pH-Responsive Polyethylene Glycol Monomethyl Ether-ε-Polylysine-G-Poly (Lactic Acid)-Based Nanoparticles as Protein Delivery Systems

Huiqin Liu; Yijia Li; Rui Yang; Xiujun Gao; Guoguang Ying

doi:10.1371/journal.pone.0159296

Abstract

The application of poly(lactic acid) for sustained protein delivery is restricted by the harsh pH inside carriers. In this study, we synthesized a pH-responsive comb-shaped block copolymer, polyethylene glycol monomethyl ether-ε-polylysine-g-poly (lactic acid) (PEP)to deliver protein (bovine serum albumin (BSA)). The PEP nanoparticles could automatically adjust the internal pH to a milder level, as shown by the quantitative ratio metric results. The circular dichroism spectra showed that proteins from the PEP nanoparticles were more stable than those from poly(lactic acid) nanoparticles. PEP nanoparticles could achieve sustained BSA release in both in vitro and in vivo experiments. Cytotoxicity results in HL-7702 cells suggested good cell compatibility of PEP carriers. Acute toxicity results showed that the PEP nanoparticles induced no toxic response in Kunming mice. Thus, PEP nanoparticles hold potential as efficient carriers for sustained protein release.

Citation: Liu H, Li Y, Yang R, Gao X, Ying G (2016) pH-Responsive Polyethylene Glycol Monomethyl Ether-ε-Polylysine-G-Poly (Lactic Acid)-Based Nanoparticles as Protein Delivery Systems. PLoS ONE 11(7): e0159296. https://doi.org/10.1371/journal.pone.0159296

Editor: Bing Xu, Brandeis University, UNITED STATES

Received: March 18, 2016; Accepted: June 30, 2016; Published: July 28, 2016

Copyright: © 2016 Liu et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Data Availability: All relevant data are within the paper and its Supporting Information files.

Funding: This study was supported by the National Program on Key Basic Research Project (973 Program, Grant no. 2011CB933100), National Program on Key Basic Research Project (973 Program, Grant no.2012CB932503), National Nature Science Foundation of China (Grant no. 30772528, NSFC81072158), China Postdoctoral Science Foundation (Grant no. 2012M510071), Natural Science Foundation of Tianjin (Grant no. 13JCQNJC14300), and Ph.D. Programs Foundation for New Teachers of Ministry of Education of China (Grant no. 20121202120021). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Competing interests: The authors have declared that no competing interests exist.

Introduction

From 1980s, FDA has approved above 400 biopharmaceuticals. Nowadays, biopharmaceuticals are becoming the leading therapeutics owing to their clinical and commercial success. Peptides and proteins are of a large class of biopharmaceuticals under investigation [1]. Poly(lactic acid) (PLA) and poly(lactic-co-glycolic acid) (PLGA) are approved for human use as sustained release drug delivery systems [2]. However, application of these compounds is limited by several protein-damaging factors [3, 4]. For example, the acidic microclimate inside these types of carriers negatively affects encapsulated proteins [5, 6].We previously designed PLGA derivatives to neutralize the acidic microenvironment in PLGA. However, drawbacks caused by the acidic microenvironment in PLA carriers persist.

PLA-based drug delivery systems exhibit certain unique properties that may be advantageous under various physiological conditions, compared with PLGA-based systems. For example, PLA exhibits higher hydrophobicity than PLGA, which leads to different degradation characteristics. The degradation and erosion of PLA are also more time consuming than those of PLGA, so PLA can be effectively used for prolonged drug release [7]. The release properties, especially the release time, of carriers derived from PLA derivatives can be accurately adjusted to fulfill special requirements. Such tailorable features are always desirable in biomedical applications, which can require release kinetics ranging from several days to as long as 6 months.

We have designed a novel strategy to improve protein stability within PLA-based nanoparticles (NPs). Hydrophilic or cationic materials were introduced to neutralize the acidic conditions that accompany the hydrolysis of PLA, thereby stabilizing several encapsulated proteins [8, 9]. This study was performed to prepare comb-shaped amphiphilic polyethylene glycol monomethyl ether-ε-polylysine-g-poly(lactic acid) [CH3-PEG-EPL-g-PLA;PEP] to form pH-responsive PLA-based NPs for protein delivery.

