A novel LDL-mimic nanocarrier for the targeted delivery of curcumin into the brain to treat Alzheimer's disease

Accepted Manuscript Title: A novel LDL-mimic nanocarrier for the targeted delivery of curcumin into the brain to treat Alzheimer’s disease Author: Fanfei Meng Sajid Asghar Shiya Gao Zhigui Su Jue Song Meirong Huo Weidong Meng Qineng Ping Yanyu Xiao PII: DOI: Reference:

S0927-7765(15)00398-7 http://dx.doi.org/doi:10.1016/j.colsurfb.2015.06.025 COLSUB 7155

To appear in:

Colloids and Surfaces B: Biointerfaces

Received date: Revised date: Accepted date:

5-4-2015 1-6-2015 10-6-2015

Please cite this article as: F. Meng, S. Asghar, S. Gao, Z. Su, J. Song, M. Huo, W. Meng, Q. Ping, Y. Xiao, A novel LDL-mimic nanocarrier for the targeted delivery of curcumin into the brain to treat Alzheimer’s disease, Colloids and Surfaces B: Biointerfaces (2015), http://dx.doi.org/10.1016/j.colsurfb.2015.06.025 This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.

A novel LDL-mimic nanocarrier for the targeted delivery of curcumin into the brain to

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treat Alzheimer’s disease

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Fanfei Menga, Sajid Asghara,b, Shiya Gaoa, Zhigui Sua, Jue Songa, Meirong Huoa, Weidong

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Mengc, Qineng Pinga, Yanyu Xiaoa*

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Pharmaceutical University, Nanjing 210009, P.R. China

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b

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Faisalabad, Pakistan

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Department of Pharmaceutics, State Key Laboratory of Natural Medicines, China

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P.R. China

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Faculty of Pharmaceutical Sciences, Government College University Faisalabad,

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Department of Clinical Laboratory, People’s Hospital of Liaocheng, Liaocheng 252000,

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* Corresponding author at: Department of Pharmaceutics, State Key Laboratory of Natural

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Medicines, China Pharmaceutical University, No. 24 Tong Jia Xiang, Nanjing 210009, PR

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China.

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[email protected] (Y.Y. Xiao).

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Tel.:

+86-25-83271079;

fax:

+86-25-83271079.

E-mail

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Abstract In this study, a novel low density lipoprotein (LDL)-mimic nanostructured lipid carrier

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(NLC) modified with lactoferrin (Lf) and loaded with curcumin (Cur) was designed for

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brain-targeted delivery, and its effect on controlling the progression of Alzheimer’s disease

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(AD) in rats was evaluated. NLC with the composition resembling the lipid portion of LDL

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was prepared by using solvent evaporation method. Lf was adsorbed onto the surface of NLC

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via electrostatic interaction to yield Lf modified-NLC (Lf-mNLC) as the LDL-mimic

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nanocarrier. In order to make sure more Lf was adsorbed on the surface of NLC, negatively

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charged carboxylated polyethylene glycol (100) monostearate (S100-COOH) was synthesized

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and anchored into NLC. Different levels of S100-COOH (0-0.02mmoL) and Lf modified

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NLC (0.5-2.5 mg/mL of Lf solution) were prepared and characterized. The uptake and

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potential cytotoxicities of different preparations were investigated in the brain capillary

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endothelial cells (BCECs). An AD model of rats was employed to evaluate the therapeutic

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effects of Lf-mNLC. The results indicate that Lf-mNLC with a high level of Lf showed the

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maximum uptake in BCECs (1.39 folds greater than NLC) as cellular uptake of Lf-mNLC by

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BCECs was found to be mediated by the Lf receptor. FRET studies showed Cur still wrapped

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inside NLC after uptake by BCECs, demonstrating stability of the carrier as it moved across

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the BBB. Ex vivo imaging studies exposed Lf-mNLC could effectively permeate BBB and

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preferentially accumulate in the brain (2.78 times greater than NLC). Histopathological

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evaluation confirmed superior efficacy of Lf-mNLC in controlling the damage associated

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with AD. In conclusion, Lf-mNLC is a promising drug delivery system for targeting therapy

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of brain disease.

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Keywords: Lactoferrin; Carboxylated polyethylene glycol (100) monostearate; LDL-mimic

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nanostructured lipid carrier system; Brain targeting; Alzheimer’s disease.

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1. Introduction Alzheimer's disease (AD) is a progressive neurodegenerative disorder with no means yet known for cure or prevention. A potential difficulty in curing irreversible brain degeneration

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in AD is the existence of blood brain barrier (BBB). BBB, a structure that impedes the

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transportation of the drugs and toxic substances into the brain for the sake of its protection, is

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a challenge for the success of therapies against central nervous system (CNS) maladies [1].

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Increasing number of brain ailments in the modern world needs solution to the

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sub-therapeutic brain delivery of pharmacologically active molecules [2]. Various tactics are

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being employed for the delivery of neurotherapeutics across the BBB, but this research

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domain still needs vigorous efforts to achieve the goal [3, 4] .

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Lipid based nanocarriers have been widely reported for the treatment of brain diseases

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[5]. Recently, novel nanocarriers based on low density lipoprotein (LDL) are getting attention

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for their distinctive characteristics [6-8]. LDL is a 22-27 nm particle composed of a core of

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hydrophobic lipids, primarily cholesteryl esters with a small amount of triacylglycerides, and

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has a surface coat of phospholipids, unesterified cholesterol, and a single molecule of

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apolipoprotein B 100 (ApoB-100) [9, 10]. As a kind of naturally originated particle, LDL is

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non-immunogenic and long circulating, and possesses the innate ability to bind both

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hydrophobic and hydrophilic molecules. In addition, the overexpression of the low density

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lipoprotein receptors (LDLR) in brain capillary endothelial cells (BCECs) offers the

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advantage of brain targeting for LDL-based nanoparticles [11, 12]. However, the quantities of

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natural LDL extracted from human serum are extremely low, and it is difficult to isolate LDL

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in large quantities due to the variable composition and size. Another approach uses

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reconstituted LDL consisting of a lipid emulsion [13, 14], and ApoB-100 has been used for

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stabilizing such emulsions. It is also difficult to isolate ApoB-100 from human serum due to

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its large size and propensity to aggregate. Lactoferrin (Lf), an 80 kDa naturally occurring iron binding cationic glycoprotein, is

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abundantly found in milk. It has been reported to possess anti-inflammatory, antibacterial,

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antifungal, antiviral, and anti-cancer activities. It can also boost natural immunity, bone

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growth, and wound healing [15, 16]. Lf can be transported across BBB by the mediation of

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the lactoferrin receptors (LfR) present at the endothelial cells of the BBB [17-19]. Some

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studies showed the expression of LfR in the state of AD and Parkinson’s disease at the

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endothelial cells of the BBB would be increased [20].

