APP下载

羟基磷灰石负载放射性18F 作为分子影像纳米探针在生物医学中的应用

2019-05-07卢久富刘存芳田光辉

无机化学学报 2019年5期
关键词:磷灰石生物医学羟基

吴 睿 卢久富 宋 娟 刘存芳 张 强 田光辉

(陕西理工大学化学与环境科学学院,陕西省催化基础与应用重点实验室,汉中 723001)

0 Introduction

Molecular or personalized medicine is the future of patient management and molecular imaging plays a key role in healthy.Molecular imaging refers to the characterization and measurement of biological processes at the molecular or cellular level[1-4].Recently,the emergence of novel nanoprobes for molecular imaging was employed for earlier disease detection[5-7].One of the most primary goal in molecular imaging is to obtain high signal and localize the signal as accurately as possible with high temporal resolution and with minimal amount of molecular probe,namely achieving higher contrast ratio of the imaging.In keeping pace with these milestones in the evolution of medical imaging,there is no doubt that PET is the most high sensitive and accurate molecular imaging modality,which has the potential to revolutionize diagnostics and therapeutic monitoring in clinic[8-10].But it remains imperative to develop higher sensitivity imaging method for clinical practice.At present,most of the researchers for PET worldwide perform in oncologic patients, by using FDG (fluorodeoxy glucose)and it′s derivative,as well as some NPs for18F carrier[11-19].Despite its high diagnostic accuracy in the important role of determining the neoplasm,PET is expected to play a pivotal role for more and more disease as a relatively well entrenched diagnostic tool.

However,for the most part,these advances have not translated into greatly improved clinical outcomes.The reason for this is that each [18F]FDG can only carried one18F that trapped the development of[18F]FDG probes as higher contrast agent.Furthermore,it cannot differentiate between cancer and inflammation in diagnosis of the tumor.Advances in PET for tumor are now extending the application further into lymphatic imaging.Success in these endeavors requires a new effort in many innovations.

In view of this,it is reasonable to assume that if we can study on innovation for the challenge above,the PET imaging may come true.Nanomedicine may has the potential to provide novel and paradigm shifting solution for the challenge.It is supposed that radionuclides were doped in the process of synthesis trace amount of nanoprobes.As a result,large number of radionuclides were labeled in the nanoparticles and the efficientsignalenhanced aswellasother advantages.Furthermore,the radionuclides were trapped in the NPs avoiding leakage and the large surface of the NPs was used for other purposes.

To reach the goal,three protagonists are mandatory.One of the top priorities is the synthesis methods that its fate is of paramount importance to ensure trace synthesis due to the limited radionuclide produced in cyclotron.A second issue is the modification on the surface in a short time.In line with this,the third concern is the sophisticated techniques and methods of separation and purification in a short time.

18F is the most readily available and widely used in PET due to its favorable half-life of 110 min and its ease of production in cyclotron.Therefore,they are utilizable by a high number of PET centers in hospital.HAp is calcium phosphate compound with the chemical formula Ca10(PO4)6(OH)2.Owing to their low toxicity,good biocompatibility,HAp NPs were applied in cell labeling,tracking,imaging,drug delivery[20-23].

Herein,in recognition of this,we open our mind to the widening field of the PET outside the FDG kingdom.A thorough and fascinating study is meet to the expected nanoprobes above.In previous report,the18F was labeled by weak physical adsorption on the surface of HAp NPs[24-25].Due to dopping18F in the process of synthesis in trace amount,18F was not only strong tied to the surface but also was inside by strong chemical covalent bond.In line with this,due to the present of the limited resources of18F and the trace amount of HAp,each HAp NP carried large amount of18F.So the detection signal will be strong enough.In addition,because of the lager volume of HAp NPs inside than outside,overwhelming majority of18F were encapsulated which were relative safe to human body.It is expected that the safe,green and efficient nanoprobes will provide an interesting platform for developing biochemistry and biomedicine.

1 Experimental

1.1 Chemicals

Disodium hydrogen phosphate,diammonium hydrogen phosphate, calcium nitrate, sodium dihydrogen phosphate and ammonium hydroxide were obtained from Sinopharm Chemical Reagent Co.,Ltd.The pentobarbital sodium was purchased from Sigma-Aldrich.Hexadecyl(cetyl)trimethyl ammonium bromide(CTAB),sodium citrate (Na-Cit)and polyethylene glycol (PEG)were purchased from Tianjin Fu-chen Chemical Reagent Science and Technology Co.,Ltd.All chemicals were analysis-grade.All water was deionized.

