Determining the state of radionuclides in polymersomes using perturbed angular correlation spectroscopy Stephanie Laura Christina Bogers Master thesis performed at: Section Radiation and Isotopes for Health Radiation, Radionuclides & Reactors Faculty of Applied Sciences Delft University of Technology In partial fulfilment of the requirements for the Degree of Master of Science in Biomedical Engineering, track Medical Physics of the Delft University of Technology. July 2015 Under the supervision of: Ir. R.M. de Kruijff F.D.P. Geurink Ing. J. Huizenga Prof. Dr. Ir. M. de Bruin Dr. Ir. A.G. Denkova Dr. ir. D.R. Schaart Committee members: Dr. ir. D.R. Schaart Dr. ir. P. Bode Dr. K. Djanashvili Date of submission: 22-07-2015 Date of presentation: 29-07-2015 2 Abstract Polymersomes, polymeric nano-carriers composed of amphiphilic block copolymers, are promising candidates for transporting (radio)pharmaceuticals to tumour cells. While methods have been developed for trapping both diagnostic and therapeutic amounts of radionuclides in these polymersomes, there is not much known about the loading process and the state of the radionuclide in the polymersomes. At this point perturbed angular correlation (PAC) spectroscopy becomes essential, as it is a useful method for gaining information about the chemical surroundings and physical structures of different gamma-emitting radioisotopes. PAC is a gamma ray spectroscopy technique which can be used for the investigation of hyperfine interactions. A hyperfine interaction is the interaction between a nucleus and its environment. Hyperfine interactions arise in the intermediate state of a decaying radionuclide. This decay is then perturbed with a time-dependent factor and can be measured from the angular correlation function. The angular correlation function is expressed as the number of coincidences per unit time as function of angle. The number of coincidences is measured using the PAC spectroscopy. The polymersomes are composed of poly(butadiene-b-ethylene oxide) block copolymers, and the labelling has been achieved by transportation of the radionuclide, complexed to a lipophilic ligand, through the hydrophobic bilayer into the aqueous cavity containing 0.5 M of KH PO . A sufficient 2 4 amount of the radionuclides was encapsulated in the polymersomes (>90 % loading efficiency). Subsequent to the loading, the sample was immersed in liquid nitrogen, after it was counted on the PAC setup for 6 hours at 90 and 180 angles. To confirm a working PAC setup, measurements on directional correlation and a simple perturbed system are performed. Excellent agreement with literature has been observed for cobalt-60 directional correlation measurements (G22 of 0.1016 vs 0.1020 in [18]). The hafnium metal measurements, which only undergo a static interaction, are compared with literature [39]. The results give an indication of a reliable PAC setup. Final measurements are performed with indium-111. The results obtained for the loaded radionuclides in polymersomes indicate that differences could be distinguished. The results indicate that the radionuclides will move from the bilayer towards the core of the polymersome. There was no clear bonding observed between the chelator and the radionuclides. The used side of the polymersomes (100 nm, 800 nm) are expected not to influence the measurement. 3 4 Contents Abstract ................................................................................................................................................... 3 Abbreviations and acronyms ................................................................................................................... 7 1 Introduction ..................................................................................................................................... 9 2 Polymersomes ............................................................................................................................... 11 3 Theory of PAC ................................................................................................................................ 13 3.1 Background on PAC ............................................................................................................... 13 3.2 γ-γ cascade ............................................................................................................................ 13 3.3 Hyperfine interactions ........................................................................................................... 14 3.3.1 Magnetic dipole interaction .......................................................................................... 14 3.3.2 Electric quadrupole interaction ..................................................................................... 15 3.4 Angular correlation of γ-γ cascade ........................................................................................ 16 3.5 Perturbed angular correlation of γ-γ cascade ....................................................................... 17 3.5.1 Unperturbed interaction ............................................................................................... 19 3.5.2 Static interaction ........................................................................................................... 19 3.5.3 Time dependent interaction .......................................................................................... 20 4 Experimental PAC setup ................................................................................................................ 23 4.1 Detectors ............................................................................................................................... 24 4.1.1 Scintillator ...................................................................................................................... 24 4.1.2 Photomultiplier tube ..................................................................................................... 25 4.2 Slow coincidence circuit ........................................................................................................ 