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Curcumin

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molecular

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phytochemical,

possesses

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pharmacological activities, including anti-oxidant, anti-inflammatory, anti-cancer, and

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antidepressant properties with low intrinsic toxicity [21, 22]. It is widely acknowledged that

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the progressive accumulation of Aβ aggregates initiates the initial development of

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neurodegenerative pathology and trigger a cascade of events such as neurotoxicity, oxidative

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damage, and inflammation that contribute to the progression of AD [23]. Cur has been shown

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to effectively reduce neurotoxic Aβ aggregates and ameliorate cognitive deficits in vivo and

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in vitro [24, 25].

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The objective of this research work was to develop a novel LDL-mimic nanocarrier

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(nanostructured lipid carrier (NLC) modified with Lf, Lf-mNLC) encapsulating Cur for

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brain-targeted delivery, and evaluate its effect on controlling the progression of AD in rats.

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Cur-loaded NLC with the composition resembling the lipid portion of LDL (PC, cholesterol 5

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oleate and glycerol trioleate) was prepared by using solvent evaporation method. Lf,

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positively charged at physiological pH, instead of ApoB-100, was used as a brain targeting

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molecule and was adsorbed onto the surface of NLC via electrostatic interaction to yield

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Lf-mNLC as the LDL-mimic nanocarrier. Carboxylated polyethylene glycol (100)

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monostearate (S100-COOH) was synthesized and its free surface carboxyl could enhance the

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negative charge of NLC, which facilitated more Lf was absorbed on the surface of NLC

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through electrostatic attraction.

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2. Experimental

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2.1 Materials

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Cur (purity, 98%) was purchased from Aladdin Reagent Co., Ltd. (Shanghai, China).

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Glycerol trioleate (purity, >98%) and phosphatidyl choline (PC, purity, 90%) were kindly

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donated by Evonik Degussa China Co., Ltd. (Shanghai, China). Cholesterol oleate

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(purity, >85%) and coumarin-6 (C6) were purchased from Tokyo Chemical Industry (Tokyo,

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Japan). Polyethylene glycol (100) monostearate (S100, the polymerization degree of ethylene

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glycol

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3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT) were purchased from

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Sigma-Aldrich (Milwaukee, WI, USA). Aβ1-42 (purity, 95.34%) was purchased from GL

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Biochem Ltd (Shanghai, China). D-galactose (D-gal) was purchased from Sigma-Aldrich

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(Milwaukee, WI, USA). All other chemicals and reagents were of analytical grade and used

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without further purification.

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2.2 Animals

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SDS-PAGE)

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Sprague-Dawley (SD) rats (180-220 g) and ICR mice (18-22 g) were obtained from 6

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Experiment Animal Center of Nantong University (Nantong, China). All animal procedures

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for this study were approved by the ethical committee of China Pharmaceutical University,

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and they were conducted in accordance with approved standards for laboratory animal care.

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2.3 Synthesis of S100-COOH

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Carboxylated polyethylene glycol (100) monostearate (S100-COOH) was synthesized

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using a one-step procedure. Briefly, 11.71 g of S100 and 0.5 g of succinic anhydride were

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mixed and activated with the catalysis of pyridine (7.5 mL) at 65 oC for 48 h. Subsequently,

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the pyridine was removed using a rotary evaporator and the residues were hydrated with 200

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mL of distilled water. The resultant solution was dialyzed with a Spectrum dialysis bag

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(MWCO of 3.5 kDa, Sigma, USA) at 4 oC for 48 h to remove the unreacted succinic

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anhydride and lyophilized to obtain S100-COOH. The structure of S100-COOH was

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characterized by 1H-NMR and 13C-NMR spectra (AVANCE AV-300, Bruker Instrument Inc.,

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Switzerland) using D2O as a solvent at 25 °C, respectively.

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2.4 Preparation of Cur-loaded Lf-mNLC

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Firstly, Cur-loaded NLC was prepared by a solvent evaporation method [26]. Briefly, PC

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(330 mg), cholesterol oleate (20 mg), glycerol trioleate (70 mg), Cur (16 mg) and different

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amounts of S100-COOH (0-0.02 mmoL) were dissolved in 10 mL of ethanol/chloroform

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mixture (1:1, v/v) and dried in a rotary evaporator under vacuum at 40 °C. The dried lipid

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film was hydrated with 10% (v/v) glycerol solution at 37 °C and ultrasonicated at 300 W for

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5 min at 4 °C, followed by extrusion through 0.22 μm cellulose nitrate membrane to remove

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the unentrapped drug and obtain Cur-loaded NLC. Afterwards, Cur-loaded Lf-mNLC was

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prepared by incubating Cur-loaded NLC with Lf solution. Briefly, 0.5, 1.5, or 2.5 mg/mL of 7

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Lf solution (dissolved in Tris-EDTA buffer (pH7.4)) was gently mixed with an equal volume

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of Cur-loaded NLC at 4 °C for 24 h. The three levels of Lf modified NLC were named as

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LfL-mNLC, LfM-mNLC and LfH-mNLC.

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2.5. Characterization of Cur-loaded NLC and Cur-loaded Lf-mNLC

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2.5.1. Morphology, particle size, zeta potential, EE and DL

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The particle size, polydispersity index (PI) and zeta potential of Cur-loaded NLC and

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Lf-mNLC were detected by Zetasizer 3000HS (Malvern, U.K.). Their morphological

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observations were performed by transmission electron microscopy (TEM, H-7000, Hitachi,

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Japan). EE of NLC and DL of NLC/Lf-mNLC were determined as previously reported [27].

