Relationship between the in vitro efficacy, pharmacokinetics and in vivo efficacy of curcumin.

Considerable interest continues to be focused on the development of curcumin either as an effective stand-alone therapeutic or as an adjunct therapy to established therapies. Curcumin (1, 7-bis (4-hydroxy-3-methoxyphenyl)-1, 6-heptadiene-3, 5- dione; also called diferuloylmethane) is a polyphenolic phytochemical extracted from the root of curcuma longa, commonly called turmeric. Despite evidence from in vitro (cell culture) and preclinical studies in animals, clinical studies have not provided strong evidence for a therapeutic effect of curcumin. The relevance of curcumin as a drug has been questioned based on its classification as a compound with pan assay interference and invalid metabolic panaceas properties bringing into question the relevance of the therapeutic targets identified for curcumin. To some extent this is due to the lack of a complete understanding of the link between the in vitro (cell culture activity), pharmacokinetics and in vivo activity of curcumin. In this review and using NF-κB as a cellular target for curcumin, we have investigated the relationship between the potency of curcumin as an inhibitor of NF-κB in cell culture, the pharmacokinetics of curcumin and curcumin's anticancer and anti-inflammatory effects in preclinical models of cancer and inflammation. Plausible explanations and rationale are provided to link these activities together and suggest that both curcumin and its more soluble Phase II metabolite curcumin glucuronide may play a key role in the treatment effects of curcumin in vivo mediated at NF-κB.

Ketotifen is a Prodrug. Norketotifen is the active metabolite.

Evaluation of the in vitro human liver microsome and hepatocyte metabolism of ketotifen demonstrated that norketotifen (NK) is the major demethylated hepatic metabolite of ketotifen. It is here reported that NK is completely devoid of the severe and dose-limiting sedative effects of ketotifen. Thus, while ketotifen is clinically dose-limited to 1 mg, bid, there are no dose-limiting sedative effects elicited by NK, even after the highest single-dose (16 mg) or after repeat-doses (8 mg × 7 days) in humans or after the highest doses given to dogs in repeat-dose toxicological studies (40 mg/kg × 14 days). In addition, NK-but not ketotifen-was found to express potent and dose-dependent inhibition of the release of the pro-inflammatory cytokine TNFα from activated human buffy coat preparations. Thus, when used as an anti-inflammatory drug, ketotifen is the sedating prodrug which is converted to NK a nonsedating metabolite with anti-inflammatory activity.

Characterization and Validation of a Canine Pruritic Model.

Preclinical Research The mechanisms mediating canine pruritus are poorly understood with few models due to limited methods for inducing pruritus in dogs. Chloroquine (CQ) is a widely used antimalarial drug that causes pruritus in humans and mice. We have developed a canine model of pruritus where CQ reliably induced pruritus in all dogs tested following intravenous administration. This model is presently being used to test antipruritic activity of drug candidate molecules. This publication has been validated in a blinded cross-over study in eight beagle dogs using the reference standards, oclacitinib and prednisolone, and has been used to test a new compound, norketotifen. All compounds reduced CQ-induced pruritus in the dog. The sensitivity of the model was demonstrated using norketotifen, which at three dose levels, dose-dependently, inhibited scratching events compared with placebo.

Safety and biosimilarity of ior(®) EPOCIM compared with Eprex(®) based on toxicologic, pharmacodynamic, and pharmacokinetic studies in the Sprague-Dawley rat.

This study examined the safety, pharmacodynamic (PD), and pharmacokinetic (PK) biosimilarity of the human recombinant erythropoietin (EPO) products ior(®) EPOCIM and Eprex(®) following a 28-day repeated intravenous dose administration in male and female Sprague-Dawley rats with a 14-day recovery period. Safety profiling was based on clinical observations, clinical pathology, and pathology findings for control rats dosed with vehicle and rats dosed either with 30, 300, and 600 I.U./kg of ior(®) EPOCIM or 600 I.U. of Eprex(®) . Adverse findings for both ior(®) EPOCIM and Eprex(®) were similar and were a consequence of thrombotic events (ulcerative skin lesions, swollen hock joints/lameness, stomach ulcers) and decreased body weight gains, all known adverse reactions to this class of drug in rats. With the exception of stomach ulcers, all other adverse findings were fully reversible. Neither drug stimulated the production of antidrug antibodies. As expected, ior(®) EPOCIM and Eprex(®) both increased reticulocyte, red blood cell, hemoglobin, and hematocrit levels in rats. The PK of EPO following dosing with ior(®) EPOCIM was well behaved and consistent with the literature. The results of this study imply that ior(®) EPOCIM and Eprex(®) had safety profiles, PD responses, and toxicokinetic profiles that were biosimilar.

