Browsing by Subject "Curcumin"
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Publication Antioxidants Attenuate Heat Shock Induced Premature Senescence of Bovine Mesenchymal Stem Cells(2022) Nir, Dana; Ribarski-Chorev, Ivana; Shimoni, Chen; Strauss, Carmit; Frank, Jan; Schlesinger, SharonMesenchymal stem cells (MSC) have many roles that are important for the body’s proper functioning. When the MSC pool is damaged, it is often correlated with impaired development or health of the organism. MSC are known for their anti-inflammatory, immunomodulatory and trophic characteristics that play an important role in the physiological homeostasis of many tissues. Heat shock impairs MSC capacity by inducing the generation of reactive oxygen species and mitochondrial dysfunction, which, in turn, send the cells into a state of premature senescence. Here, we pre-exposed MSC to melatonin, resveratrol, or curcumin, which are natural antioxidative compounds, and tested the protective effects of these substances from oxidative stress and aging. Our data showed that pre-exposure of MSC to antioxidants decreased reactive oxygen species while mitochondrial damage remained high. Additionally, although the proliferation of the cells was slow, antioxidants protected the cells from premature senescence, and subsequent cytokine release was prevented. We conclude that while elevated temperatures directly cause mitochondrial damage, senescence is induced by elevated ROS levels. We suggest that heat shock alters cell and tissue homeostasis by several independent mechanisms; however, reducing tissue senescence will reduce damage and provide a pathway to overcome physiological challenges in animals.Publication Relative bioavailability of curcumin as affected by formulation strategies : from in vitro digestion and cell culture experiments to human clinical trials(2022) Flory, Sandra; Frank, JanCurcumin, the bioactive component of turmeric (Curcuma longa L.), has been used for thousands of years in traditional medicine for the prevention or treatment of several diseases and symptoms. Nowadays, curcumin is investigated worldwide as a nutritional supplement. To overcome the central limitation of its naturally low oral bioavailability, several formulation strategies have been developed, such as its co-administration with turmeric oils or piperine to inhibit its metabolism and efflux or its incorporation into micelles, cyclodextrin complexes or phospholipid bilayers to improve its stability and solubility. So far, the different formulations have not been compared directly, in one cohort of participants and at equal doses. The present doctoral thesis aimed, for the first time, at a direct comparison of the bioavailability of curcumin in form of a native curcuma extract or seven formulations, namely polysorbate 80 micelles, g-cyclodextrin complexes, liposomes, phytosomes, submicron-particle curcumin or curcumin administered with turmeric oils or piperine, in healthy adults. The project further aimed to investigate several critical factors for curcumin bioavailability in vitro and to explain thereby the observations made in vivo. In a randomized, double-blind crossover trial with 12 healthy participants (6 females, 6 males), curcumin pharmacokinetics, namely AUC (area under the plasma concentration-time curve), Cmax (maximum plasma concentration) and tmax (time to reach Cmax) were compared after administration of a single oral dose of 207 mg curcumin in form of a native curcuma extract or one of the seven formulations. Curcumin incorporated into polysorbate 80 micelles or g-cyclodextrin complexes showed 57-fold and 30-fold improved bioavailability compared to the native extract, whereas all other formulations showed no or minor effects. tmax of the better bioavailable formulations was smaller (1 to 2 hours) compared to all others (up to 7 hours). To compare the formulations regarding their digestion characteristics and transepithelial transport, in vitro digestion experiments followed by Caco-2 cell transport assays were conducted with the formulations normalized to their curcumin content. In parallel to the effects in vivo, curcumin showed higher stability, solubility and micellization efficiency when it was incorporated into polysorbate 80 micelles (100%, 80%, 55%) or g-cyclodextrin complexes (73%, 33%, 23%), whereas curcumin permeability through Caco-2 cell monolayers was not affected by its formulation. In the next study, curcumin efflux, partially mediated by P-glycoprotein (P-gp), was investigated, because the inhibition of curcumin efflux from the intestinal cells back to the intestinal lumen is targeted by the co-administration of curcumin with turmeric oils or piperine. In LS180 (colon adenocarcinoma) cells, native curcuma extract and the seven formulations were studied regarding cellular curcumin uptake within 1 hour and efflux within further 8 hours, as well as their effects on P-gp activity. Independently from its formulation, curcumin inhibited the activity of P-gp. Cellular curcumin uptake and efflux showed significant variability between formulations but no consistent effects. Cellular uptake and efflux may thus not be important for curcumin bioavailability in vivo. Another potential factor influencing bioavailability, that was investigated for native and micellar curcumin, was the time-dependent intracellular distribution in intestinal cells. Uptake and intracellular distribution in Caco-2 cells mainly did not differ between native and micellar curcumin. After 30 minutes, both were localized in lysosomes and mitochondria, after 180 minutes in peroxisomes and native curcumin also in mitochondria. The temporary localization in lysosomes is in line with the involvement of endocytosis in cellular uptake of curcumin. Nevertheless, the intracellular localization of curcumin was not affected by its incorporation into polysorbate 80 micelles. The data generated in this doctoral project thus demonstrate that the incorporation of curcumin into polysorbate 80 micelles or g-cyclodextrin complexes successfully improve its bioavailability. The improved bioavailability of both formulations can be explained by enhanced digestive stability, solubility and micellization efficiency and appears to be independent from post-digestive processes, such as intestinal permeability, cellular uptake, cellular efflux or intracellular distribution. Consequently, the present doctoral thesis delivers relevant information for the therapeutical application of curcumin, for the development of highly bioavailable formulations, as well as the basis for further clinical research on the health beneficial effects of curcumin.Publication Uptake and time‐dependent subcellular localization of native and micellar curcumin in intestinal cells(2022) Flory, Sandra; Benz, Ann‐Kathrin; Frank, JanUptake into intestinal cells and intracellular distribution into metabolically competent organelles, such as the endoplasmic reticulum, are important processes potentially limiting the bioavailability of xenobiotics. The incorporation of curcumin into polysorbate 80 micelles improves its naturally low oral bioavailability in humans. Here, we investigated uptake and time‐dependent localization of curcumin in intestinal cells when administered as native or micellar formulation. Differentiated Caco‐2 cells were incubated with 200 μmol/L native or micellar curcumin for up to 180 min and cellular uptake was quantified. Intracellular curcumin was detected already after 30 min and did not differ significantly between formulations or over time. Subcellular localization of native and micellar curcumin in Caco‐2 cells was studied by density gradient centrifugation. After 30 min, curcumin from both formulations was mainly associated with mitochondria and lysosomes, after 180 min native curcumin was associated with mitochondria and peroxisomes, micellar curcumin with peroxisomes only. Uptake and localization of native and micellar curcumin in intestinal cells do not differ significantly and consequently do not explain differences in bioavailability in humans. The temporary co‐localization with lysosomes is in agreement with the previously proposed role of endocytosis in cellular uptake of curcumin and warrants further investigation.