Materials and Methods

Materials

PLA (molecular weight (M_W): 8.0 kDa) was obtained from Jinan Daigang Biomaterial Co., Ltd. (Jinan, China). ε-polylysine (EPL) (M_W, 4.08 kDa) was obtained from Fanqing Biochemical Co., Ltd. (Peking, China). Methoxypolyethylene glycol amine (CH3-PEG-NH₂; M_w, 1.1, 2.1, 5.1, and 10.1 kDa) was obtained from Shanghai Rebone Biomaterials Co., Ltd. (Shanghai, China). The fluorescent pH-sensitive dye, SNARF-1(R) dextran (M_W,10 kDa), was obtained from Shanghai Haoran Bio Technologies Co., Ltd. 1-Ethyl-(3-3-dimethylaminopropyl) carbodiimide hydrochloride (EDC∙HCl), 1-hydroxybenzotrizole (HOBt), fluorescein isothiocyanate (FITC), 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazoliumbromide (MTT), di-tert-butyl dicarbonate (BOC), trifluoroacetic acid, and hematoxylin and eosin (H&E) were obtained from Sigma. Propofol was purchased from Tianjin Lianxing Bio Technologies Co., Ltd. Bovine serum albumin (BSA; M_W, 67 kDa) and a BCA protein assay kit were obtained from Junyao Weiye Biochemical Co., Ltd. (Peking, China). Micropore filters and ultrafiltration tubes were obtained from Tianjin Lianxing Bio Technologies Co., Ltd. The dialysis bags were obtained from Shanghai Green Bird Sci. and Tech. Co., Ltd. Other reagents were obtained from business companies. All animals were purchased from Tianjin Aoyide Experimental Animal Technology Co., Ltd.

PEP Preparation & Characterization

We synthesized the functional PEP copolymers via classical amide bond forming reactions as described previously [10]. For BOC-protected EPL (BOCEPL), the BOC groups protected the primary amines of EPL. BOCEPL-PEG-CH3 was obtained using EDC∙HCl and HOBt to link CH3-PEG-NH₂ and BOCEPL. EPL-PEG-CH3 was obtained by BOC deprotection of BOCEPL-PEG-CH3 using trifluoroacetic acid. The coupling reaction of PLA with EPL-PEG-CH3 was performed using HOBt and EDC∙HCl to yield the final product CH3-PEG-EPL-g-PLA (PEP). ¹H NMR spectroscopy (Bruker Avance III 400) was used to determine the copolymer structure and the result was shown in S1 Fig.

The polydispersity and M_w of PEP were determined by gel permeation chromatography (GPC) [11] using a Waters system (Waters, USA) that included a Waters 600 E pump. The flow rate of the pump was 1.0 mL/min, while the columns (PL-M-B) were kept under 50°C. To prepare samples, we dissolved the material in DMF (10 mL) and then filtered it (0.22 μm). We measured the M_w of PEP using polystyrene standards.

NP Structure, Zeta Potential, and Size

We employed nanoprecipitation to prepare NPs [10]. DMF (10 mL) was used to dissolve PEP (concentration: 10 mg/mL). Double distilled water (DDW) (100 mL) was used to dissolve BSA (concentration: 0.4 mg/mL). Then, the PEP solution was added to the aqueous phase drop wise, and the mixture was stirred for 15 min. The mixtures were dialyzed against DDW (5,000 mL) for 48 h at 4°C to obtain the final NP solution. The abovementioned method was also used to produce blank NPs in the absence of BSA. Then, the obtained NP solution was freeze-dried and stored under 4°C.

We performed transmission electron microscopy (TEM) using a Hitachi HT7700 instrument. One NP drop was put onto a copper grid of 200 meshes to equilibrate. We removed the water from the copper grid after NPs deposition using a filter paper before loading into the microscope.

We used Zetasizer 3000 HS (Brookhaven) to measure the zeta potential of the NP sat 37°C. The NP size and polydispersity were detected through dynamic light scattering (Brookhaven, INNDVO300/BI900AT). X-ray photoelectron spectroscopy (XPS) was used to examine the chemical composition of NP shaving PEG of different M_w.

Lyophilized NPs were subsequently re-suspended in 1.0 mL D₂O for ¹H NMR analysis (determination of surface composition of NPs).