The safety of ß-carotene from Yarrowia lipolytica.

Crystalline ß-carotene from genetically modified Yarrowia lipolytica is an alternative source of ß-carotene for use as a nutritional supplement. To support the use of ß-carotene from Y. lipolytica as a food ingredient, the genotoxic and subchronic toxicity potential of this compound was determined. Genotoxicity was examined using Salmonella typhimurium and Escherichia coli (Ames test), a chromosomal aberration assay in Chinese Hamster Ovary WBL cells, and the micronucleus test in CD-1 mice. All three assays showed no significant results due to ß-carotene from Y. lipolytica. In a subchronic toxicity study in SD rats, ß-carotene from Y. lipolytica was administered by oral gavage for 13weeks at 0, 125, 250 or 500mg/kg per day. Adverse effects were not observed following clinical, clinical pathology and gross- and histopathological evaluations of dosed rats; thus, the no-observed-adverse effect level (NOAEL) for ß-carotene from Y. lipolytica was 500mg/kg, the highest dose used in the study. In conclusion, ß-carotene derived from Y. lipolytica was shown in genotoxicity models and a standard rat subchronic rat study to have a safety profile similar to that of the current commercial products (synthetic and natural) with no unexpected finding attributable to the alternative source.

Therapeutic effect of liposomal-N-acetylcysteine against acetaminophen-induced hepatotoxicity.

BACKGROUND: Acetaminophen (APAP) is an antipyretic analgesic drug that when taken in overdose causes depletion of glutathione (GSH) and hepatotoxicity. N-acetylcysteine (NAC) is the antidote of choice for the treatment of APAP toxicity; however, due to its short-half-life repeated dosing of NAC is required. PURPOSE: To determine whether a NAC-loaded liposomal formulation (Lipo-NAC) is more effective than the conventional NAC in protecting against acute APAP-induced hepatotoxicity. METHODS: Male Sprague-Dawley rats were challenged with an intragastric dose of APAP (850 mg/kg b.wt.); 4 h later, animals were administered saline, NAC, Lipo-NAC or empty liposomes and sacrificed 24 h post-APAP treatment. RESULTS: APAP administration resulted in hepatic injury as evidenced by increases in plasma bilirubin, alanine (AST) and aspartate (ALT) aminotransferase levels and tissue levels of lipid peroxidation and myeloperoxidase as well as decreases in hepatic levels of reduced GSH, GSH peroxidase and GSH reductase. Treatment of animals with Lipo-NAC was significantly more effective than free NAC in reducing APAP-induced hepatotoxicity. Histological evaluation showed that APAP caused periacinar hepatocellular apoptosis and/or necrosis of hepatocytes around the terminal hepatic venules which was reduced by NAC treatment, the degree of reduction being greater for Lipo-NAC. CONCLUSION: These data suggest that administration of Lipo-NAC ameliorated the APAP-induced hepatotoxicity.

Safety and pharmacokinetic studies of liposomal antioxidant formulations containing N-acetylcysteine, α-tocopherol or γ-tocopherol in beagle dogs.

The safety and pharmacokinetic profile of liposomal formulations containing combinations of the antioxidants α-tocopherol, γ-tocopherol or N-acetylcysteine in beagle dogs was examined. Each group consisted of beagle dogs of both genders with a control group receiving empty dipalmitoylphosphatidylcholine (DPPC) liposomes (330 mg/kg DPPC, EL), and test groups receiving liposomes prepared from DPPC lipids with (i) N-acetylcysteine (NAC) (60 mg/kg NAC [L-NAC]); (ii) NAC and α-tocopherol (αT) (60 mg/kg NAC and 25 mg/kg α-tocopherol [L-αT-NAC]) and (iii) NAC and γ-tocopherol (60 mg/kg NAC and 25 mg/kg γ-tocopherol (γT) [L-γT-NAC]). The dogs in the control group (EL) and three test groups exhibited no signs of toxicity during the dosing period or day 15 post treatment. Weight gain, feed consumption and clinical pathology findings (hematology, coagulation, clinical chemistry, urinalysis) were unremarkable in all dogs and in all groups. Results from the pharmacokinetic study revealed that the inclusion of tocopherols in the liposomal formulation significantly increased the area under the curve (AUC) and ß-half life for NAC; the tocopherols had greater impact on the clearance of NAC, where reductions of central compartment clearance (CL) ranged from 56% to 60% and reductions of tissue clearance (CL2) ranged from 73% to 77%. In conclusion, there was no treatment-related toxicity in dogs at the maximum feasible dose level by a single bolus intravenous administration while the addition of tocopherols to the liposomal formulation prolonged the circulation of NAC in plasma largely due to a decreased clearance of NAC.