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2.5.2. Fluorescence and UV-Visible absorbance spectra

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The interaction of Cur with the hydrophobic lipid core of NLC or Lf-mNLC was

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investigated by fluorescence and UV-Visible absorption spectra [28, 29]. The fluorescence

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and UV-Visible absorption spectra of Cur (dissolved in methanol), Cur-loaded NLC and

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Lf-mNLC (in aqueous solution) with the Cur concentration of 1.5 μg/mL were compared.

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The fluorescence emission spectrum was recorded from 450 to 700 nm with an excitation

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wavelength of 420 nm. Excitation and emission slit widths (modulation of magnitude and

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resolution of transmitted light) were standardized at 5 nm each. The UV-Visible absorption

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spectrum was taken from 300 to 700 nm.

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2.5.3. Plasma stability of NLC and LfH-mNLC

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NLC and LfH-mNLC were mixed with the equal volume of the rat plasma and incubated

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for prearranged time intervals (15, 30, 60, 120, 240, 360 min) in a 37 °C water bath. After

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incubation, 100 μL of the sample was diluted in 4 mL of distilled water and the particle size 8

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and zeta potential were measured by the Dynamic Light Scattering Analyzer.

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2.5.4 In vitro drug release study The in vitro release of Cur from NLC or Lf-mNLC was carried out in physiological saline

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containing 1% (w/v) tween 80 using a membrane dialysis method. 1 mL of different Cur

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preparations (containing 400 μg of Cur) was placed in a pre-swelled dialysis bag (8~10 kDa

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MW cutoff, Sigma, USA). Cur solution (containing 30%（w/w）polyethylene glycol 400) was

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taken as a control. The bag was tightened and soaked in 50 mL of release medium at 37 °C

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for 48 h (n=3). At a given time interval, 1 mL of the medium was withdrawn and replaced

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with the same amount of pre-warmed fresh medium. The withdrawn sample was then

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centrifuged at 12,000 rpm for 10 min and the supernatant was analyzed by HPLC method

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[27]. Care was taken to protect the sample from light throughout the experimental procedure.

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The release kinetic models were studied using DDsolver software.

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2.6. Cytotoxicity and cellular uptake studies

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2.6.1. Cell culture

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BCECs were cultured in the endothelial cell culture medium that contained DMEM/F12,

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20% heat-inactivated fetal bovine serum (FBS), 100 U/mL penicillin, and 100 μg/mL

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streptomycin. BCECs were maintained in an incubator (Thermo Scientific, USA) at 37 °C

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under an atmosphere of 5% CO2.

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2.6.2. Cytotoxicity evaluation

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In order to justify the nontoxicity of different empty preparations, their cells viabilities

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were determined by MTT assay. Briefly, 5 × 103 cells/well were seeded in 96-well culture

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plates for 24 h and then incubated with empty NLC, empty LfL-mNLC, empty LfM-mNLC, 9

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and empty LfH-mNLC. The concentrations of empty carriers were in the range of 100−1600

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μg/mL. After 24 h incubation, 10 μL of 5 mg/mL MTT was added into each well for 4 h in

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dark, and then the medium was replaced with 150 μL of DMSO. The absorbance value at 570

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nm (A570nm) was read using the microplate reader (Thermo Electron Corporation. USA). Cell

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viability was expressed as a percentage of A570nm of the study group relative to that of control

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group.

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2.6.3. Cellular uptake

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C6-loaded NLC and Lf-mNLC were prepared similar to the preparation of Cur-loaded

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NLC/ Lf-mNLC, but Cur was replaced with C6. BCECs were seeded into twelve-well plates

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at a density of 2×105 cells/well and cultured in complete cell-culture medium for 24 h at

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37 °C. Then, the medium was replaced with 1 mL of different C6-loaded preparations (C6=

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300 ng/mL) and cells were further incubated for another 2 h. Cells were trypsinized and

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harvested. The fluorescence intensities of C6 in cells were determined by a BD FACS Calibur

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flow cytometer (BD Bioscience, Bedford, MA). The excitation wavelength of C6 was 465 nm,

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and FL1-H filter was used for the collection of fluorescence intensity. The data were analyzed

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through Flow Jo 7.6 software. The influences of incubation concentration, temperature and

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time on cellular uptake of the formulations were also monitored. Furthermore, uptake

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inhibition experiment was also performed by pre-incubating BCECs with excess of Lf (10

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mg/mL) for 30 min, and then the cells were incubated for 2 h at 37 °C with NLC or

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LfH-mNLC (C6=100 ng/mL).

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2.7. Intracellular stability of NLC and LfH-mNLC

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FRET analysis was conducted to evaluate the stability of NLC or Lf-mNLC in cells after 10

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uptake by BCECs in order to make sure the passage of drug across the BBB in the form of

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being wrapped in NLC [30]. A FRET pair of hydrophobic dyes, DiO as donor and DiI as

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acceptor, was loaded into the core of NLC or LfH-mNLC, with the method similar to the

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preparation of Cur-loaded NLC/ LfH-mNLC. In order to verify the occurrence of FRET, the

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fluorescence spectra of NLC or LfH-mNLC loaded with DiI and DiO were measured in the

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blank cell culture medium-DMEM/F12 or trichloromethane-methanol (1:1) with the

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excitation at 488 nm. To monitor the integrity of carriers in BCECs, NLC or LfH-mNLC were

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incubated with BCECs at 37°C for 1 h. Subsequently, NLC or LfH-mNLC was removed, and

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the cells were washed thrice with ice-cold PBS. At last, the cells were incubated with the cell

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culture medium for predetermined time periods. Fluorescence images were acquired with the

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excitation at 488 nm, and the emission between 555 nm and 655 nm for DiI detection, as well

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as the emission between 500 nm and 530 nm for DiO detection by CLSM (Leica TCS SP5).