NP Water Absorption and Degradation

We measured the water absorption of the PEP NPs using previously described procedures [10]. Approximately 20mg of dried sample was added to phosphate buffered saline (PBS, 0.1 M, pH 7.4) at37°C. The product obtained after 48 h was cautiously blotted off between tissue paper sheets. The sheets were weighed with an electronic microbalance (AE 240, Mettler, Switzerland) (accuracy: ±0.01 mg). We computed the proportion of water absorption according to the following formula: (1) where W_w is the swollen sample weight, and W_d represents original weight. The experiment was repeated three times, and the data are represented as the mean values ± the standard error.

The residual weight was computed as follows: (2) where Wi represents original sample weight and Wc represents constant weight after drying at different time points.

BSA Release and Kinetics

Approximately 20 mg of BSA-loaded NPs was soaked in 5 mL of PBS (0.1 M, pH 7.4) and maintained at 37°C with horizontal shaking. Then, 100μL aliquots of the sample were transferred into an ultrafiltration tube at different time points and centrifuged at 8,000 rpm for 15 min. We then removed the liquid and resuspended the sample with 100 μL of PBS.A BCA protein assay was employed to detect BSA in the supernatant after centrifugation. We examined the samples in triplicate for each test.

The mechanism of PEP NP protein release was evaluated using two models, namely, the Ritger–Peppas and biexponential equations.

Model 1 was established using the Ritger–Peppas equation: (3) where M_t/M_∞ denotes the ratio of released drug, K_RP represents the geometric shapes of the carrier, t indicates the release time, and n denotes the release exponent relevant to the mechanism of drug release. Fickian diffusion is observed when n≤ 0.43 for drug release from spherical matrices. When the value of n was between 0.43 and 0.85, the mechanism of drug release is described as non-Fickian (anomalous) [12].

The following formula describes Model 2, which is suitable for the release data in this study: (4) where k₁ and k₂represent the first-order rate constants, and a₁ and a₂ are the percentages of the BSA on the outer layer and inside the NPs, respectively[13].

We used adjusted coefficient of determination (R²_adjusted) to identify whether the model could properly described the release data. The adjusted coefficient of determination was considered to best explain the data.

(5)

Biocompatibility of PEP NPs

MTT was employed to measure the viability oftheHL-7702 cells. The viability of each cell was computed as below: (6) where Abs_test represents the amount of formazan in the cells with NP administration, and Abs_control represents the amount of formazan in the controlled cells (with no NP treatment).

We assessed acute toxicity of PEP NPs and EPL using male and female Kunming mice weighing 20–25 g each (7–8 weeks) after tail vein injection according to our previous study [10].

We then conducted an exploratory assay to investigate the dose range for determining the LD50 of PEP and PLA NPs. The exploratory assay was performed in 30 mice. We randomly assigned the mice into three groups (labeled as A, B, and C), each of which contained 10 animals. The doses of the PEP and PLA NP solutions, which were diluted in a sodium chloride (NaCl) solution (0.9%), were 12 mg/mL and 3 mg/mL, respectively. These doses were the highest concentrations of the PEP and PLA NPs prepared with nanoprecipitation. The experimental groups (A and B) were treated with continuous intravenous administrations of PEP and PLA NP solutions for 12 h (0.3 mL/h), respectively. The control mice were treated with continuous administration of a NaCl solution (0.9%) intravenously for 12 h (0.3 mL/h). We observed the mice for 14 days with an interval of six hours to evaluate their mortality and physiological behaviors. No deaths were observed in the animals administered with PEP and PLA NPs. Thus, theLD50 of PEP and PLA NPs could not be determined.

The aforementioned method was also used to detect the acute toxicity of EPL. However, the continuous intravenous treatment was replaced with a single administration of EPL solution intravenously. We randomly assigned the mice into seven groups (labeled as A, B, C, D, E, F, and G), each of which contained 10 animals. EPL was diluted in a NaCl solution (0.9%), with doses of 450.0, 383.0, 321.9, 270.5, 227.3, and 191.0 mg/kg for the experimental groups (A, B, C, D, E, and F). The animals in the experimental groups received a one-time administration of EPL solution (0.2 mL) intravenously. The control mice were treated with a one-time administration of 0.2 mL of a NaCl solution (0.9%) intravenously.

