Water-soluble lanthanide coordination polymers particles with white-light emission and color tuning

Water-soluble polymer particles (PPs) with strong fluorescence emission were prepared from hyperbranched poly(ethylenimine) (PEI) and terpyridine-bearing aldehyde (TPy) via Schiff base reaction and self-assembly in aqueous phase. TPy/PEI PPs were then used to develop a series of luminescent lanthanide coordination polymers particles (Ln-CPPs). The optical properties of these Ln-CPPs are readily modulated over a wide spectrum in water systems. Finally, water-soluble white-emitting Ln-CPPs were achieved by controlling the lanthanide ion stoichiometry. This Ln-CPPs design approach offers a robust pathway for white-luminescent materials in water systems.

Water-soluble polymer particles (PPs) with strong fluorescence emission were prepared from hyperbranched poly(ethylenimine) (PEI) and terpyridine-bearing aldehyde (TPy) via Schiff base reaction and self-assembly in aqueous phase.

In recent decades, dynamic metal coordination polymers (M-CPs) have attracted great interest in catalysis, drug delivery, chemical sensors and bioanalysis applications.^1–7 M-CPs are constructed from metal ions and organic ligands with a variety of structures and interesting properties for many potential applications. M-CPs acting as chemical sensors are mainly explored by making use of their luminescence properties.^8–10 The luminescent M-CPs can emit a stable and intense luminescent emission, so some substances can be detected by observing changes in luminescence intensity. It is well known that lanthanide ions have high color purity and long lifetime excitation lifetime, and the emission covers the entire visible range of 400 to 700 nm. In particular, Eu(iii) and Tb(iii) ions can emit intense red and green light, respectively. Lanthanide coordination polymers (Ln-CPs) are promising luminescent materials because lanthanide ions have similar chemical properties and two or more lanthanide ions can be randomly distributed in coordination polymers with metal sites, which can modulate the color and brightness of the emission.¹¹ For the above reasons, Ln-CPs have attracted the attention of many scientists and have been effectively used to design multiple color and white light emitting materials. For example, He and co-workers¹² developed a new fluorophore that exhibits white light by combining an Eu(iii) moiety (red emission) with an organic ligand (blue and green emission). Ma et al.¹³ reported a white-light-emitting La(iii)/Tb(iii)/Eu(iii) coordination polymers based on combination of blue-emitting ligand/La(iii), green-emitting Tb(iii) and red-emitting Eu(iii) units. Song et al.¹⁴ developed a white-light-emitting compound by doping a Eu(iii) ion into the Gd(iii) framework.Meanwhile, the selection of suitable ligands plays a crucial role in the synthesis of Ln-CPs with good luminescent properties, since organic ligands can be used not only as building blocks for the construction of new backbones of Ln-CPs, but also as effective sensitizer for Ln(iii) ions.^15,16 However, ligands are generally poorly water soluble, which limits the practical sensing application in environmental and biological systems.¹⁷ An efficient strategy to promote dispersion in water is to prepare Lanthanide coordination polymer particles (Ln-CPPs) by miniemulsion method, reprecipitation method, and so on.¹⁸ Nevertheless, several drawbacks still exist for their preparation and application, such as sophisticated multistep synthetic pathways, use of environmentally unfriendly organic solvents, and the possibility of fluorescence self-quenching in aqueous solution. Therefore, the systematic investigation of water-soluble Ln-CPPs with white-light emission is quite rare. More research studies are urgently needed to accelerate the development of white-light luminescent Ln-CPPs in the water system.Based on the above considerations, we rationally designed water-soluble polymer particles with blue emission and selected Tb(iii)/Eu(iii) to construct white-light-emitting Ln-CPPs (Fig. 1). The water-soluble polymer particles were constructed from hyperbranched poly(ethylenimine) (PEI) and terpyridine-bearing aldehyde (TPy) via Schiff base reaction and self-assembly. Structural characterization and luminescence properties in the water system of Ln-CPPs are studied in detail. An important clue could be obtained from the result that Ln-CPPs constructed by terpyridine ligands can maintain their structural and luminescent properties in the water system. This research also provides a basis for realizing the controllability of water-soluble white-light-emitting Ln-CPPs in the future.Open in a separate windowFig. 1Schematic preparation of TPy/PEI PPs and Ln(III) coordination-based luminescent polymer particles (Ln-CPPs) under UV light (λ_ex = 365 nm).Synthesis of the TPy/PEI PPs is based on facile Schiff base reaction, which refers to the reaction between primary amine on PEI and aldehyde group on TPy, resulting in a product containing C N bonds. Moreover, the diluted TPy/PEI PPs solution emits blue fluorescence under a 365 nm UV lamp. Fig. 2A displays the fluorescence excitation and emission spectra of the TPy/PEI PPs solution, and the maximum excitation and emission wavelengths are 330 and 448 nm, respectively. The UV-vis absorption spectra of TPy/PEI PPs, PEI and TPy were shown in Fig. S4.^† Compared with TPy, the absorption peak at 250 nm in TPy/PEI PPs solution is weakened, which may be due to the decolorization effect caused by the formation of copolymer by TPy and PEI. In addition, the absorption peak at 335 nm in TPy/PEI PPs solution is attributed to n → π* transitions of C N bonds.^18,19 These phenomena indicated TPy/PEI PPs were a newly generated subject.Open in a separate windowFig. 