25 4.2.1 Spectroscopy amplifier .................................................................................................. 25 4.2.2 Coincidence unit ............................................................................................................ 26 4.3 Fast coincidence circuit ......................................................................................................... 26 4.3.1 Constant-fraction Discriminator .................................................................................... 26 4.3.2 Time to amplitude converter ........................................................................................ 28 4.4 The output signal ................................................................................................................... 28 4.5 Signal processing ................................................................................................................... 29 5 Materials ........................................................................................................................................ 31 5.1 Radionuclides ........................................................................................................................ 31 5.2 Polymersome preparation and loading (with indium-111) ................................................... 31 5.3 Equipment ............................................................................................................................. 32 5.3.1 Electronic components .................................................................................................. 32 5.3.2 Sample holder ................................................................................................................ 32 5 5.3.3 Sample encapsulation ................................................................................................... 33 6 Methods ........................................................................................................................................ 35 6.1 Characterization of the PAC setup ........................................................................................ 35 6.1.1 Energy- and time resolution measurements ................................................................. 35 6.1.2 Detector performance ................................................................................................... 36 6.1.3 Limitations of the setup................................................................................................. 37 6.2 Directional correlation measurements ................................................................................. 37 6.3 Hafnium-181 measurements ................................................................................................. 38 6.4 Indium-111 measurements ................................................................................................... 38 7 Results and discussion ................................................................................................................... 41 7.1 Characterization of the PAC setup ........................................................................................ 41 7.1.1 Time resolution.............................................................................................................. 41 7.1.2 Energy resolution .......................................................................................................... 42 7.1.3 Detector performance ................................................................................................... 43 7.1.4 Limitations of the setup................................................................................................. 46 7.2 Directional correlation measurements ................................................................................. 48 7.3 Hafnium-181 measurements ................................................................................................. 50 7.4 Indium-111 measurements ................................................................................................... 53 8 Conclusion ..................................................................................................................................... 59 9 Outlook .......................................................................................................................................... 61 10 References ..................................................................................................................................... 63 11 Appendices .................................................................................................................................... 67 12 Poster ............................................................................................................................................ 77 Acknowledgements ............................................................................................................................... 79 6 Abbreviations and acronyms Abbreviation Explanation PAC Perturbed angular correlation PMT Photomultiplier tube LaBr (Ce) Lanthanum bromide 3 ADC Analog to digital converter MCA Multi channel analyser CFD Constant fraction discriminator TAC Time to amplitude converter SBD Radiation protection services Hf Hafnium In Indium Na Sodium Cs Caesium Co Cobalt LN Liquid nitrogen 2 7 8 1 Introduction Cancer is one of the leading causes of morbidity and mortality worldwide. In 2012, approximately 14 million new cases and 8.2 million cancer-related deaths were recorded. It is expected that cancer cases will rise from 14 million in 2012 to 22 million within the next 2 decades. [1] These numbers indicate that knowledge about the causes of cancer and interventions to prevent and manage the disease are essential. Every cancer type requires a specific treatment, encompassing one or more modalities, such as surgery, chemotherapy and radiotherapy. Although surgery is considered to be one of the most effective ways to treat cancer patients, in cases where the disease metastasizes radionuclide therapy is, next