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2.8. Pharmacokinetics

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intravenous administration of Cur solution, Cur-loaded NLC and LfH-mNLC at a dose of 10

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mg/kg of Cur (n=5). After being collected at predetermined intervals, the blood was

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centrifuged at 4000 rpm for 10 min at 4 °C and then the plasma were frozen at -20°C until

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assay. 100 μL of acetonitrile was added into 100 μL of plasma, vortexed for 2 min and

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centrifuged at 12000 rpm for 10 min. 20 μL of supernatant was injected into the HPLC

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system equipped with a fluorescence detector (Shimadzu, Japan) to determine the

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concentration of Cur, and the excitation and emission wavelength were 436 and 518 nm,

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respectively. The plasma concentration versus time data were analyzed by Kinetica 4.4 11

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(Thermo Electron Corporation, Waltham, MA, USA) and various parameters were studied.

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2.9. Biodistribution study In order to verify the brain-targeting of Lf-mNLC, ex vivo imaging experiments were

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performed in rats. DiR, a hydrophobic near infrared dye, was loaded into NLC or LfH-mNLC.

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SD rats were intravenously administered with DiR-loaded NLC or LfH-mNLC (0.5 mg/kg)

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and anesthetized. A Kodak multimodal-imaging system IS2000MM (Kodak, USA) was used

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to perform ex vivo imaging experiments at 1, 2, 3 and 4 h post injection with the wavelength

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fixed at 720 nm for excitation and 790 nm for emission. To probe the biodistribution of NLC

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or LfH-mNLC, rats were sacrificed at 24 h post-injection, and different organs were separated

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and washed by saline, assembled for fluorescence imaging and analyzed by IS2000MM

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software (Kodak ID Image Analysis Software, Kodak).

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In addition, brain sections were used to further understand the distribution of NLC or

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LfH-mNLC in the CNS. Briefly, C6-loaded NLC and LfH-mNLC (6 mg/kg) were injected into

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the tail veins of mice, respectively. After 1 h, the mice were anaesthetized and then the brains

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were removed, fixed in 4% paraformaldehyde for 24 h, and dehydrated with 15% sucrose

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solution for 12 h and then 30% sucrose solution for 24 h. Thereafter, the brain samples were

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frozen in OCT (Sakura, Torrance, CA, USA) at -80 °C and cut into 20 μm thickness with a

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cryotome Cryostat (Leica, CM 1900, Germany). After staining with 5 μg/mL DAPI for 20

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min at room temperature, slides were observed using a fluorescence microscope (Olympus,

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Japan). Fluorescence intensity of C6 in the third ventricle and cortex was measured and

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analysed using Image J software.

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2.10 Neuroprotective effects of different Cur preparations on AD model rats

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2.10.1 In vivo model of AD The in vivo model of AD was established in rats by administering Aβ1-42 and D-gal. The

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SD rats were treated with intraperitoneal injection 4% D-gal (0.3 mL/100g/d) by

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intraperitoneal injection for six weeks. Aβ1-42 was dissolved in saline (1 mg/mL) and then

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incubated at 37 °C for 7 days to form the aggregation. The rats were anaesthetized and fixed

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in a stereotaxic apparatus. The animals were bilaterally injected in the dorsal hippocampus

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(2.3 mm posterior to the bregma, ±1.8 mm lateral to the Midline and 2.0 mm ventral to the

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skull surface) with 5 μL of Aβ1-42 within 5 min. The needle was then slowly withdrawn after

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being kept for another 3 min. Rats in the sham group were injected with the same volume of

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saline. After surgery, the rats were kept in the cages for recovery.

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2.10.2 Drug administration

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AD model rats were divided into five groups: the AD control group, sham group, and

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three test groups (n=10 for each group). One week after the surgery, Cur solution (30% (w/v)

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PEG-400 in a 5% (v/v) glucose solution), NLC and LfH-mNLC were intravenously

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administered to the rats at 2 mg/kg/d equivalent dose of Cur for three weeks, respectively.

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2.10.3 Determination of malondialdehyde (MDA)

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The rats were anaesthetized with ether, and blood samples were taken from the

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eyeground veins. The plasma was obtained after centrifugation (5 min, 4000 rpm, 4 °C) and

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assessed for the concentration of MDA using a MDA assay kit according to the

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manufacturer’s protocols.

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2.11 Histopathology

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Rats in each group (n=5) were anaesthetized and perfused through the heart with cold 13

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saline followed by 4% paraformaldehyde. Then the whole brains were harvested and

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immersed in 4% paraformaldehyde. Afterwards, the brains were embedded in paraffin and cut

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into 5-μm sectioned. Sections were stained with hematoxylin-eosin (HE) staining,

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respectively. The hippocampal areas were examined under a Leica optical microscope (Leica,

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Germany).

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2.12. Statistical data analysis

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The data are given as mean ± SD. Statistical significance was tested by two-tailed Student’s t test or one-way ANOVA. Statistical significance was set at P < 0.05.

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3. Results and discussion

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3.1 Preparation and characterization of NLC and Lf-mNLC

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3.1.1. Morphology, particle size, zeta potential, EE and DL

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Based on particle size, zeta potential and EE, Cur-loaded NLC was prepared with PC,

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cholesterol oleate, glycerol trioleate and Cur according to an optimized ratio of

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1:0.06:0.21:0.05 (w/w/w/w). Effects of different amounts of S100-COOH on particle size, PI,

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zeta potential and EE of Cur-loaded NLC are listed in Table 1A. The particle size of NLC

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decreased after modification with S100-COOH and was found inversely proportional to the

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amount of S100-COOH, which might be due to its surface-active effects [31]. In addition, the

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PEG chains of S100-COOH could act as a tighter net on the outside of vesicles, thus limiting

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the increase of vesicle size [26]. The inclusion of S100-COOH in NLC also led to the

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increase in negative charge due to the ionized –COOH on the surface of NLC and the

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absolute value of zeta potential increased gradually with the increase of S100-COOH. The

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substantial increase in PI and decrease in EE as the added amount of S100-COOH increased

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to 0.02 mmoL could be due to two reasons. Firstly, the added amount of S100-COOH might

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not totally arrange themselves on the surface of NLC and they could have spontaneously

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formed the small sized unstable micelles [32]. The drug could be easily released from the

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micelles and precipitate in the medium. Secondly, the decreased drug loading space owing to

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the smaller particle size might also contribute to the partial drug encapsulation. As the

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isoelectric point of Lf is about 8.65, the protein would be positively charged in the suspension

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of NLC (pH 6.0-6.5). The more the negative charge on the surface of NLC, the more

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favorable it is for Lf to be adsorbed on the surface of NLC. Therefore, NLC coated with

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0.012 mmoL of S100-COOH was chosen for further modification.