2(A) Fluorescence excitation and emission spectra of TPy/PEI PPs (0.01 g mL⁻¹). (Inset) Photographs of TPy/PEI PPs under visible light and UV light of 365 nm. (B) FT-IR spectra of TPy/PEI, PEI, and TPy.The morphologies of TPy/PEI PPs were characterized by transmission electron microscopy (TEM), Fig. S5A^† is a TEM image and reveals that the TPy/PEI PPs are monodisperse spherical shape with the size distribution in the range of 26–50 nm. Formation of water-soluble nanoparticles is due to the following factors. In TPy/PEI copolymer, ample amine groups and pyridinium groups are hydrophilic, whereas Schiff base bonds are hydrophobic. As a result, the hyperbranched structure of TPy/PEI copolymer tends to fold and collapse, shrinking and self-assembling into uniform polymer nanoparticles in aqueous medium.¹⁸ Many hydrophilic groups on the surface of TPy/PEI PPs make the excellent water dispersity possible. To further explore the chemical composition of TPy/PEI PPs, we performed FT-IR spectra of PEI, TPy, and TPy/PEI PPs (Fig. 2B). Several featured vibration bands at 3284 and 1590 cm⁻¹ in PEI are associated with the stretching vibration of N–H bond, and their intensity is decreased in TPy/PEI PPs, which indicates that some amine groups have reacted with TPy. In addition, another remarkable new peak at 1630 cm⁻¹ was observed in TPy/PEI PPs, which can be assigned to the C N bond.^20–25 Meanwhile, a new peak at 8.37 ppm was observed in the ¹H NMR spectra of TPy/PEI PPs (Fig. S6^†), which can be assigned to N CH protons.²⁶ The monitoring of the aldehyde conversion into imine units can be carried out by measuring the CH̲O/CH̲ N integral ratio, and the conversion rate of the aldehyde into imine units is 69%. The estimation of the conversion rate from the ¹H-NMR spectrum agrees well with the calculation from the weighting measurements with a conversion rate of 73%. These analysis results well demonstrated the formation of Schiff base bonds between TPy and PEI.TPy/PEI PPs possess intrinsic fluorescence, good water solubility, and functional terpyridine structure unit, allowing us to incorporate the Ln(iii)-TPy coordination complexes into polymer networks. With the incremental addition of Tb(NO₃)₃ to the TPy/PEI PPs solution (2% v/v), the TPy : Ln ratio is 2 : 1, which produces green-luminescent Ln-CPPs, GL CPPs (τ = 0.35 ms, Φ = 4.3%, CIE coordinates (0.27, 0.36), Fig. S7, S8 and Table S1^†). In the corresponding emission spectrum, a decrease in the luminescence intensity of the ligand centred emission band at 448 nm with the concomitant emergence of sharp bands at 489 nm, 544 nm, 583 nm, and 622 nm was observed (Fig. S7^†). A decrease in the luminescence intensity of the central emission band of the ligand was observed. These emission bands were assigned to ⁵D₄–⁷F₆, ⁵D₄–⁷F₅, ⁵D₄–⁷F₄, and ⁵D₄–⁷F₃ based transitions, respectively, for Tb(iii).^27–30 A similar procedure was observed upon addition of Eu(NO₃)₃ to the TPy/PEI PPs solution with the occurrence of five characteristic Eu(iii)-based emission bands having maxima at 579 nm (⁵D₀–⁷F₀), 592 nm (⁵D₀–⁷F₁), 617 nm (⁵D₀–⁷F₂), 649 nm (⁵D₀–⁷F₃), and 687 nm (⁵D₀–⁷F₄), resulting in a clear red-luminescent Ln-CPPs, RL CPPs (τ = 0.81 ms, Φ = 11.3%, CIE coordinates (0.52, 0.29)). These emission spectra demonstrate that Ln³⁺ (Eu³⁺ or Tb³⁺) ions were successfully doped to the TPy/PEI PPs. More importantly, strong fluorescence could still be detected even after these Ln-CPPs were stored for over a week, implying that the coordination between the TPy/PEI PPs and Ln³⁺ ions is very stable. The interactions between the TPy/PEI PPs and Ln³⁺ ions were further monitored by FT-IR spectroscopy (Fig. S9^†). Strong absorbent bands at 3256, 1549 and 1398 cm⁻¹ in TPy/PEI PPs are attributed to the stretching vibrations of N–H bond.^18,19 After the formation of RL CPPs, GL CPPs or WL CPPs using Ln³⁺ ions, a dramatically red shift appeared, which indicated the coordination of the TPy/PEI PPs to Ln³⁺ ions. The medium-to-weak bands at 760 cm⁻¹ for RL CPPs, 769 cm⁻¹ for GL CPPs and 765 cm⁻¹ for WL CPPs are observed as additional evidence of the Ln–N formation.³¹Next we investigated how to modulate the emission of polymer particles by adjusting the stoichiometry of the two lanthanide chromophores. Titration of the Tb/Eu molar ratio resulted in a series of Ln-CPPs with a broad spectrum of emission under UV irradiation (Fig. 3A). By testing the emission spectrum (Fig. 3B and C), it was found that the intensity of the green band at 544 nm increased gradually at the expense of the intensity of the red band at 616 nm as a function of Tb/Eu molar ratio. Interestingly, an intense white-luminescent Ln-CPPs, WL CPPs (CIE coordinates (0.33, 0.34)), were observed when the Eu/Tb molar ratio was 1 : 4. The smart illumination control strategy here provides a simple design approach for broad-spectrum color adjustment of luminescent polymer materials.Open in a separate windowFig. 3Luminescence tuning: (A) photographs of Ln-CPPs under UV irradiation, corresponding CIE coordinates are mentioned below; (B) emission spectra (λ_ex = 330 nm) of Ln-CPPs and (C) Job''s plot showing the peak emission intensity of the red band at 544 nm and green band at 616 nm as a function of the Tb/Eu molar ratio (1 : 1, 2 : 1, 3 : 1, 4 : 1, 5 : 1, 6 : 1, 7 : 1, and 8 : 1).In conclusion, we created polymer particles with blue emission from PEI and TPy via Schiff base reaction and self-assembly under mild conditions. The structural characterization and the fundamental properties of the TPy/PEI PPs have been studied. Because of the specific structure, the TPy/PEI PPs exhibit excellent water solubility. Furthermore, we have used the TPy/PEI PPs to develop a series of luminescent Ln-CPPs with Eu(iii), Tb(iii), and mixed Eu(iii)/Tb(iii) in aqueous medium. The individual Ln-CPPs exhibited bright red (Eu-CPPs) and green (Tb-CPPs) fluorescence upon exposure to UV light (λ_ex = 365 nm). Careful tuning of the stoichiometric ratio of Eu(iii) and Tb(iii) helped in achieving water-soluble white-emitting Ln-CPPs, which could offer a suitable pathway for preparing white-luminescent materials in water systems. Due to their stability in water, in our next work efforts will be focused on exploring their potential applications in biological and environmental areas as luminescence sensing and quantitative detection materials.     

