Preparations of the plant Curcuma longa Linn have been used to treat various ailments for centuries in Ayurvedic medicine, a traditional Indian system of healing(1). This plant, also known as turmeric, is a member of the Zingiberaceae, or ginger family. Within Ayurveda, turmeric preparations are taken orally to treat dyspepsia, flatulence, liver disease, urinary tract disease and as a “blood purifier.” It is also used externally for pemphigus and other skin diseases, and may be inhaled for the treatment of coryza. Components of turmeric are currently undergoing scientific evaluation for their utility as anti-inflammatory agents(2), value in preventing and treating cancer (3, 4), for the treatment of human immunodeficiency virus (HIV) infection(2) and most recently for the treatment of cystic fibrosis(5). In addition to its medicinal applications, turmeric is used as a dye and food additive. Originally valued because of its ability to maintain the freshness of food, it is a spice commonly used in curry which is currently its most important commercial application.

Curcuma longa Linn is indigenous to South and Southeast Asia where it is grown for commercial use. Turmeric is derived from the rhizome, or root of the plant. Curcumin was isolated in 1815 and the chemical structure was subsequently identified to be diferuloylmethane (Fig. 1). Along with the other curcuminoids (demethoxycurcumin, bisdemethoxycurcumin, and cyclocurcumin), it composes a yellow pigment that is poorly soluble in water and comprises 3–5% of turmeric extract(1). Curcumin has a structure similar to Congo Red (Fig. 1) and, like Congo Red, it binds to and stains amyloid plaques in vivo (unpublished observations). It has been demonstrated in various experimental preparations to have anti-oxidant, anti-inflammatory, and cholesterol-lowering properties (see below), all three of which are felt to be key processes involved in the pathogenesis of Alzheimer’s disease (AD). Epidemiological studies in India, a country where turmeric consumption is widespread, suggest it has one of the lowest prevalence rates of AD in the world(6, 7). Though there are many potential explanations for this observation, a preventative role of curcumin is a possibility. In this paper we summarize the evidence supporting the evaluation of a role for curcumin in the prevention and treatment of human AD.

Fig. (1). Chemical structures of Curcumin and Congo Red.

Using a rat liver microsome preparation, Reddy and Lokesh(13) demonstrated that curcumin inhibited lipid peroxidation and Sreejayan and Rao(14) replicated this in a distinct in-vitro model, demonstrating that curcumin, demethoxycurcumin, and desmethoxycurcumin were more potent antioxidants than alpha-tocopherol. Shih and Lin(15) showed that curcumin prevented oxidative damage of DNA in mouse fibroblasts. Kim et al (16) showed that the curcuminoids were more potent antioxidants than alpha-tocopherol using a 2,2-diphenyl-1-picrylhydrazyl (DPPH) radical trapping assay in which the ability of the compounds to reduce a radical cation is assessed. Multiple experiments therefore provide evidence that curcumin has substantial antioxidant properties.

Investigators have demonstrated that curcumin inhibits lipoxygenase and cyclooxygenase 2, enzymes that are responsible for the synthesis of the pro-inflammatory leukotrienes, prostaglandins, and thromboxanes(21). It also inhibits AP-1 mediated transcription related to cytokine regulation in vitro(22) and suppresses inducible nitric oxide synthase (iNOS) in activated macrophages(23), processes that promote inflammation. As lipid peroxides also promote inflammation, curcumin’s antioxidant effects also serve to decrease inflammation.

As aggregation of Aβ into fibrils and the subsequent formation of amyloid plaques are posited by many to be important steps in the pathogenesis of AD, these processes are potential targets for therapy. Ono et al(28) performed an in-vitro study in which they measured the effects of curcumin on formation of Aβ fibrils from Aβ_1–40 and Aβ_1–42 peptides. They found that curcumin inhibited the formation and extension of Aβ fibrils and destabilized preformed Aβ fibrils in a dose-dependent fashion at a range between 0.1 and 1 micro-molar concentration. We have independently confirmed this finding (in press). Additional experiments suggested that curcumin’s effect did not depend on specipic epitopes of Aβ but rather the compound bound to fibrillar Aβ regardless of the specific Aβ sequences of which it was composed.