Toxicity of ricin toxin A chain in rats.

Ricin toxin A chain (RTA) is the cytotoxic component of the dimeric protein, ricin, one of the most potent and deadly plant toxins extracted from the seeds of Ricinus communis. RTA has been investigated as a potential candidate for cancer chemotherapy, in the form of immunotoxins, and as a method for depleting macrophages in vivo. The toxicity of RTA immunotoxins is mostly characterized by inflammation and necrosis and has been attributed to the RTA moiety of the conjugate. The present study was carried out to investigate the toxicity of intravenously (i.v.) administered RTA alone and to assess whether the observed tissue injuries are associated with increases in oxidative stress (OS) and inflammation. RTA (10 or 90 µg/kg body weight) was administered to animals i.v., and 5 or 24 hours later, liver, lungs, kidneys, and hearts were examined. RTA, at a dose of 90 µg/kg (i.v.), resulted in significant increases (P < 0.05) in an inflammatory response (i.e., increases in hepatic and lung myeloperoxidase activity) and increases in oxidant response (increases in lipid peroxidation and decreases in glutathione levels in hepatic and lung homogenates). These data suggest that i.v. administration of RTA resulted in organ injuries that were associated with inflammation and OS.

Infusion pharmacokinetics of Lipocurc™ (liposomal curcumin) and its metabolite tetrahydrocurcumin in Beagle dogs.

Curcumin's instability and its metabolite, tetrahydrocurcumin (THC) pose a major issue for the establishment of dependable pharmacokinetics and excretion profiles. Additional pharmacokinetic variances are associated with durations of intravenous infusions. We found that stabilizing curcumin with phosphoric acid allows accurate quantitative determinations of curcuminoids in the plasma and bile, by preventing degradation during the analytical processes. Two male and two females dogs were infused with Lipocurc™ 10 mg/kg over two hours, and another four dogs (two males and two females) were infused with Lipocurc™ 10 mg/kg over eight hours. Plasma levels of curcumin and THC were determined during the infusions and at necropsy. THC levels were 6.3-9.6-fold higher than curcumin during both infusion rates, suggesting a combination of a high-rate of enzymatic curcumin metabolism and a comparatively slower rate of blood THC clearance. When levels of curcumin and THC were compared during infusion durations, the two-hour infusion levels were significantly higher than the eight-hour infusion. The plasma half-lives of both compounds following the two-hour infusion ranged from 0.4-0.7 hours, and was a consequence of both hepatic and renal clearance However, at higher plasma concentrations renal excretion predominated, particularly with THC. Enhanced clearance rates were noted during eight-hour infusions, which prevented achieving a steady state. These observations suggest that for leukemias and lymphomas, the two-hour infusion may be advantageous based upon higher concentration profiles, and unstimulated clearance rates, however data on curcumin penetration into circulating hematopoietic cancer cells and efficacy data are required in order to confirm these suggestions.

Tissue distribution of (Lipocurc™) liposomal curcumin and tetrahydrocurcumin following two- and eight-hour infusions in Beagle dogs.

This study interrogated whether different durations of intravenous infusions of lipocurc™ would alter curcumin metabolism, tissue distribution and whether treating necropsied tissues of Beagle dogs with phosphoric acid prior to measuring curcumin and its metabolite, tetrahydrocurcumin (THC), would stabilize the compounds allowing for accurate analytic measurements. Two cohorts comprising two male and two female dogs were infused each intravenously with 10 mg/kg lipocurc™, either over two hours or over eight hours. Tissue data from each cohort was averaged from four dogs. Curcumin and THC distributed among all 13 tissues were examined at necropsy. The highest curcumin level was observed in the lungs followed by the liver. Tissue levels of curcumin in the lung, spleen and liver increased substantially following the eight-hour infusion compared to the two-hour infusion. The pancreas, kidney and urinary bladder also contained relatively high curcumin levels. Tissue partition coefficients for curcumin and THC were also higher for the eight-hour infusion than the two-hour infusion. The tissue THC/curcumin ratio varied in a tissue-specific manner and was lower for the eight-hour compared to the two-hour infusion. In conclusion, this raised the possibility that prolonged infusion of curcumin may facilitate distribution into tissues via a transporter-dependent mechanism and elevated tissue concentrations of curcumin may inhibit or saturate a putative reductase enzyme converting curcumin to THC. The addition of phosphoric acid stabilized the levels of curcumin and THC in some but not all the examined tissues, raising issues of tissue-specific curcumin and THC stability.

Acute toxicity study of liposomal antioxidant formulations containing N-acetylcysteine, α-tocopherol, and γ-tocopherol in rats.