One‐Step Preparation of Reduction‐Responsive Biodegradable Polymers as Efficient Intracellular Drug Delivery Platforms

Reduction‐responsive biodegradable polymeric micelles based on functional 2‐methylene‐1,3‐dioxepane (MDO) copolymers are developed and investigated for triggered doxorubicin (DOX) release. The MDO‐based copolymers P(MDO‐co‐PEGMA‐co‐PDSMA) are synthesized via the simple one‐step radical ring‐opening copolymerization of MDO, poly(ethylene glycol) methyl ether methacrylate (PEGMA), and pyridyldisulfide ethylmethacrylate (PDSMA). The copolymers can self‐assemble to form micelles in aqueous solution. DOX, a model anticancer drug, is loaded into the micelles with the drug loading content (DLC) of 11.3%. The micelles can be disassembled under a reductive environment (10 × 10^?3m glutathione), which results in a triggered drug release behavior. The glutathione‐mediated intracellular drug release of DOX‐loaded micelles is investigated against A549 cells. Confocal laser scanning microscopy (CLSM) results demonstrated that DOX‐loaded micelles exhibits faster drug release in glutathione monoester (GSH‐OEt)‐pretreated A549 cells, compared with untreated and buthionine sulfoximine (BSO)‐pretreated A549 cells. Based on the facile synthetic strategy, the reduction‐sensitive biodegradable micelles with triggered intracellular drug release are promising for anticancer drug delivery.