1.2 Synthesis of HAp NPs and doping of19F

Chemical precipitation was employed to synthesize large amount of HAp NPs.Diammonium hydrogen phosphate and calcium nitrate tetrahydrate were employed as the precursors in a molar ratio of Ca to P being 1.67.Briefly,3 mL of 0.10 mmol·L-1diammonium hydrogen phosphate solution was added into 10 mL of the centrifuge tube and 5 mL of 0.10 mmol·L-1calcium nitrate was dropped into the solution.The pH value of the solutions was maintained at 9~10 by adding ammonium hydroxide.The mixed solution was heated at 80℃for 1h under magnetic stirring.After that,the suspension was centrifugation (24 000 r·min-1)for 10 min,and washed three times with deionized water.For doping fluoride,1 mL of 0.10 mmol·L-1sodium fluoride was added to the solution,other steps are the same.The control experiments were carried out in the presence of PEG,Na-Cit and CTAB as modifier,following the same procedure.For trace amount of synthesis,30 μL of 0.10 mmol·L-1diammonium hydrogen phosphate solution participated in the reaction,the quantity of sodium fluoride remain the same,the other based on the stoichiometric ratio.

1.3 Characterization of HA NPs with TEM and EDS

The morphology and structure ofthe assynthesized HAp NPs were determined by transmission electron microscope(TEM).TEM images were recorded using FEI Tecnai G2 S-Twin type with a field emission gun operating at 200 kV.EDS(energy dispersive spectrometer)was used to confirm the HAp NPs with F element.

1.4 In vitro stability studies

The stability of18F labeled HAp NPs(18F-HAp)in vitro was investigated to determine the leaching of fluorine.Considering the harm of radioactive18F,the common19F replaced18F.The19F-HAp NPs were incubated in PBS(phosphate-buffered saline).The19FHAp NPs in the presence of CTAB and without CTAB were suspended in 1 mL of PBS(pH~7.4)at 37℃ for 2 h.After 2 h,the NPs were characterized with TEM to check whether the morphology changed.

1.5 Synthesis of18F-HAp

18F was produced by irradiation of18O-water with protons from cyclotron.The solution in18O-water was used without further purification.The18F was nominally in the form of no-carrier-added fluoride ions,although typically19F was also present in traces.Initial studies were performed using HAp NPs,and focused on testing the optimal medium in which to carry out the radiolabeling and optimal incubation times required.Briefly,30 μL of 0.10 mmol·L-1diammonium hydrogen phosphate solution was added into 5 mL of the centrifuge tube.Then,1.11×108Bq of18F was added to the solution,and 50 μL of 0.10 mmol·L-1calcium nitrate was dropped into the solution.The pH value of the solution was maintained at 9~10 by sodium hydroxide.The mixed solution was heated at 80℃for 1 h under magnetic stirring.

1.6 Determination of radiolabeling yield

Subsequently,radiolabeling of HAp NPs was investigated in detail.The radiolabeling yield of18FHAp was determined by measuring the radioactive activity.PBS was added to18F-HAp solution and 5 μm of aluminum oxide powder were employed to remove free18F,filtration with 0.22 μm of membrane.Subsequently,the filter liquor was carefully pipetted out into a test tube and18F activity was measured.18F associated with HAp NPs was also measured.

1.7 Biodistribution studies

Furthermore,practical application of18F-HAp as radiotracer was investigated by biodistribution carried out in normal rats.For distribution studies,18F-HAp were injected into rats and free18F ions as control group.The animals were anesthetized by using a dose of pentobarbital sodium and the anaesthetized conditions were maintained until the surgical procedure was completed.Anaesthetized animals were prepared for aseptic laparotomy.Aseptic conditions were maintained by using sterile wire and instruments during surgery.Rats were injected with18F-HAp probes through the tail vein.Abdominal organs were placed in situ,and surgical wound was stitched immediately.To ascertain the distribution pattern of the agent,the animals were sacrificed by cardiac puncture post-anesthesia post-injection.Three animals were used for each time point,collecting main viscera organs(liver,spleen,kidney,lung,muscle and bone).