The animals were sacrificed on the 14^th day following intravenous injection in the acute experiment. Kunming mice were euthanized with carbon dioxide. Carbon dioxide was introduced into the box slowly. When the concentration of carbon dioxide reached to 99.9%, carbon dioxide was introduced continually into the box for 10 minutes. Then, the carcasses were sterilized by 75% ethanol and were transferred to the laminar flow bench for dissection. Three internal organs, namely, the liver, kidney, and spleen, were acquired from each animal. The tissues were immediately fixed in 10% formalin and dehydrated for paraffin wax embedding. We sectioned each embedded specimen and stained them with H&E. The images were visualized with an Olympus IX71 microscope.

All the animals received humane care in strict accordance with the Regulations for the Administration of Affairs concerning Experimental Animals (Tianjin, revised in June 2004), which conforms to the Guide for the Care and Use of Laboratory Animals published by the US National Institutes of Health (NIH Publication no. 85–23, revised 1996).

Mapping of Microclimate pH within PEP and PLA NPs

We used a ratio metric method to map the pH within NPs according to previous descriptions [10].We used anAr/He laser to excite the encapsulated fluorescent dye (SNARF-1 dextran) at 488 nm and acquired the data I₆₄₀/I₅₈₀,the relationship of the ratio (I₆₄₀/I₅₈₀) and pH was obtained from a standard curve. All detection was performed with a 63× oil immersion objective.

Secondary Structural Stability of Released Protein

BSA-loaded NPs (100 mg) were dispersed in 2 mL of sterilized DDW. The solution was transferred into 5 mL ultrafiltration tubes (100 kDa cutoff) at specified time intervals and centrifuged at 4°C (8,000 rpm, 30 min). We employed a BCA protein colorimetric assay to evaluate the protein release concentration. The NPs were re-dissolved in 2 mL of sterilized DDW for continued release. The stability of the released protein (with the same concentration as that in the DDW) from the NPs was assessed by measuring the CD spectra on a Jasco-715 Spectropolarimeter (JASCO, Tokyo, Japan) at 37°C with constant nitrogen gas flow. The spectra showed the average of 8–20 scans, and CD intensities were represented as mdeg.

Distribution and Pharmacokinetics of NPs

The tests on the carriers were performed using 50 Kunming mice (25 male and 25 female), with a weight of 20–25 g each (7–8 weeks). We randomly assigned the mice into five groups (labeled as A, B, C, D, and E), with 10 animals in each group.

Testing solutions containing BSA-FITC-loaded PEP NPs (group A), blank PEP NPs as the control of the PEP NPs loaded with BSA-FITC (group B), BSA-FITC-loaded PLA NPs (group C), blank PLA NPs (as the control of the BSA-FITC-loaded PLA NPs; group D), and free BSA-FITC (group E) were used in the in vivo experiments. The experimental groups were given one-time administrations of the testing solutions (0.4 mL) intravenously. Simultaneously, the control group (group E) animals were injected with 0.4 mL of a NaCl solution (0.9%).

We anaesthetized the mice by peritoneal injection of propofol (15 mg/kg). Blood was drawn from abdominal aorta, 0.2 mL each time. Blood was drawn from each animal for in vivo BSA-FITC examination. The blood solution was mixed with heparin was centrifuged at 5,000 rpm for 10 min at 25°C. Afterward, 100 μL of plasma samples were acquired, diluted to 3 mL with 0.9% NaCl solution, and evaluated by fluorescence spectroscopy (Ls55, Perkin Elmer).

The amounts of BSA-FITC that accumulated in the liver, kidney, and spleen tissues were also detected. The animals were euthanized (the method was shown in “Biocompatibility of PEP NPs”), and their livers, kidneys, and spleens were collected at different time points (1 hour, 2 hours, 4 hours, 8 hours, 16 hours, 32 hours, 64 hours, 128 hours, 256 hours and 384 hours, respectively). After three washes with physiological saline, the organs were blotted off cautiously between tissue paper sheets. The sheets were weighed on an electronic microbalance and transferred to homogenizers to obtain the tissue homogenates. Subsequently, the homogenates were diluted with 1 mL of physiological saline, transferred into a 15 mL centrifuge tube, and then centrifuged at 8,000 rpm for 30 min at 4°C. The supernatants were collected, and precipitates were washed twice with 1 mL of physiological saline. The supernatants were combined and diluted to 5 mL with physiological saline. Impurities were removed with 0.22 μL micropore filters. The BSA-FITC concentrations were measured by fluorescence spectroscopy.

The amounts of BSA-FITC in the blood and organs (livers, kidneys, and spleens) were determined using a linear standard calibration curve.