     

The Interaction Between Amphiphilic Polymer Materials and Guest Molecules: Selective Adsorption and Its Related Applications

The interaction between amphiphilic polymer materials and molecules such as drugs, proteins, and DNA plays one of the key roles for the applications in separation, delivery of drugs, biosensors, and tissue engineering. Thus, the fundamental investigation of this interaction is necessary before some polymer materials can be designed for practical applications. Here, various factors are discussed to determine the interactions between amphiphilic polymer materials and guest molecules. Based on this fundamental understanding, a series of amphiphilic polymer materials with selective adsorption to guest molecules has been developed and widely used for applications in smart separation, temporally controlled release, and patterning of guest molecules, such as dyes, drugs, and proteins.

     

Foxp3表达与老年颈动脉粥样硬化的关系

目的　探讨老年颈动脉粥样硬化与外周血叉头翼状螺旋转录因子p3（Foxp3）表达以及高敏C反应蛋白（hs-CRP）之间的关系。方法　对66例老年颈动脉粥样硬化患者和51例健康对照者分别利用流式细胞仪检测外周血Foxp3,速率散射比浊法检测hs-CRP。结果　老年颈动脉粥样硬化患者外周血CD4^＋CD25^＋Foxp3^＋调节性T淋巴细胞显著减少,经瑞舒伐他汀钙治疗后较治疗前明显增加;颈动脉粥样硬化患者血清hs-CRP明显高于对照组,有颈动脉斑块的患者血清hs-CRP显著高于颈动脉内中膜增厚患者;将CD4^＋CD25^＋Foxp3^＋与hs-CRP进行相关性分析,两者之间呈负相关。结论　老年颈动脉粥样硬化与外周血Foxp3表达、hs-CRP密切相关。外周血Foxp3表达、hs-CRP在老年人颈动脉粥样硬化、斑块形成的发生发展中起着重要的作用,控制这些危险因素有益于控制和减少脑卒中的发生。     

脑-星状神经节-心房通路调控巨噬细胞对犬急性脑卒中后心房颤动的影响

目的探讨脑-星状神经节-心房通路对犬急性脑卒中(AS)后心房颤动(房颤)的影响及其调控机制。方法26只比格犬按随机数字表法随机分为假手术组(Sham组,n=6)、急性脑卒中组(AS组,n=7)、星状神经节消融(stellate ganglion ablation)组(SGA组,n=6)和巨噬细胞清除组(CL组,n=7)。Sham组犬开颅手术后不行大脑中动脉阻塞(middle cerebral artery occlusion,MCAO);AS组行MCAO后建立AS模型;SGA组行MCAO后行左侧星状神经节(LSG)消融;CL组行MCAO后于左、右心房注射磷酸二钠脂质体。4组犬于3 d后记录心房有效不应期(ERP)、有效不应期离散度(dERP)、房颤诱发率、交感神经活性、巨噬细胞及相关炎性细胞因子表达水平。结果与Sham组比,AS组心房dERP[(14.8±2.1)ms对(36.5±4.8)ms,P<0.05]和房颤诱发率[(4.4±2.2)%对(24.4±4.4)%,P<0.05]均明显升高,而SGA组与CL组dERP[(36.5±4.8)ms对(21.0±3.6)ms,(17.6±2.8)ms,均P<0.05]和房颤诱发率[(24.4±4.4)%对(5.5±2.7)%,(5.3±3.2)%,均P<0.05]均较AS组显著降低;Sham组、SGA组和CL组间房颤诱发率和巨噬细胞水平差异无统计学意义;AS组和CL组LSG活性均较Sham和SGA组明显增加;AS组巨噬细胞和相关炎性因子浸润明显高于Sham、CL和SGA组。结论脑-星状神经节-心房系统可通过增加心房组织巨噬细胞水平增加AS模型犬房颤的易患性。     

Role of gut microbiota on intestinal barrier function in acute pancreatitis

Acute pancreatitis(AP) is a common gastrointestinal disorder. Approximately15%-20% of patients develop severe AP. Systemic inflammatory response syndrome and multiple organ dysfunction syndrome may be caused by the massive release of inflammatory cytokines in the early stage of severe AP,followed by intestinal dysfunction and pancreatic necrosis in the later stage. A study showed that 59% of AP patients had associated intestinal barrier injury,with increased intestinal mucosal permeability, leading to intestinal bacterial translocation, pancreatic tissue necrosis and infection, and the occurrence of multiple organ dysfunction syndrome. However, the real effect of the gut microbiota and its metabolites on intestinal barrier function in AP remains unclear. This review summarizes the alterations in the intestinal flora and its metabolites during AP development and progression to unveil the mechanism of gut failure in AP.     