2 Results and discussion

2.1 Synthesis and TEM characterization

TEM characterization of NPs is one of the most common method.To get good morphology nanoprobe for PET imaging and to check whether F affect the formation of the microcrystals,a large amount of HAp NPs and the trace amount of F-HAp NPs were used for TEM characterization.As shown in Fig.1,the TEM imagesconfirm thattheobtained productswere typically rodlike shape in nanosize with an average length of 50 nm and an average width of 10 nm.There are no significant difference between them.

To get perfect morphology nanoprobes,three different modifiers were employed for TEM characterization.Fig.2 is the TEM micrographs in the presence of PEG (a),Na-Cit(b)and CTAB(c),respectively.The NPs were irregular and rod-like in the presence of PEG and Na-Cit(Fig.2a,2b).However,spherical nanoparticles were formed in the presence of CTAB,with average of 40 nm in diameter(Fig.2c).

Fig.1 TEM images of HAp NPs in large amounts(a)and trace F doped HAp NPs(b)

Fig.2 TEM images of PEG(a),Na-Cit(b)and CTAB(c)modified HAp NPs

As discussed above,citrate molecules actually act as distinct chelating agent,common dispersant and morphology regulator to synthesize morphologycontrolled NPs.They also have been extensively used as crystal growth depressant and in a cross-linking role to prepare various size/shape controlled NPs or nanostructures through the route of solution chemistry[26].Cit3-ligand plays a critical role in the present reaction system,where crystal growth,self-assembly and phase transition coexist.Crystal growth occurred in parallel for the formation of HAp,however,the underlying mechanisms were studied. Chelating ligands of Na-Cit firstly mobilize calcium ions during the first step of starting reagents mixture process to generate Cit-Ca complexes.A citrate molecule has four binding sites,including three COO-and OH-group,among which three sites can be bound with Ca2+cations.Ca2+should be first in the form of stable complex owing to efficiently reacting with citrate anions.Upon heating the medium,Ca2+ions are released from the complexes,the supersaturaion condition could be achieved and significantly inhibits the crystal growth.So,when HAp forms,the negative H2PO4-,OH-,and F-in the solution then react with the free Ca2+to generate F-HAp nuclei.Then,the PO43-anions compete with the chelators to produce colloidal sol of HAp,where the HAp nuclei grew into the nanocrystals with covered Cit3-groups,which may selectively bond to certain crystallographic facets of recrystallized HAp via covalentor electrostatic interactions between intramolecular COO-groups and surface cationic sites Ca2+.With increasing reaction time,these nuclei then grow into big particles along certain orientation due to the selective adsorption of anionic citrate species.

On one hand,Cit3-groups accordingly form a protective layer to hold back the further growth of particles.On the other hand,the noncovalent or weak covalent interactions (e.g.electrostatic,hydrogen,coordination bonds)among the surface ligands(OH-or COO-groups)stretching outwards of the surface of different nanoparticles probably provide a driving force that makes primary nanounits form monodisperse microspheres.After the complexation of added citric acid to metal ions,the negative charge on the surface of nanoparticles repels each other due to carboxyl groups,preventing agglomeration.Thus,the dispersant can act as a dispersing agent,and the nanoparticles exhibit good monodispersity.It is suggested that upon the above driving force,different HAp NPs move with respect to one another and reach an equilibrium that balance attractions and repulsions,producing a steady state of microspheres with the minimal surface energy.As a result,rod-like HAp NPs appeared.

For PEG,as shown in Scheme 1,when PEG is dissolved in aqueous solution,the PEG-OH bond is formed.PEG molecule has the ability to chelate Ca2+,therefore,PEG-OH can attract Ca2+to form the bond of PEG-O-Ca2+-O-PEG,then PEG-O-Ca2+-O-PEG react with PO43-to produce HAp crystal nuclei.In this process,the release rate of Ca2+and PO43-are the important factors.The release rate of Ca2+reduced with increasing the concentration of PEG[27].A large amount of deposits form in a short time when the solution was in the absence of PEG or the concentration of PEG was quite low,indicating HAp produced quickly.With increasing the of PEG,initial deposits were gradually reduced and it required longer time to produce large quantities of deposits,indicating that PEG reduced the release rate of Ca2+and restrained the formation of HAp crystal nuclei.When the release rate ofCa2+and the deposit rate of HAp crystal nuclei depositing in the precipitation center achieve a dynamical equilibrium,HAp crystal nuclei deposit isotropically,and finally the HAp particlesare obtained.The HAp crystal nuclei could not deposit isotropically in the precipitation center,so the morphology of as-prepared HAp particles are not spherical.