We have also demonstrated that the in-vitro prevention of Aβ fibril formation by curcumin is visualizable by electron microscopy. Furthermore, curcumin inhibits the formation of antibody-detectable Aβ oligomers(29), which are felt to be intermediates in Aβ aggregation (in press).

Thus curcumin appears to have primary effects on Aβ aggregation in addition to its antioxidant, anti-inflammatory, and platelet aggregation inhibiting properties.

In some studies curcumin has had ulcerogenic properties, causing gastric ulcerations in rats at doses of 100 mg/kg(32). Furthermore, in a study of rats treated with 50,000 ppm dietary turmeric oleoresin there was an increased incidence of ulcers, inflammation, and hyperplasia of the forestomach, cecum, and colon(3). In other investigations, however, curcumin had antiulcerogenic properties, causing decreased gastric secretion in rats(33) and it has been traditionally used to treat dyspepsia. It is likely that differences in the dose and preparation of the agent account for these disparate observations.

In one study, female mice receiving 50,000 ppm turmeric oleoresin had a significantly increased incidence of thyroid gland follicular cell hyperplasia(34). Animals studies of carcinogenicity, genotoxicity, and teratogenicity have been equivocal or negative(3).

Animal studies therefore indicate that curcumin at high doses is safe though vigilance is suggested for potential hepatic, gastric, and thyroid toxicity.

The bioavailability of curcumin may be limited by intestinal and hepatic glucuronidation. Piperine, an inhibitor of glucuronidation, could be administered concomitantly with curcumin to increase bioavailability. Shoba et al demonstrated the feasibility of this approach in both rats and humans(38). When 20 mg of piperine was administered orally with 2 gm of curcumin to volunteers, serum levels were significantly enhanced at 1 hour’s time, increasing total bioavailability by 20-fold. No toxicity was observed in the 10 subjects who participated in this study.

In short-term studies doses of up to 1,200 mg/day were demonstrated to be well-tolerated in patients with rheumatoid arthritis(41), post-surgical patients(42) and ophthalmology patients(43). In a study of 19 patients with acquired immune deficiency syndrome (AIDS) two patients, one of whom had a history of peptic ulcer disease, developed gastric irritation(44).

In a study of patients with colon cancer treated for 4 months(35), 1 patient on 1,320 mg developed nausea in the first month that resolved despite continued administration of the drug and two patients developed diarrhea (one on 880 mg and one on 2,200 mg/day) and dropped out of the study. In the study of patients with pre-cancerous lesions treated for 3 months, doses of up to 8000 mg/day were tolerated well though higher doses were difficult to tolerate due to their bulky volume(36). In summary, high doses of curcumin appear to be well-tolerated with few adverse effects other than gastric irritation or nausea. To date, however, we are not aware of longer-term safety and tolerability studies in humans nor of studies specifically done in an elderly population as would be encountered in a study of AD.

In light of the antioxidant, anti-inflammatory, and anti-amyloid effects discussed above, curcumin has become a candidate compound for the prevention or treatment of AD. Several animal models for AD pathology currently exist and investigators have performed studies of curcumin in such animals.

Lim et al(45) studied the effects of curcumin in transgenic mice which carry a human mutation in the amyloid precursor protein (APPsw) that causes AD pathology. APPsw mice display age-related neuritic plaques, inflammation, oxidative damage, and age-related memory deficits but not neurofibrillary tangle pathology. In this study, ten month old APPsw mice were fed diets containing either no curcumin, low-dose (Sigma, 160 ppm), or high-dose curcumin (5000 ppm) for 6 months before being sacrificed. Mice fed low-dose curcumin had decreased total microgial activity, decreased cerebral levels of oxidized proteins, and decreased levels of IL-1β, a cytokine that has been implicated in age-related memory loss(46). Most intriguingly, mice fed low-dose curcumin also had significantly reduced levels of soluble and insoluble Aβ as well as a reduced amyloid plaque burden. An additional observation was that the reduction in microglial activity was localized such that increased activity was observed in the area around amyloid plaques, possibly representing a stimulatory effect of curcumin on phagocytosis of plaques by microglia. APPsw mice fed high-dose curcumin displayed similar decreases in IL-1β and oxidized proteins but no change in Aβ. One possible explanation for the unanticipated results between the low- and high-dose groups is that the multiple mechanisms of action that curcumin has have different dose requirements and time courses that may counterbalance each other at higher doses. More recently we have replicated the effect of low dose curcumin on insoluble Aβ levels in more aged APPsw mice in which AD-like pathology is established (unpublished observations).

