Postprandial hyperlipidaemia is a common metabolic disturbance in atherosclerosis. During the postprandial phase, chylomicrons and their remnants can penetrate the intact endothelium and cause foam cell formation. These particles are highly atherogenic after modification. People in the Western world are non-fasting for most of the day, which consequently leads to a continuous challenge of the endothelium by atherogenic lipoproteins and their remnants. Furthermore, atherosclerosis is considered a low-grade chronic inflammatory disease. Many studies have shown that the process of atherogenesis in part starts with the interaction between the activated leucocytes and activated endothelium. Postprandial lipoproteins can activate leucocytes in the blood and up-regulate the expression of leucocyte adhesion molecules on the endothelium, facilitating adhesion and migration of inflammatory cells into the subendothelial space. Another inflammatory process associated with postprandial lipaemia is the activation of the complement system. Its central component C3 has been associated with obesity, coronary sclerosis, the metabolic syndrome and fasting and postprandial TAGs (triacylglycerols). Moreover, chylomicrons are the strongest stimulators of adipocyte C3 production via activation of the alternative complement cascade. A postprandial C3 increment has been shown in healthy subjects and in patients with CAD (coronary artery disease) and with FCHL (familial combined hyperlipidaemia). Postprandial lipaemia has been related to TAG and free fatty acid metabolism. All of these mechanisms provide an alternative explanation for the atherogenicity of the postprandial period.
Interleukin 6 plays a key role in the pathogenesis of multiple myeloma (MM). Therefore we conducted a phase I dose-escalating study with chimaeric monoclonal anti-IL6 antibodies (cMab) in MM patients resistant to second-line chemotherapy. The cMab (CLB IL6/8; Kd 6.25 x 10(-12)M) was given in two cycles of 14 daily infusions, starting on day 1 and day 28, repectively, with a daily dose of 5 mg in patients 1-3, 10 mg in patients 4-6, 20 mg in patients 7-9 and 40mg in patients 10-12 (total dose 140 mg, 280mg, 560 mg and 1120 mg of anti-IL6, respectively). 11/12 patients had elevated pretreatment IL6 levels. Except for transient thrombocytopenia in two patients there was no toxicity. There were no changes in haemoglobin levels, granulocyte count, liver enzymes or renal function. No human anti-chimaeric antibodies were induced. This was also reflected in a long half-life time of the cMab (median 17.8 d), resulting in accumulation of the anti-IL6 cMab and high levels of circulating IL6. However, this was in the form of biologically inactive IL6/cMab complexes and did not result in acceleration of the disease. Although C-reactive protein (CRP) levels were decreased to below detection level in 11/12 patients, indicating effective IL6 blocking, none of the patients achieved a response according to the standard criteria. We conclude that this chimaeric anti-IL6 Mab has a low toxicity, low immunogenicity and a long T1/2. A dose of 40 mg/d for 14 d can safely be used in future phase II studies.
Background. Glutamine‐supplemented total parenteral nutrition (TPN) improved the nitrogen balance in catabolic situations. In animal studies, parenteral glutamine supplementation appeared to maintain gut integrity. This study was performed to evaluate the possible positive effects of glutamine supplementation in catabolic hematologic patients. Methods. This was a prospective double‐blind placebo‐controlled pilot study, in which 20 treatment cycles in unselected hematologic patients with intensive chemotherapy were studied. Glutamine was given as a dipeptide. Patients were randomized per treatment cycle to receive isonitrogenous TPN (0.272 g nitrogen/kg of body weight) and isoenergetic TPN (2200 kcal NPE/day) without or with 40 g L‐alanyl‐L‐glutamine (26 g glutamine) until the neutrophil count was greater than 0.5 × 109/L. The daily oral food intake was recorded and analyzed carefully. Toxicity grades for performance status, mucositis, and diarrhea were scored according to the World Health Organization classification. Results. No differences in neutropenic period, fever, extra antibiotics, and toxicity scores were observed, except for a gain in body weight per treatment cycle in favor of the glutamine‐supplemented TPN. No side effects or allergic reactions were noted after the dipeptide administration. Conclusion. Supplementation of glutamine dipeptide was safe but had no significant positive clinical effect.
In vitro as well as in vivo observations have shown that IL6 plays a key role in the pathogenesis of multiple myeloma. Therefore we started a phase I/II dose escalating study with chimeric monoclonal anti-IL6 antibodies (cMab) in multiple myeloma (MM) patients resistant to second-line chemotherapy. Here we describe the pharmacological data as well as a new method for calculating the endogenous IL6 production. During treatment with anti-IL6 cMabs, the endogenous IL6 production immediately decreased in all patients to below 3 g/d and never reached the pre-treatment value during the treatment period, except in two patients who developed an active infection, resulting in an IL6 production of 128 and 1,208 g/d, respectively. We concluded that in MM patients endogenous IL6 production is 2-30 times higher than in healthy individuals. The anti-IL6 cMab strongly suppress this endogenous IL6 production, probably by blocking a positive feed-back loop, but this cMab does not prevent infection-induced IL6 production. The chimeric anti-IL6 Mabs have a long half-life time, a low immunogenicity, and are able to block IL6-dependent processes in
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