situations. Many patients develop ventilatory failure and require hospital admission even if the cause of the exacerbation is less dramatic (bronchial infections, pain of any nature, electrolyte disturbances, etc.). Although the physiopathology of chronic obstructive pulmonary disease exacerbations is multifactorial, the above-mentioned fragility suggests the existence of a "fragile balance" between respiratory muscle overload and respiratory muscle adaptations. Assessment of respiratory muscle function through specific tests evaluating the strength and endurance could offer valuable information about this particular susceptibility to muscle imbalance. Identification of patients possessing a fragile respiratory muscle balance could have important implications for the application of specific strategies such as respiratory muscle training, nutrition, or anabolic treatment.
...
PMID:Structure and function of the respiratory muscles in patients with COPD: impairment or adaptation? 1462 Nov 6
Vinzenz Priessnitz (1799-1851) did not only carry out water treatments within the scope of his cure, but also movement therapy, aerial and solar baths, natural lifestyle and, above all, diet therapy. According to the literature Priessnitz only seldom allowed
starvation
within his cure because this would break his preferred principle of restoration. Nevertheless, the widely unknown 'Vinzenz Priessnitz family water book' which he dictated to his daughter Sophie in 1847, includes 13 orders of
starvation
for a series of indications (breast inflammations, pneumonia,
pulmonary embolism
, cholera, intestines inflammation, tapeworm) and symptoms (diarrhoea and vomiting, heart cramp, head woe, faint, stone pains, feeling of sickness). Furthermore, it comprises diet recommendations on cold water drinking, milk and cold confection of pastry, compote and buttermilk, vegetables, fruit and strawberries, fruit and frozen food, no meat, little meat and cold food. In the view of the literature, these diet principles and means as well as their applications then and now are discussed. As for those days the Priessnitz diet was quite modern, manifold, logic and 'natural'.
...
PMID:Starvation and diet according to the Vinzenz Priessnitz family water book of 1847. 1734 85
Extract: When we are wounded, either externally (for instance, when we cut ourselves) or internally (for instance, due to gastric ulcer or brain hemorrhage), blood clots -- sponge-like plugs that are rapidly formed in response to the injury by activated blood platelets and fibrin in a process called coagulation -- prevent profound bleeding. Thus, good or hemostatic clots save our lives. However, under pathological conditions blood clots can also form inside vessels. Such bad or thrombotic clots occlude blood vessels and cause oxygen
starvation
of vital organs including the brain (stroke), heart (acute myocardial infarction) or lungs (
pulmonary embolism
). Thrombosis is one of the leading causes of morbidity and mortality from cardiovascular and other disease conditions. Diverse anti-thrombotic means are being developed. For instance, anticoagulants (such as heparin) and platelet inhibitors (such as aspirin) help to prevent formation of clots (blood thinners). Fibrinolytics, known as plasminogen activators (such as tissue-type plasminogen activator, or tPA) dissolve formed clots by degrading the fibrin meshwork. Both types of therapeutics are widely used in medical practice, e.g., for treatment of two forms of ischemic heart disease caused by thrombi in coronary vessels -- acute myocardial infarction and unstable angina.
...
PMID:Coupling of anti-thrombotic agents to red blood cells offers safer and more effective management of thrombosis. 2070 55