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Table 1B shows the effect of different concentrations of Lf on particle size, PI, zeta

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potential, EE, and DL of Cur-loaded NLC coated with 0.012 mmoL of S100-COOH. The

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adsorption of Lf on the surface of NLC led to the increase of particle size and zeta potential

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of NLC. However, Lf coating had not interfered with DL and EE of NLC. The particle size

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and shape of NLC and Lf-mNLC were further confirmed by TEM (Fig. 1). Both NLC and

324

Lf-mNLC were quasi-spherical in shape. However, Lf-mNLC appeared a core-shell structure

325

and the thickness of the covering layer increased with the increasing amount of Lf.

326

Furthermore, a dense core was observed for nanocarrier with high concentration of Lf which

327

is not evident in NLC or Lf-mNLCs with low concentration of Lf. This could be due to

328

formation of a more compact nanocarrier owing to the greater electrostatic interactions with

329

higher concentration of Lf. TEM also showed that both NLC and Lf-mNLC were uniformly

330

dispersed without any visible sign of aggregation, indicating the stability of the formulations.

331

3.1.2. In vitro drug release study

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Page 15 of 38

In vitro drug release profiles of Cur from different preparations are studied (see Fig.2 of

333

the Appendix). Except for Cur solution, all preparations exhibited sustained release of Cur

334

without any burst release, which could be attributed to the encapsulation of Cur into NLC.

335

Compared with NLC, the release of Cur from Lf-mNLC decreased significantly (P < 0.05)

336

and increasing the amount of Lf further slowed the drug release, which suggests that Lf

337

adsorption further limited the diffusion of the drug from NLC [33].

us

cr

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332

In order to explore the release mechanisms of Cur from Cur-loaded NLC and Lf-mNLC,

339

various models (zero-order, first-order, Higuchi, and Weibull models) were utilized to

340

simulate the release profiles (see Table 1 of the Appendix). Weibull model was found to be

341

the best-fit model to explain the release process. According to the exponent parameter (β) of

342

Weibull model, the Cur release mechanism from NLC and Lf-mNLC was found to be the

343

combined mechanism of Fickian diffusion and Case II transpobrt [34].

344

3.1.3. Fluorescence and UV-Visible absorbance spectra

M

d

te

Fluorescence and UV-Visible absorbance spectra of Cur, Cur-loaded NLC and

Ac ce p

345

an

338

346

LfH-mNLC are presented in Fig. 2. As depicted in the UV-Visible absorbance spectrum, there

347

is an intense absorption band at around 425 nm for Cur and the presence of a shoulder peak at

348

350 nm indicates the location of Cur in polar environment [29]. However, the appearance of a

349

shoulder peak at around 450 nm for the Cur-loaded NLC and LfH-mNLC could be ascribed to

350

the presence of Cur in the apolar core of NLC and LfH-mNLC [35]. For the fluorescence

351

spectra, Cur in methanol showed a sharp fluorescence peak at around 540 nm, but there was a

352

blue shift in the fluorescence spectra of Cur-loaded NLC and LfH-mNLC and Cur showed a

353

well-defined peak at around 520 nm. Sahu et al. [36] reported that when encapsulated in 16

Page 16 of 38

bovine casein micelle, Cur showed a shift in fluorescence spectra from 540 nm to 500 nm

355

because of the binding of Cur in the hydrophobic domain of the protein molecule in micelle.

356

Therefore, we inferred that when compared with that of native Cur, the blue shift in

357

fluorescence spectrum of Cur was induced by the encapsulation of Cur in the hydrophobic

358

domain of the NLC and LfH-mNLC through hydrophobic interactions.

359

3.1.4 Plasma stability

us

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354

In order to study the plasma stability of NLC and LfH-mNLC, variations in the particle

361

size and zeta potential of formulations were assayed in the rat plasma. The results showed

362

that NLC and LfH-mNLC had slightly smaller diameters in plasma than in distilled water, but

363

remained stable (see Fig.3A of the Appendix). The insignificant changes in the size of the

364

nanocarriers imply that the coating of Lf did not affect the stability of NLC in the plasma and

365

LfH-mNLC was stable in the plasma. The zeta potential of NLC and LfH-mNLC both dropped

366

to nearly -25 mv after 15 min incubation with the plasma and then remained steady for the

367

rest of the study (see Fig.3B of the Appendix). This could be attributed to the presence of

368

negatively charged proteins in the serum.

369

3.2. In vitro cytotoxicity assay against BCECs

M

d

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370

an

360

No significant toxicity on BCECs was found for empty NLC and Lf-mNLC as more

371

than 80% cell viability was observed even at highest concentration (1600 μg/mL) (see Fig.4

372

of the Appendix). Formulations that show greater than 80% cell viability have been regarded

373

as safe [37]. There were no significant differences in cell viability of NLC and Lf-mNLC

374

group, which shows both NLC and Lf-mNLC might be good biocompatible carriers.

375

3.3. Cellular uptake study 17

Page 17 of 38

The uptake of LfL-mNLC, LfM-mNLC and LfH-mNLC in BCECs was 1.06, 1.16 and

377

1.39 times higher, respectively, compared to that of NLC (Fig. 3A). As the cellular uptake of

378

LfH-mNLC was higher than those of LfL-mNLC and LfM-mNLC, LfH-mNLC was chosen for

379

subsequent studies.

ip t

376

As shown in Fig. 3B, the uptake amounts of both LfH–mNLC and NLC at 37 °C were

381

much higher than those at 4 °C, suggesting that their uptakes were energy-dependent. The

382

uptake increased with the increase in the concentration of C6 from 10-100 ng/mL, which

383

indicates that the uptakes of both NLC and LfH-mNLC were also concentration-dependent.