Liposomes have been used for the delivery of antioxidants to different tissues and organs for the treatment of oxidative stress-induced injuries. In this study, the acute toxicity of a single dose of intravenously (i.v.) administered liposomal antioxidant formulation, containing N-acetylcysteine (NAC) with or without α-tocopherol (α-T) or γ-tocopherol (γ-T), in rats was examined. Each group consisted of 5 male and 5 female Sprague-Dawley rats, with a control group receiving empty dipalmitoylphosphatidylcholine (DPPC) liposomes (660 mg/kg) and test groups receiving DPPC liposomes (660 mg/kg) entrapped with 1) NAC (200 mg/kg), 2) NAC (200 mg/kg) and α-T (83.3 mg/kg), and 3) NAC (200 mg/kg) and γ-T (71.4 mg/kg). These dose levels were determined from the dose-range-finding study and were considered to be the maximum feasible dose (MFD) levels, based on the volume of 10 mL/kg and physical properties and viscosity of the test articles that could be safely administered to rats by an i.v. injection. Two weeks after treatment (day 15), rats in the control group and three test groups exhibited no clinical signs of toxicity during the dosing period or during the 14-day post-treatment period. Weight gain and food consumption in all animals was appropriate for the age and sex of animals. Clinical pathology findings (e.g., hematology, coagulation, clinical chemistry, and urinalysis) were unremarkable in all rats and in all groups. In conclusion, the results of this study showed no treatment-related toxicity in rats at the MFD level by a single bolus i.v. administration.

Safety and toxicological evaluation of a synthetic vitamin K2, menaquinone-7.

Menaquinone-7 (MK-7) is part of a family of vitamin K that are essential co-factors for the enzyme γ-glutamyl carboxylase, which is involved in the activation of γ-carboxy glutamate (Gla) proteins in the body. Gla proteins are important for normal blood coagulation and normality of bones and arteries. The objective of this study was to examine the potential toxicity of synthetic MK-7 in BomTac:NMRI mice and in Sprague-Dawley rats. In an acute oral toxicity test, mice were administered a single oral dose of 2000 mg/kg body weight (limit dose) and no toxicity was observed during the 14-day observation period. In the subchronic oral toxicity test in rats, animals were administered MK-7 for 90 days by gavage at the following doses: 0 (vehicle control, corn oil), 2.5, 5, and 10 mg/kg body weight/day. All generated data, including clinical observations, ophthalmology, clinical pathology, gross necropsy, and histopathology, revealed no compound-related toxicity in rats. Any statistically significant findings in clinical pathology parameters and/or organ weights noted were considered to be within normal biological variability. Therefore, under the conditions of this experiment, the median lethal dose (LD(50)) of MK-7 after a single oral administration in mice was determined to be greater than the limit dose level of 2000 mg/kg body weight. The no observed adverse effect level (NOAEL) of MK-7, when administered orally to rats for 90 days, was considered to be equal to 10 mg/kg body weight/day, the highest dose tested, based on lack of toxicity during the 90-day study period.

Treatment of ricin A-chain-induced hepatotoxicity with liposome-encapsulated N-acetylcysteine.

BACKGROUND: The toxicity of ricin resides in the ricin A-chain (RTA) and is attributed to the inhibition of protein synthesis but inflammation and oxidative stress have also been implicated. RTA can independently enter cells producing comparable tissue injury and inflammation, although at much higher concentrations than intact ricin. Treatment for exposure to ricin or RTA is supportive. PURPOSE: To examine the effectiveness of conventional or liposome-encapsulated N-acetylcysteine (Lipo-NAC) in ameliorating RTA-induced hepatotoxicity. METHODS: Four hours after RTA administration (90 µg/kg b.wt, iv), rats were treated with conventional NAC or Lipo-NAC (25 mg/kg NAC). The hepatoprotective effects of the antioxidant formulations were assessed by measuring indexes for liver injury (alanine [ALT] and aspartate [AST] aminotransferase activities), inflammation (myeloperoxidase, tumor necrosis factor-α, chloramine levels), and oxidant response (lipid peroxidation, nitrotyrosine, glutathione levels) 24-h post-RTA exposure. RESULTS: Administration of RTA to animals resulted in hepatotoxicity as demonstrated by elevated plasma ALT and AST levels, increases in an inflammatory response, and increases in oxidant response. Treatment of animals with the antioxidant formulations reversed the RTA-induced hepatotoxicity, being most evident following the administration of Lipo-NAC. CONCLUSION: NAC, administered in a liposomal form, may serve as a potentially effective pharmacological agent in the treatment of RTA-induced liver injuries.