The AUC_t0-t value was measured by assessing the area under BSA-FITC curves between t₀ and t according to the trapezoidal rule [14].

Statistical Analysis

All data are expressed as the mean ± standard deviation. Significant differences were assessed with at-test and are significant when P<0.05.

Results and Discussion

PEP Preparation and Characterization

The number of PLA chains grafted onto EPL-PEG-CH3 increased with an increase in the feed ratio of PLA to EPL-PEG-CH3 (Table 1). This indicates a steric effect between free PLA and PLA-g-EPL-PEG-CH3. For similar reaction times, the degree of PLA grafting was most affected by the feed ratio of PLA to EPL-PEG-CH₃. The¹H NMR spectrum of PEP is displayed in Fig 1a. The peak at δ 2.5ppm was assigned to residual protonated DMSO (DMSO-d6). The peak at δ 3.5 was attributed to the methylene protons of PEG. The peaks at δ 1.3–1.8, 3.3, and 3.9 were attributed to C_δH₂-C_γH₂-C_βH₂, C_εH₂, and C_αH of EPL, respectively. The peaks at δ 5.2 and 1.4 were attributed to the methine and methyl protons of PLA, respectively.

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Table 1. Materials prepared with reagents of different molar ratios.

https://doi.org/10.1371/journal.pone.0159296.t001

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Fig 1. Structure of the amphiphilic comb-shaped copolymer PEP and biodegradation properties of PEP nanoparticles.

(a) 1H-NMR spectrum of PEP in DMSO-d6; (b) 1H-NMR spectrum of PEP NPs in D2O; (c) chemical composition percentages of azote on the surface of different NPs; (d) Biodegradation properties of PEP and PLA NPs in PBS (0.1 M, pH 7.4) at 37°C.

https://doi.org/10.1371/journal.pone.0159296.g001

GPC was performed to confirm the M_w and structures of the copolymers (Table 1). The product PEP52, comprised of two PLA chains grafted onto one EPL-PEG-CH₃ molecule, was obtained using a feed ratio of 1:4.5 (EPL-PEG-CH₃ to PLA). The M_w of EPL-PEG-CH₃ was 9.2 kDa (i.e., 4.1 kDa + 5.1 kDa). The M_w of the final, conjugated material was approximately 25.1 kDa after attachment of PLA (8.0 kDa)onto EPL-PEG-CH₃. This value was 15.9kDa (≈ 8.0 × 2 kDa) higher than that of the original EPL-PEG-CH₃.Correspondingly, materials containing 3 and 4 PLA grafted chains per EPL-PEG-CH3 molecule were obtained using EPL-PEG-CH₃ to PLA feeding ratios of 1:5.7 (for PEP53) and 1:8.4 (for PEP54), respectively. These results verified that theEPL-PEG-CH₃ to PLA feed ratio was the determining factor of the degree of PLA grafting.

Structure of NPs

The transmission electron micrographs in Fig 2 show PEP NPs with fine spherical shapes and aggregation. We used XPS to explore the nitrogen component percentage on the surface of blank NPs with different PEG M_w to observe whether the constructed carriers contained cores with PEG coating (Fig 1c).

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Fig 2. TEM image of PEP NPs.

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We could detect just 2.68% nitrogen from the blank NPs (PEP02), which did not contain a PEG segment. This value significantly decreased with increasing M_w values of PEG. The XPS results detected no nitrogen for the products with PEG M_w higher than 5 kDa. These findings revealed that the PEG segments resided on the NP surface, with the PLA intertwining with EPL to form the NP core. Table 2 illustrates that the PEP NPs zeta potential was reduced from 48.62 to 21.17 mV with increasing PEG M_w (0–10 kDa), and the size was enlarged from 84.55 to 130.57 nm. The above findings confirmed that the PEG segments surrounded the core.

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Table 2. WU, LC, zeta potential, and particle size of NPs.

https://doi.org/10.1371/journal.pone.0159296.t002

In order to further confirm whether PEP nanoparticles were coated with PEG shell, Lyophilized NPs were re-suspended in 1.0 mL D₂O for ¹H NMR analysis. In the NPs spectrum, PEG signals were clearly observed. However, the signal from PLA and EPL could not be seen. These results further suggested that PLA might intertwine with EPL blocks forming the core, and PEG segments formed the corona of the nanoparticles (Fig 1b).