to chemotherapy, one of the only proven alternatives. Radionuclides are, therefore, indispensable in both diagnostics as in therapy. [2] In radiotherapy, tumours are irradiated to kill the tumour cell. This can be done in two different manners: from outside the body (external radiotherapy) and inside the body (internal radiotherapy). During external radiotherapy, the tumour is irradiated using several beams. A disadvantage is that surrounding healthy tissue will receive a dose as well. Using internal radiotherapy, the radiation could be delivered very locally. Hence, this method destroys the tumour cells while simultaneously preserving the surrounding healthy tissue as much as possible. Another advantage of internal radiotherapy is that small metastases can be treated. Using internal radiotherapy, radionuclides will be injected into the body. Preventing the radionuclides to spread throughout the body, radiation can be loaded into a carrier. One of these carriers which are investigated are polymersomes. Polymersomes are polymeric nano-carriers which can be used to transport therapeutic or diagnostic amounts of radionuclides to specific sites in the body. [3] Polymersomes can be loaded with alpha-, beta- or gamma-emitting radionuclides, this process is called radiolabelling. Once the polymersomes are loaded, the radionuclides are transported to the tumour site. Ionizing radiation is emitted by the radionuclides in the polymersomes. They could kill tumour specific cells and limit the damage to healthy surrounded tissue. [4,5] There is not much known about the specifics of radiolabelling polymersomes. Once the radionuclides are loaded, is the radiation inside the core or in the bilayer of the polymersomes? In what state is the radionuclide inside the polymersome? Perhaps these and similar questions could be answered using perturbed angular correlation (PAC) spectroscopy. PAC spectroscopy is a very useful method to gain information about the chemical surroundings and physical structures of different radioisotopes. PAC relies on measuring the variations in time between two decays as a function of time and angle. These variations are caused by the surroundings (solid, liquid etc.) of the radionuclide and PAC is able to measure these. PAC is a non-invasive method, hence no limitations in the choice of sample environment are present. PAC experiments can be carried out with samples in any aggregate state and in a wide range of pressures, temperatures and external electromagnetic fields. [5] Only minute quantities of biological material (10-12 mol) are needed to perform PAC experiments. [6] The theory behind PAC spectroscopy is based on the decay of an excited state of a decaying nucleus to a metastable state, by the emission of a first radiant. This emission is followed by a decay from the metastable state to the ground state where a second radiant is emitted. [7] This metastable state is called the intermediate level of the cascade. 9 Radionuclides used for PAC spectroscopy should have specific properties: • the nuclides should have a nuclear de-excitation through a γ-γ cascade • the intermediate level of the γ-γ cascade should have a spin ≥ 1 • the half-life of the intermediate state should be between 2 ns and 1 µs It is noted that a useful range of the half-life of the intermediate state is not well defined. When the intermediate life-time is small, the system becomes unperturbed, so the system is not able to measure any interactions. Unfortunately, the exact point from where interactions could be measured has not been found in literature. Two radionuclides which have favourable properties and are therefore used in typical PAC experiments are indium-111 and hafnium-181. The activity of the samples is typically between 1-100 µCi. The ultimate goal of research in this field is to measure radionuclides encapsulated in polymersomes in vivo. In this manner, patients can be treated in an effective manner by local radiotherapy and while using PAC spectroscopy important information about the treatment and diagnostics are gathered. The first goal in this project is to investigate the possibility of using PAC can be used in vitro experiments. When these results are positive, further research can be performed to explore the possibilities of using PAC in vivo. The objective of this thesis is to determine the state of radionuclides inside polymersomes using perturbed angular correlation spectroscopy. To answer this question, a properly working PAC spectroscopy setup is necessary. At the beginning of this project, an old setup was available and explored to investigate if it was still working. Confirmation of a properly working PAC setup should be done by several experiments. The time and energy resolution and other setup limitations are important quantities to investigate. After this, directional correlation measurements are performed with an unperturbed radionuclide, which gives a first clue about the working of the setup. Hafnium- 181 metal only shows static interactions and has a short half-life of the intermediate state. Once these measurements are preformed, first preliminary measurements with indium-111 in different states and loaded into polymersomes are performed. These measurements are performed to confirm the hypotheses that PAC is a suitable method to use in in vivo measurements. In this thesis different topics are covered in order to answer the research question. First, the working principle of polymersomes is described, followed by a brief historical outline and a quick overview of the working of PAC. Further, knowledge about hyperfine interactions, angular correlation and perturbed angular correlation is necessary, which will be explained in section 3.3 – 3.5. Then, the PAC setup will be declared in more detail. In a subsequent material section, a list of all the used materials and electronics can be found. The experiments done are explained in the method section. From this the results obtained in this research are described and discussed. The last part of this thesis contains the conclusions and an outlook for further research. 10