Scheme 1 PEG and schematic illustration of possible forming process of HAp

Surfactant-based systems have been widely used in the synthesis of nanosized materials.CTAB is a typical surfactant controlling particle size,and is used to direct the growth and stabilize the shape of certain types of colloidal nanoparticles[28].The use of CTAB bases on the theory of critical micelle concentration(CMC).In the presence of CTAB,CTAB might raise the solubility of HAp to some extent and accelerate the dissolution and crystallization process.Since the crystallization process is under CMC,the resulting HAp are invariably nanosphere.The behavior of CTAB is considered to correlate with the charge and stereochemistry properties.In an aqueous system,CTAB would ionize completely and result in a cation with tetrahedral structure.It is then proposed that the charge and structure complementarity endows CTAB with the capability to controlthe crystallization process.Similarexplanation could be made to interpret the experiment of sodium dodecyl sulfonate(SDS).CTAB was an efficient agent for modulating the formation of HAp NPs.

2.2 In vitro stability studies

A satisfactory result with stability investigation in vitro was obtained.TEM image of rod-shape and sphere-shaped HAp NPs are shown in Fig.3.HAp NPs without CTAB still kept rod shape with a uniform size of 50 nm(Fig.3a).The crystals were spheroidic in shape and well monodisperse with an average size of about 40 nm (Fig.3b)in the presence of CTAB.It is demonstrated that HAp NPs keep stable in PBS.

2.3 EDS characterization

EDS was employed to investigate the elemental composition of HAp.The19F-doped HAp NPs were characterized instead of18F-doped.Only Ca,P,and O elements appeared in HAp samples(Fig.4a),corresponding to Ca10(PO4)6(OH)2sample.There was no other element in the sample,excluding carbonaceous species.The EDS of F-HAp NPs (Fig.4b)depicted the presence of Ca,P,O and F elements.It is indicated that the F element is successful loaded in HAp NPs.

Fig.3 TEM images of HAp NPs with CTAB(b)and without CTAB(a)dispersed in PBS

Fig.4 EDS image of HAp NPs(a)and F-HAp NPs(b)

2.4 Mechanism

The mechanism of doping was also explored.The HAp structure with the unconnected PO43-tetrahedra orients towards Ca2+ions along the a-axis,and the electronegative ions(OH,F,Cl)are placed perpendicularly to Ca2+ions along the c-axis,as shown in Fig.5.The hexagonal crystal lattice of apatite is maintained upon the anion substitution.Nevertheless,the different sizes of the ions results in lattice strain,which,in the particular case of F substitution(the ionic radii are 0.168 nm for OH-and 0.132 nm for F-)causes a contraction of the a-axis.These small structural alterations due to F substitution are probably of crucial importance in the biomineralization mechanism of the apatite containing natural tissues of bones and teeth[29-30].

The radiusoffluorideion issmallerthan hydroxyl,so the fluorine ion can replace the position of the hydroxyl groups in the lattice.In addition,the electronegativity of fluorine is larger than oxygen,and the attraction of F-H is stronger than O-H in the hydroxyl groups.So the OH…F…OH bond is enhanced.The F-HAp lattice parameters change,and the lattice constant of HAp is larger than F-HAp.The structure arrangement of fluorapatite is more compact than hydroxyapatite,and the stability of fluorapatite is better than HAp.As a result,fluorine can be facile to dope in the HAp NPs.

Fig.5 Crystal structure of hydroxyapatite

2.5 Radiolabeling yield

To improve density of labeling and get high sensitivity probes,we calculated and evaluated the amounts of18F labelling theoretically.In addition,it provides a new method to study the amount of labelling in microcosm.Here,the HAp NPs are spherical.Therefore,the volume of each of the NPs can be calculated,and the number of F atom in each nanoparticle was calculated.The results are as follow:

The volume of one HAp crystal cell:

The volume of one HAp nanoparticle:

The number of crystal cell in one HAp NP:

The weight of one HAp NP:

(The density of HAp is 3.16 g·cm-3,the radius of the HAp NP is about 20 nm)

The weight of HAp bases on experiment:

(The molar mass of HAp is 1 004 g·mol-1)

The total number of HAp NPs:

The total number of HAp crystal cell:

As we know,one HAp crystal cell contains two hydroxyl groups.In other words,if the hydroxyl on the HAp were completely replaced by F,one crystal cell has two F,at most.