384

The uptakes of NLC and LfH–mNLC by BCECs were also dependent on the incubation time

385

(Fig. 3C). As shown in Fig. 3D, the uptake of LfH–mNLC was significantly suppressed in the

386

presence of excess free Lf, while the uptake of NLC was scarcely influenced, which confirms

387

that Lf mediated endocytosis mechanism was responsible for the enhanced uptake of

388

LfH–mNLC. BCECs have been reported to possess LfR and an increase of these receptors in

389

BCECs has also been found in Parkinson's and Alzheimer's disease [38, 39], which could

390

extend the applications of Lf-mNLC for the treatment of various brain malignancies.

391

3.4. Intracellular integrity studies of NLC and LfH-mNLC

us

an

M

d

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392

cr

380

FRET occurs through the energy transfer from the donor (DiO) to the acceptor (DiI)

393

only when both fluorescent molecules are in a range of 1-10 nm. Implicitly, with the increase

394

in distance between the donor and acceptor, the FRET ratio IR/(IG+IR) decays very rapidly,

395

where IR and IG are fluorescence intensities at 576 nm and 508 nm, respectively. When the

396

carriers disintegrate in the cells, the fluorescent molecules could not be closely retained

397

anymore, thus resulting in a lower FRET ratio [40]. Therefore, we used FRET experiment to 18

Page 18 of 38

398

monitor the stability of the carriers in cells after uptake by BECEs. LfH-mNLC in DMEM/F12 showed a strong DiI signal (see red curve in Fig. 5 of the

400

Appendix) with a FRET ratio of 0.80, which shows LfH-mNLC were stable in DMEM/F12.

401

While after using trichloromethane-methanol (1:1) to destroy the carriers, FRET phenomenon

402

almost disappeared (see green curve in Fig. 5 of the Appendix) with a FRET ratio below 0.30.

403

Same behavior was expressed by mNLC (data is not shown). The confocal images showed

404

that both NLC and LfH-mNLC in BCECs had a strong FRET phenomenon at 1 h post

405

incubation (Fig. 4), which indicates that the carriers remained intact in the cells. With the

406

passage of time (1-4 h), a decrease in red fluorescence was seen, however intracellular FRET

407

phenomenon was still existing, and implying most of the carriers didn’t disintegrate in the

408

BCECs and kept their integrity. At 8 h, the green fluorescence of DiO became much stronger

409

and FRET phenomenon disappeared, suggesting the disintegration of NLC and LfH-mNLC.

410

BBB is the unavoidable doorway for the brain targeted delivery systems, but it is not the

411

destination. The carriers intended for CNS delivery should remain intact while moving across

412

BCECs and avoid enzymatic degradation in the BCECs, which guarantees the efficient drug

413

delivery to the diseased regions of brain. Previously, Lf functionalized nanoparticles have

414

been reported to attain maximum concentration in the brain after 1 h following intravenous

415

administration [37, 41, 42]. FRET experiments revealed that NLC or LfH-mNLC were stable

416

in BCECs for at least 4 h, which might be long enough to permit safe passage of drug across

417

the BBB.

418

3.5. Pharmacokinetic studies

419

Ac ce p

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an

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399

The plasma concentration-time curves of Cur after intravenous injection of different 19

Page 19 of 38

preparations in rats are shown in Fig. 5. The blood concentration of Cur decreased rapidly

421

within the initial 2 h and could not be detected at 4 h after intravenous administration of Cur

422

solution. However, the concentration of Cur after intravenous administration of Cur-loaded

423

NLC and Lf-mNLC at 4 h were 13.03 and 5.49 ng/mL, respectively.

ip t

420

The pharmacokinetic data of Cur were simulated by non-linear least squares. The results

425

showed that the kinetics of a two-compartment open model was best fitted to Cur plasma

426

concentration-time curves in rats. The area under the curve (AUC) and MRT dramatically

427

increased and the clearance (CL) decreased (P<0.05) for Cur encapsulated in NLC when

428

compared with Cur solution (Table 1C). Compared to the drug solution, NLC and LfH-mNLC

429

showed 2.53 and 1.55 folds higher AUC, respectively and prolonged residence in body with

430

4.49 and 3.02 times greater MRT, respectively. While, 1.81 and 1.05 times lesser clearance

431

from the body than the drug solution was observed for NLC and LfH-mNLC, respectively.

te

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cr

424

Comparing the pharmacokinetic parameters of NLC and LfH-mNLC, an even lower

433

AUC and higher CL were observed for the latter. The coupling of NLC’s surface with Lf

434

affected the pharmacokinetics of NLC. These results are in good agreement with a previously

435

published study [43]. The main reason may be the specific targeting capability of Lf which

436

could have accelerated the uptake of Lf-mNLC by the target tissues or organs [44].

437

3.6. Biodistribution studies

Ac ce p

432

438

To investigate the brain-targeting capability of Lf-mNLC, ex vivo fluorescence images

439

of the rats were acquired after intravenous administration of DiR-loaded NLC and

440

LfH-mNLC. As displayed in Fig. 6A, the LfH-mNLC group showed significantly higher

441

fluorescence intensity in the brain than the NLC group at any time point post-administration. 20

Page 20 of 38

Additionally, the brain and major organs were harvested and imaged at 24 h

443

post-administration (Fig. 6B). As shown in Fig. 6C, The fluorescence intensity in brain tissue

444

for the LfH-mNLC group was 2.78 times high as that for the NLC group according to the

445

quantitative DiR fluorescence intensity, indicating that LfH-mNLC accumulated more than

446

NLC in brain. The presence of NLC in the brain could be attributed to the presence of PEG. It

447

has been previously demonstrated that PEG coated nanoparticles might adsorb the

448

apolipoprotein E (ApoE), and utilize the LDLR mediated transport to cross the BBB [45].

449

Our results suggested that LfH-mNLC could cross the BBB and penetrate the brain more

450

efficiently than NLC that might be attributed to the interaction between Lf and Lf receptors

451

over-expressed at the BBB.

