Mirtazepine: heir apparent to amitriptyline?

"What's new in therapeutics?" will examine and evaluate drugs that may have a place in hospice, palliative, and long-term care. Mirtazepine will be examined and evaluated. Mirtazepine is a potential alternative anti-depressant with multiple additional benefits. It is an atypical anti-depressant, which has both noradrenergic and specific serotonergic receptor antagonism (NaSSa), and a unique pharmacological profile. Mirtazepine appears to be a "designer drug" for palliative medicine with a number of benefits, but cost may be a drawback.

Suppression of systemic, intramuscular, and subcutaneous adipose tissue lipolysis by insulin in humans.

In addition to sc and visceral fat deposits, muscle has been shown to contain relevant amounts of lipids whose breakdown is subject to hormonal regulation. The aim of the present study was to determine insulin dose-response characteristics of systemic, sc adipose tissue and muscle lipolysis in humans. We used a combination of isotopic (primed continuous infusion of [d5]glycerol) and microdialysis techniques (catheters placed in the anterior tibial muscle and sc abdominal adipose tissue) during a three-step hyperinsulinemic-euglycemic clamp (insulin infusion, 0.1, 0.25, 1.0 mU/kg x min) in 13 lean, healthy volunteers. The glycerol rate of appearance was used as the index for systemic lipolysis; interstitial glycerol concentrations were used as the index for muscle and sc adipose tissue lipolysis. The insulin concentrations resulting in a half-maximal suppression (EC50) of systemic lipolysis, adipose tissue, and muscle lipolysis were 51, 68, and 44 pmol/L, respectively (between one another, P < 0.001). For each compartment there were significant correlations between the EC50 and the insulin sensitivity index for glucose disposal (r > 0.67; P < 0.05). However, lipolysis (as percent of baseline) was similar during the first two insulin infusion steps, but was significantly lower in adipose (22+/-2%) than in muscle (53+/-4%; P < 0.001) during step 3. Although we have no direct measurement of interstitial insulin concentrations, we conclude that based on the EC50 values, muscle is more sensitive with respect to the net effect of circulating insulin (transendothelial transport plus intracellular action) on lipolysis than sc adipose tissue in terms of exerting its full suppression within the physiological insulin range. This could be important in muscle for switching from preferential utilization of free fatty acids to glucose in the postprandial state. Inadequate suppression of im lipolysis resulting in excessive local availability of free fatty acids may represent a novel mechanism contributing to the pathogenesis of impaired glucose disposal, i.e. insulin resistance, in muscle.

Lipolysis in skeletal muscle is rapidly regulated by low physiological doses of insulin.

AIMS/HYPOTHESIS: Both patients with Type II (non-insulin-dependent) diabetes mellitus and normoglycaemic, insulin resistant subjects were shown to have an increased lipid content in skeletal muscle, which correlates negatively with insulin sensitivity. Recently, it was shown that during a hyperinsulinaemic euglycaemic clamp interstitial glycerol was reduced not only in adipose tissue but also in skeletal muscle. To assess whether lipolysis of muscular lipids is also regulated by low physiological concentrations of insulin, we used the microdialysis technique in combination with a 3-step hyperinsulinaemic glucose clamp. METHODS: Nineteen lean, healthy subjects (12 m/7 f) underwent a glucose clamp with various doses of insulin (GC I = 0.1, GC II = 0.25 and GC III = 1.0 mU x kg(-1) x min(-1)). Two double lumen microdialysis catheters each were inserted in the paraumbilical subcutaneous adipose tissue and in skeletal muscle (tibialis anterior) to measure interstitial glycerol concentration (index of lipolysis) and ethanol outflow (index of tissue flow). RESULTS: During the different steps of the glucose clamp, glycerol in adipose tissue was reduced to 81 +/- 7 % (GC I), 55 +/- 8 % (GC II) and 25 +/- 5 % (GC III), respectively, of basal. In contrast, glycerol in skeletal muscle declined to 73 +/- 5 % (GC I) and to 57 +/- 6 % (GC II) but was not further reduced at GC III. Tissue flow was higher in the skeletal muscle and remained unchanged in both compartments throughout the experiment. CONCLUSION/INTERPRETATION: This study confirms the presence of glycerol release in skeletal muscle. Lipolysis in skeletal muscle and adipose tissue are suppressed similarly by minute and physiological increases in insulin but differently by supraphysiological increases. Inadequate suppression of intramuscular lipolysis resulting in increased availability of non-esterified fatty acids, could represent a potential mechanism involved in the pathogenesis of impaired glucose disposal, i. e. insulin resistance, in muscle. [Diabetologia (1999) 42: 1171-1174]

Appetite stimulants in terminal care: treatment of anorexia.

Anorexia is a common problem in terminally ill patients. The loss of appetite brings with it physical, psychological, and social problems. Effective treatment, therefore, should be multidimensional. The pharmacist is well-positioned to evaluate the appropriate use of medications for their effects on appetite, weight gain, mood, nausea, and anorexia. Studies have demonstrated that megestrol acetate has the most positive results in patients with advanced cancer and human immunodeficiency virus. Other medications studied have a less significant impact. Total parenteral nutrition can also sustain meaningful life for many terminally ill patients, but it is rarely successful in alleviating the anorexia associated with terminal illness.