[Reciprocal action between caffeine, other stimulants and drugs]. / Wechselwirkungen zwischen Coffein, anderen Genussmitteln und Arzneistoffen.

Caffeine is ingested not only with beverages as coffee, tea, coca-cola but also in form of many analgetic drugs. Therefore interactions of this substance with other biologically active substances and drugs should be expected, and the knowledge of these would be of practical importance. The interactions between caffeine and alcohol, smoking, salicylic acid, phenacetin, barbiturates, and theobromine are described.

[Coffee and health]. / Kaffee und Gesundheit.

Coffee as a rule develops stimulating effects on the central nervous system, heart and circulation which are mainly caused by caffeine. In certain cases coffee may also have a sedative effect and sometimes even it is useful to fall asleep quickly. Furthermore coffee may be advantageous in the treatment of some functional disorders caused by lacking of dopamine, because coffee is able to increase the dopamine formation in brain. Concerning the effects of coffee in the gastrointestinal-tract and liver-bile system caffeine is only of secondary importance. Hereby certain roasting substances, possibly also chlorogenic acid or caffeic acid should be responsible for the stimulating effects observed in these organs. These stimulating effects could be caused whether directly or indirect e.g. by liberating gastrin or other gastrointestinal hormones. Vitamin niacin, which is formed in greater amounts from trigonelline during the roasting process, may also be important from the nutritional standpoint. Therefore coffee may be prescribed as a true drug in cases of deficiency in vitamin niacin or also in the pellagra disease. By extensive epidemiological studies performed lately it could be demonstrated that there exists no correlation between coffee consumption and certain risk factors as hypertension, heart infarction, diabetes, gout or cancer diseases. Furthermore there was no evidence that coffee or its caffeine content are able to induce genetic alterations or even malformations.

Excretion of sulfobromophthalein in rats with iodomethane-induced depletion of hepatic glutathione.

Male urethane-anesthetized Wistar rats with biliary fistulas were infused for 60 min i.v. with sulfobromophthalein (BSP) or BSP-glutathione conjugate (BSP-GSH) at 594 nmol/100 g/min. Thirty minutes prior to the start of the infusion, 20 mg/kg iodomethane, dissolved in oliver oil, was given into the duodenum. The control received oil only. At the start of the infusion the hepatic concentration of GSH was 0.96 +/- 0.23 mg/g liver in the iodomethane-treated animals versus 1.93 +/- 0.13 mg/g liver in the control (P less than 0.001). When unconjugated BSP was infused, the excretion of total BSP (unconjugated plus conjugated) was markedly lower in the iodomethane-treated group than in the control. This difference was due solely to differences in biliary appearing conjugated BSP; the excretion of unconjugated BSP was identical in both groups. The different excretion patterns were paralleled by equal hepatic accumulation of total BSP in both groups. The ratio of unconjugated BSP/BSP-GSH in the liver was about twice as high after pretreatment with iodomethane than in the control group. When BSP-GSH instead of BSP was infused, the excretion rates of this dye were identical in both groups. The maximal transport capacity (Tm) was double that observed with infusion of unconjugated BSP in control animals. There is indirect evidence that BSP and BSP-GSH might have different excretion pathways.

[Metabolic effect of coffee and caffeine]. / Stoffwechselbeeinflussung durch Kaffee und Coffein

Coffee and its most important constituent, caffeine, may not only stimulate the function of many organs but also increase the metabolism in the body. These effects require a higher energy production which is mainly obtained from striated muscles by glycogenolysis and from fat tissue by lipolysis. Sutherland and Butcher were able to demonstrate that these degradation processes are primarily caused by an increase of cyclic 3,5-AMP. - In this connection caffeine and other methylxanthines are of special interest because these compounds also increase the intracellular amount of cyclic 3,5-AMP. This effect may be caused by an inhibition of phosphodiesterase, a release of catecholamines with resulting stimulation of adenylcyclase or by competitive inhibition of adenosine. At the present time it cannot be said which of these mechanisms primarily is involved in the in vivo effects of caffeine and other methylxanthines.

[Teratogenic and mutagenic studies with caffeine in the animal experiment]. / Teratogenetische und mutagenetische Untersuchungen mit Coffein im Tierexperiment

Principles of teratogenic and mutagenic actions are defined. The recent experimental studies with laboratory animals, and our investigations with caffeine-sodium benzoicum and with soluble coffee in pregnant rats and mice showed no teratogenicity. The results are compared with specific teratogenic effects of cytostatic agents. A teratogenicity of caffeine can be excluded, a mutagenicity in animal experiments can also not be proved.

The influence of cholic acid and dehydrocholic acid on the biliary excretion of unconjugated and conjugated sulfobromophthalein in rats.

Urethane anesthetized Wistar rats with biliary fistulas were infused during 100 min with sulfobromophthalein (BSP), the glutathione conjugate of sulfobromophthalein (BSP-GSH), cholic acid (CA) and dehydrocholic acid (DCA). The dyes (594 nmol/100 g/min) and the bile acids (1200 nmol/100 g/min) were infused separately, and in combination as well. When BSP was infused, CA and DCA increased the maximal excretion of total BSP (conjugated plus unconjugated) from 1400 to 4100 and 3300 nmol/100 g/10 min. The bile flow observed with BSP plus CA was not significantly different from that with BSP plus DCA. The biliary excretion of total BSP was higher throughout with CA than with DCA because CA increased the biliary concentration of PSP while DCA did not. The bile flow attained with CA alone was significantly lower than that with BSP plus CA. The current data provide arguments for abandoning the view that choleresis per se is the crucial determinant for BSP excretion. When BSP-GSH was infused instead of BSP, the excretion rate of the dye was not altered by the additional infusion of CA whereas it was significantly reduced by DCA. The maximal biliary concentration of BSP-GSH fell from 25.9 nmol/mul to 15.3 and 9.4 nmol/mul with CA and DCA, respectively. Both CA and DCA impaired the hepatic uptake of BSP and BSP-GSH. During the infusion with CA, BSP plus CA and BSP-GSH plus CA the biliary excretion rates of bile acids did not differ significantly from each other. This favours the view that the transfer for CA from the liver to bile is different from that for BSP and BSP-GSH. A fraction of bile fluid "independent of choleretics" (viz. of bile salts, BSP and BSP-GSH) is estimated and discussed in view of the different types of infusion.

Differences of reabsorption of unconjugated BSP and BSP-glutathione from the rat biliary tree after retrograde intrabiliary injection.

It has been shown that water and electrolytes are reabsorbed from the biliary tract of the rat. Furthermore there are some suggestions for the reabsorption of organic compounds during their passage down the biliary tract. Our results presented in this paper demonstrate a different mode of biliary excretion of unconjugated BSP [BSP-U] and BSP- glutathione [BSP-GSH] after retrograde intrabiliary injection, BSP-GSH is excreted to a much greater extent than BSP-U within the first 5 minutes after retrograde administration. In other terms BSP-GSH is reabsorbed to a lesser extent than BSP-U. Additionally the reabsorption of BSP-U and BSP-G after retrograde injection seems to be dependent on the concentration and the contact time in the biliary tree. It is suggested that the different biliary excretion of BSP-U and BSP-GSH after intravenous injection might be explained partly by a different reabsorption mode.