Similar effects of curcumin were observed in an animal model of AD in which human Aβ_1–40 and Aβ_1–42 were infused with a lipoprotein chaperone into the cerebral ventricles of aged female rats(47). Such rats develop Aβ deposits, neurodegeneration, and memory impairment. Reduced levels of 8-EPI-F₂ isoprostanes, an oxidative produce of arachidonic acid, and normal levels of synaptophysin, a marker of synaptic integrity were seen in curcumin (2000 ppm), but not ibuprofen-fed rats. Both curcumin and ibuprofen-fed rats had decreased microglial activity. Increased microglial staining was seen in areas surrounding amyloid plaques. We also measured the spatial memory and post-synaptic density 95 (PSD-95) levels, a synaptic protein that anchors N-methyl-D-aspartate (NMDA) receptors, in the brains of younger rats infused with a higher dose of Aβ_1–40 and Aβ_1–42. Rats fed with curcumin (500 ppm) showed reduced path length and latency in finding the hidden platform in the Morris water maze test, demonstrating superior memory function compared to control-fed rats. Increased PSD-95 and decreased Aβ-stained area also were seen in curcumin-fed rats. These studies suggest that curcumin ameliorates both the pathology and cognitive deficits induced by Aβ infusion in rats.

These findings provide evidence that curcumin can ameliorate the pathology and cognitive deficits in animal models of AD but leaves the mechanism for this activity open to question. We have performed subsequent fluorescence studies that demonstrate that curcumin binds to amyloid plaques in human AD and Tg2576 transgenic mouse brain tissue in-vitro. Furthermore, curcumin was found to bind to amyloid plaques when such mice were either fed curcumin or curcumin injected in the carotid artery (in press). This demonstrates that curcumin crosses the blood-brain barrier in these mice, and direct binding to plaques may be important in its anti-amyloid activity. Animal studies therefore are highly suggestive of efficacy against AD pathology via multiple possible mechanisms. Further study of curcumin in the treatment or prevention of AD in humans is warranted.

• To determine the safety and tolerability of 2000 mg and 4000 mg/day of Curcumin C3 Complex® in patients with AD treated for 6 – 12 months.
• To obtain pharmacokinetic data including central nervous system penetration on subjects with AD receiving these doses of orally adminstered Curcumin C3 Complex®.
• To gather data on the effects of curcumin on biomarkers thought to be related to the pathology AD and the mechanism of action of curcumin (cholesterol levels, CSF isoprostanes, alpha-1-antichymotrypsin, C-reactive protein, tau, Aβ_1–40 and Aβ_1–42)
• To gather preliminary efficacy data (Alzheimer’s Disease Assessment Scale, cognitive subscale (ADASCog), Neuropsychiatric Inventory (NPI), Activities of Daily Living Scale (ADCS-ADL)) of curcumin in AD.

There is substantial in-vitro data indicating that curcumin has antioxidant, anti-inflammatory, and anti-amyloid activity. In addition, studies in animal models of AD indicate a direct effect of curcumin in decreasing the amyloid pathology of AD. As the widespread use of curcumin as a food additive and relatively small short-term studies in humans suggest safety, curcumin is a promising agent in the treatment and/or prevention of AD. Nonetheless, important information regarding curcumin bioavailability, safety and tolerability, particularly in an elderly population is lacking. We are therefore performing a study of curcumin in patients with AD to gather this information in addition to data on the effect of curcumin on biomarkers of AD pathology.

NIA ADRC Grant AG 16570, Institute for the Study on Aging, John Douglas French Foundation, and the Shirley and Jack Goldberg Trust