高血压伴左心室肥厚患者ACE2350G/A及Chymase基因多态性与心房颤动的关系

目的 研究血管紧张素转换酶基因2350G→A单核苷酸多态性（ACE2350G/A）及胃促胰酶（Chymase）基因多态性在高血压伴左心室肥厚（LVH）人群中心房颤动（房颤）及非房颤患者中的分布,探讨高血压伴LVH患者房颤发生的分子遗传学机制,为房颤的防治提供临床和实验依据.方法 2010年8月至2013年6月泰州市人民医院收治的408例高血压伴LVH住院患者,根据有无房颤分为LVH-房颤组和LVH组,利用聚合酶链反应（PCR）及限制性酶切技术进行检测ACE2350G/A及Chymase基因的CMA/B多态性.结果 LVH-房颤组ACE2350基因G、A等位基因的频率明显高于LVH组（x2=5.503,P=0.019）.ACE2350基因多态性与高血压伴LVH患者房颤相关.CMA/B基因在房颤组与LVH组G、A等位基因频率差异无统计学意义（x2=0.933,P=0.334）,CMA/B基因与高血压伴LVH患者房颤发生无显著相关.与正常人相比,各类型LVH患者的CMA/B基因的GG,AA及G、A等位基因频率差异均有统计学意义.结论 ACE2350基因多态性与高血压伴LVH患者房颤发生相关,AA基因型增加房颤的发生风险,A等位基因为房颤发生的危险基因.CMA/B基因与高血压伴LVH患者房颤发生无显著相关.     

肿瘤坏死因子-α拮抗剂对类风湿关节炎和强直性脊柱炎患者血清白细胞介素-17和外周血 Th17细胞比例的影响

目的初步探讨外周血 Th17细胞亚群的比例以及 IL-17的表达水平在 RA 和 AS 患者接受 TNF-α拮抗剂治疗前后的改变及其意义。方法选择 RA 患者27例和 AS 患者22例,2种疾病中各有14例患者接受 TNF-α拮抗剂治疗40周。对照组24名来源于健康献血者。采用流式细胞术检测外周血 CD4+T 细胞中 Th17细胞亚群的比例,ELISA 检测外周血 IL-17表达水平。符合正态分布数据采用2个独立样本 t 检验,不符合正态分布则采用 Wilcoxon 秩和检验,患者治疗前后的比较采用配对 t 检验。结果治疗前,RA 和 AS 患者外周血 CD4+ T 细胞中 Th17细胞亚群的比例显著高于健康对照组[RA 1.03%（0.66%,1.78%）与健康对照0.50%（0.43%,0.67%）,Z=-3.236,P<0.01;AS（1.16±0.09）%与健康对照（0.59±0.06）%,t=5.226,P<0.01]。同样,IL-17的表达水平在2组疾病中也显著升高[RA（32.3±2.5） pg/ml,健康对照（14.3±2.5） pg/ml,t=5.070,P<0.01;AS 28.98（23.84,36.14） pg/ml,健康对照11.84（5.33,22.12） pg/ml,Z=-4.103,P<0.01]。 TNF-α拮抗剂治疗后,2组疾病 CD4+T 细胞中 Th17细胞亚群比例无明显变化[RA 驻（0.1045±0.2126）%;AS 驻（0.0025±0.1838）%],但 IL-17表达水平则明显下降[RA 驻（-13.5±5.0） pg/ml;AS 驻（-16.0±1.9） pg/ml]。结论 Th17细胞及其分泌的细胞因子 IL-17在 RA 和 AS 的发病机制中起重要作用,TNF-α拮抗剂对 AS 和 RA 患者 Th17细胞亚群炎症细胞因子的分泌功能有明显的抑制作用,但40周的治疗仍不能降低 Th17细胞比例,这可能是 TNF-α拮抗剂短期治疗后疾病复发的原因之一。