M

an

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442

Fig. 7A shows coronal slices of the mouse brain. Periventricular region of the third

453

ventricle and cortex showed the green fluorescence of C6. The stronger and widely

454

distributed fluorescence intensity of LfH-mNLC than that of NLC quantified with help of

455

Image J software (Fig. 7B), in these regions, indicates that Lf-receptor mediated transcytosis

456

process might have allowed LfH–mNLC to penetrate the BBB and access the brain

457

parenchyma. The therapeutic targets for the treatment of various disorders (insomnia,

458

neurodegenerative disorders, obesity) are hypothalamus and thalamus which are present at

459

the sides of the third ventricle [46, 47]. The outreach of this novel Lf-mNLC to these areas of

460

brain makes it as a suitable candidate for the delivery of therapeutic moieties.

461

3.7. Pharmacodynamic study

462

3.7.1. In vivo model of AD

463

Ac ce p

te

d

452

There

are

many

reports

about

establishing

the

model

of

AD

through

21

Page 21 of 38

intracerebroventricular injection of Aβ1-42 [48]. D-gal is a normal substance in the body and

465

can be metabolized at normal concentrations. However, at high levels it can be oxidized into

466

aldose and hydroperoxide under the catalysis of galactose oxidase, resulting in the formation

467

of a superoxide anion and oxygen-derived free radicals. These free radicals can induce

468

neuronal degeneration and death [49]. Some studies have demonstrated that long-term

469

subcutaneous injection of D-gal lead to the oxidative modifications in cerebral tissue, and

470

further contributes to lipofuscin deposition, slight neuronal damage and memory decay which

471

are similar to the pathological characters of natural aging model [50]. The animal model of

472

AD with combined administration D-gal and Aβ1-42 was better to reflect the complexity of the

473

disease and was more similar to the symptoms and pathological alteration of AD.

474

3.7.2. Determination of MDA level in blood

M

an

us

cr

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464

Oxidative stress can cause damage to membrane lipids, proteins and antioxidative

476

enzyme defense system, thus resulting in the oxidative modifications in cerebral tissue. This

477

further leads to lipofuscin deposition, neuronal damage and memory decay which are all

478

prominent and early changes in AD [50]. MDA increase is an important indicator of lipid

479

peroxidation, which is a well-known paradigm of damage to membranes under conditions of

480

oxidative stress [51]. Furthermore, MDA plasma levels have often been used as the oxidative

481

biomarkers for D-gal-induced aging models [50].

Ac ce p

te

d

475

482

The decrease in MDA levels for Cur solution group, NLC and LfH-mNLC group were

483

found to be 8.29%, 14.09% and 21.2%, respectively (see Fig. 6 of the Appendix). The content

484

of MDA in the blood of the AD model rats increased almost by 50% compared with the sham

485

control group, while the MDA levels significantly (P<0.05) decreased in the NLC and 22

Page 22 of 38

LfH-mNLC compared with Cur solution treated group. For LfH-mNLC group, the decrease of

487

MDA was 1.50 and 2.68 folds of that in NLC and Cur solution group, respectively. This

488

suggests that LfH-mNLC group could successfully cross the BBB and effectively reduce the

489

damage associated with oxidative stress.

490

3.7.3. Histopathology

cr

ip t

486

Neuronal loss in the hippocampus is one of the key hallmarks of AD [52]. Histological

492

observations were conducted to examine the state of the nerve cells in hippocampus region

493

and to evaluate the treatment effectiveness of Cur loaded formulations. No neuronal damage

494

was discovered in the rats of sham group while obvious neuronal loss, karyopyknosis and

495

perikaryon shrinkage were observed in hippocampus of AD control group (see Fig. 7 of the

496

Appendix). After treatment with Cur loaded formulations, the pathological damages were

497

ameliorated to varying extents. The ameliorative effects were more significant for LfH-mNLC

498

as compared to the NLC or Cur solution, which indicates that LfH-mNLC could effectively

499

bypass the BBB and deliver the drug to the brain, making it be a capable carrier for further

500

investigations in the treatment of brain malignancies.

an

M

d

te

Ac ce p

501

us

491

To construct an animal model of AD, primates are the ideal animals owing to their

502

structural and behavioral similarities to humans. But, their use in the laboratory research is

503

limited due to the cost and availability constraints. Presently, rodents (rats and mice) are

504

preferred for the construction of animal AD models [42, 48, 53]. The models of rodents are

505

developed on the basis of pathogenesis of AD reflecting the pathological characters of disease.

506

During current research, the positive results of LfH-mNLC traversing the BBB and

507

ameliorating the pathological characters in the models of rodents indicate its potential 23

Page 23 of 38

508

effectiveness in primates. Nevertheless, future studies should be conducted on primates to

509

evaluate the immunogenicity and safety of LfH-mNLC over a long period of time.

510

4. Conclusion In this study, a novel LDL-mimic nanostructured lipid carrier system (Lf-mNLC) was

512

developed for brain-targeted delivery. Lf-mNLC showed sustained release of active moiety

513

with no significant difference for formulations with different levels of Lf. The significantly

514

increased uptake of Lf–mNLC by BCECs compared with that of NLC diminished in the

515

presence of free Lf, which exposes the Lf receptor mediated endocytosis process. The brain

516

coronal sections displayed a higher accumulation of Lf–mNLC in the cortex and the third

517

ventricle than that of NLC. The pharmacodynamic studies revealed that Lf-mNLC could

518

efficiently control the progression of the AD. In conclusion, Lf–mNLC may provide a

519

flexible drug delivery platform for brain targeting.

520

522

Acknowledgments

Ac ce p

521

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d

M

an

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511

This work was supported by the Natural Science Foundation of Jiangsu Province

523

(Program No. BK20130655, No. BK2012761), the Open Project Program of State Key

524

Laboratory of Natural Medicines, China Pharmaceutical University (Program No.

525

SKLNMKF201204) and College Students Innovation Project for the R&D of Novel Drugs

526

(Program

527

entrepreneurial training program (Program No. G13076).

No.