The number of F atom:

The number of18F atoms in one nanoparticle:

For maximum number,there was 1.28×105F atom in one HAp NP.This,however,is only in theory.Actually:

The volume of one HAp NP:

The calculation formula of weight for radionuclide:

A:radioactivity,1.11×108Bq;k rely on A:2.393×10-24mol;M:molar mass of18F;T1/2:half-life,109.8 min.

So the amount of18F:

The number of18F:

The number of18F atoms in one nanoparticle:

According to calculation,one HAp NP can label 22018F atoms,in theory,which provided robust theory foundation.Fortunately,radiolabeling yield of18F-HAp determined by measuring the radioactivity associated with the HAp NPs as described in the experimental section was 89%±0.6%,which was identical with envision.

2.6 Biodistribution studies

The tissue and the organs were excised,and the activity associated with each organs or tissue was measured in counter.The uptake in different organs/tissue was calculated from these data and expressed as injected activity(%).The data revealed that rapid accumulation of 40%was in the liver and 24%in spleen at 30 min.Tibia was considered as the representative of skeleton while calculating total skeleton uptake.Uptake in the bone,muscle,kidney and lung organs were very low(Injected dose fraction per gram<10%ID/g).No appreciable uptake was observed in any of the major organs or tissue,particularly in lungs and spleen,due to the possible leakage of the radiolabeled particulates from liver.Liver and spleen as part of reticuloendothelial system and the colony macrophagocyte,the nanoprobes were facile to target there as well as enhanced permeability and retention effect (EPR).Since free18F has a native bone targeting capability,the low radioactivity in bone suggests that most of the18F radiolabels remain intact on HAp NPs.Besides,the weak radioactive signal for the kidney is the evidence of the stability of the18FHAp NPs,because metabolism of free18F passed through kidney.

Fig.6 Photos of the organs(A)and vivisectional rat(B)

Fig.7 Distribution of free18F in the rat

Fig.8 Distribution of18F-HAP in the body of rat

3 Conclusions

In brief,we have developed a simple,rapid and efficient strategy for synthesis of18F-labeled HAp.A trace amount of synthesis was employed,with label simultaneously.The method was benefit to improve radiolabeling yield and prevent to leak.The facile18F-labeling method for HAp NPs will offer significant opportunities for developing molecular image probes.The animalexperimentation willopen up new perspectives for the preparation of uniform nanoprobes for PET bioimaging application from the cellular scale to whole-body evaluation.

Acknowledgments:

We greatly appreciate the Natural Science Foundation of Shaanxi Province (Grant No.2018JQ2057),Scientific Research Program of Shaanxi Provincal Education Department(Grant No.17JK0151),PhD Research Foundation ProjectofShaanxi University of Technology (Grant No.209020195),National Natural Science Foundation of China (Grant No.21502109),the Key Scientific Research Projects ofShaanxiEducation Department(Grants No.18JS023,17JS027).

Part of this work was performed at Shaanxi Normal University and the General Hospital of Lanzhou Military Region.The authors express their sincere thanks to Jiagen Lv,the professor of Shaanxi Normal University,for his keen interest and constantsupport.Theauthorsgratefully acknowledge Wansheng Liang.The help rendered by the staff members of the animal house facility of PET-CT center of General Hospital of Lanzhou Military Region is also acknowledged.

猜你喜欢

磷灰石生物医学羟基
磷灰石的宝石与工业价值
广西医科大学生物医学工程一流学科建设成效
云南某中低品位磷矿工艺矿物学研究*
蝾螈的皮肤受伤后可快速愈合
珊瑚羟基磷灰石表面改性的工艺
生物医学大数据的现状与发展趋势研究
磷灰石吸附铀试验及其铀成矿意义
纳米机器人及其发展研究
对羟基苯甘氨酸合成条件的研究
羟基化合物比较与例题剖析