J1030830)

and

the

National College

Students'

innovation

528 529 24

Page 24 of 38

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595

[52] Q.X. Song, M. Huang, L. Yao, X.L. Wang, X. Gu, J. Chen, J. Chen, J.L. Huang, Q.Y. Hu, T. Kang, Z.X. Rong, H. Qi,

596

G. Zheng, H.Z. Chen, and X.L. Gao, ACS Nano, 8 (2014) 2345. 27

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597 598

[53] Y. Luo, F.N. Niu, Z.Z. Sun, W.S. Cao, X. Zhang, D.N. Guan, Z.M. Lv, B. zhang, and Y. Xu, Mech. Ageing. Dev., 130 (2009) 248.

Ac ce p

te

d

M

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cr

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ip t cr us

Fig. 1. TEM images of NLC (A), LfL-mNLC (B), LfM-mNLC (C), and LfH-mNLC (D). Bar is 100 nm.

an

599 600 601

M

602 603

Ac ce p

te

d

604

29

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ip t cr us

604

Fig. 2. UV-Vis absorption spectra (Left) and fluorescence emission spectra (Right) of Cur solution (a),

606

Cur- loaded NLC (b) and LfH-mNLC (c).

Ac ce p

te

d

M

607 608

an

605

30

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ip t cr us an

608

Fig. 3. (A) Uptake of different formulations in BCECs at a dose of 300 ng/mL of C6 at 37 °C (n = 3); Uptake

610

of NLC and LfH-mNLC in BCECs (B) for different concentrations of C6 at 37°C or 4°C (n = 3), (C) at a dose of

611

100 ng/mL of C6 at different time at 37 °C (n =3), and (D) at a dose of 100 ng/mL of C6 in the presence of

612

excess free Lf (10 mg/mL) at 37 °C (n = 3). Data are expressed as mean ± SD. # P < 0.05 compared with NLC.

613

◆

615

d

te

P < 0.05 compared with LfM-mNLC.

Ac ce p

614

M

609

31

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ip t cr us an M

615

Fig. 4. Intracellular integrity assessment of Dil and Dio loaded NLC and LfH-NLC after incubation with

617

BCECs at 37 °C between 1 h and 8 h by monitoring the FRET phenomenon using CLSM.

te Ac ce p

618 619

d

616

32

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ip t cr

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Fig. 5. Plasma concentration–time profiles of Cur in rats after intravenous administration of Cur solution, Cur-loaded NLC and LfH–mNLC at a dose of 10 mg/kg of Cur (n=5).

Ac ce p

619 620 621 622

33

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ip t cr us an

622

Fig. 6. (A) Whole body fluorescence images of SD mouse after intravenous injection of DiR-loaded NLC

624

and LfH–mNLC (0.5 mg/kg). (B) Fluorescence images of excised brain and other organs at 24 h

625

post-injection of DiR-loaded NLC and LfH–mNLC. (C) The fluorescence intensity of DiR in brain and other

626

organs at 24 h post-injection of DiR-loaded NLC and LfH–mNLC. Data are shown as mean ± SD (n = 3).

627

P<0.05 versus NLC .

629 630

d

te

◆

Ac ce p

628

M

623

34

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ip t cr us

630

Fig.7.

The coronal slices of the mouse brain. (A) Distribution of NLC and LfH–mNLC in the third ventricle and

632

cortex. The green fluorescence signals of C6 were visualized using the FITC filter of brain sections 1 h

633

after i.v. injection. The cell nuclei were stained with 5 μg/mL DAPI for 20 min and visualized using the

634

UV filter (100×). (B) Fluorescence intensity of C6 in the third ventricle and cortex was measured and

635

analysed using Image J software. Data are shown as mean±SD (n = 3).

M

d

P<0.05 versus NLC.

te

638

◆

Ac ce p

636 637

an

631

35

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638

Table 1A

639

Effects of different amounts of S100-COOH on particle size, PI, zeta potential, and EE of Cur-loaded NLC.

640

Data were presented as the mean±SD (n=3). Particle size

S100-COOH

Zeta potential PI

(nm)

EE(%)

(mv)

(mmoL)

ip t

Added amounts of

163.4±2.8

0.17±0.017

-3.56±1.05

91.57±0.87

0.002

119.4±1.1

0.12±0.010

-6.95±0.72

0.004

113.7±2.7

0.15±0.012

0.008

105.7±1.8

0.16±0.037

0.012

92.4±0.9

0.17±0.012

-16.87±1.91

96.74±0.95

0.020

74.7±0.7

0.26±0.023

-16.94±1.82

87.65±1.30

cr

0

us

90.39±2.51

92.09±0.39

-13.90±0.43

94.05±1.50

M

an

-8.90±1.32

641 Table 1B

643

Effects of different amounts of Lf on particle size, PI, zeta potential, EE, and DL of Cur-loaded NLC

644

coated with 0.012 mmoL of S100-COOH. Data were presented as the mean±SD (n=3). Preparations

Lf (mg/mL)

te

d

642

Particle size

Zeta potential

PI

Ac ce p

(nm)

NLC

LfL–mNLC

LfM–mNLC LfH–mNLC 645

0

0.5

1.5

2.5

EE(%)

DL(%)

(mv) 96.74±0.95

92.4±0.9

0.17±0.012

-16.87±1.91

2.65±0.23

99.7±1.6

0.20±0.014

-17.90±0.64

-

-

100.9±1.4

0.17±0.020

-12.94±0.62

-

-

103.8±0.6

0.15±0.022

-5.80±0.73

96.51±1.87

2.60±0.17

-: no detection

646 647

Table 1C

648

Pharmacokinetics parameters of Cur after intravenous administration of Cur solution, Cur-loaded NLC and

649

LfH-mNLC at a dose of 10 mg/kg of Cur to rats. Data are presented as the mean±SD (n=5). Preparations

Parameters 36

Page 36 of 38

t1/2 (h)

MRT(h)

AUC0-1

Clearance (L/h)

(ng×h/mL) Cur solution NLC LfH-mNLC

117±10.2

1.31±0.06

*

296±11.6

*

1.16±0.14

*

181±14.6

*

0.41±0.04

6.45±2.63

*

11.08±0.89*

1. 84±0.03 1.24±0.06

17.7±2.00

*

*P<0.05 versus Cur Solution

ip t

650

0.07±0.04

651

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cr

652

37

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ip t

652

cr

653

us

654

Ac ce p

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M

an

655

38

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