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In This Article

  • Summary
  • Abstract
  • Introduction
  • Protocol
  • תוצאות
  • Discussion
  • Disclosures
  • Acknowledgements
  • Materials
  • References
  • Reprints and Permissions

Summary

This protocol describes the use of 18F-AV-1451 PET/MRI to reveal tau pathology and neurodegeneration, aiding neurologists in diagnosing Alzheimer's disease, assessing its severity, and gaining insights into its progression and underlying pathological mechanisms.

Abstract

Alzheimer's disease (AD) is a progressive and irreversible neurodegenerative disorder characterized by cognitive dysfunction, decline in daily living abilities, and behavioral changes, imposing a significant economic and social burden worldwide. One of the primary pathological hallmarks of AD is the accumulation of neurofibrillary tangles formed by hyperphosphorylated tau protein. Positron emission tomography/magnetic resonance imaging (PET/MRI) provides detailed structural and functional information along with specific protein distributions, making it an increasingly valuable tool for AD diagnosis and research. 18F-AV-1451 is a radiotracer specifically designed for tau protein detection in PET imaging of brain tissue. This study presents a detailed protocol for the radiosynthesis of 18F-AV-1451, patient preparation, PET/MRI image acquisition techniques, and its potential applications in AD evaluation. 18F-AV-1451 PET/MRI could aid neurologists in diagnosing AD, assessing disease severity, and gaining insights into its pathological mechanisms. In conclusion, this protocol provides a sensitive, comprehensive, and non-invasive approach for the evaluation of AD, offering valuable insights into disease progression and pathology.

Introduction

Alzheimer's disease (AD) is a progressive and irreversible neurodegenerative disorder. Patients typically experience cognitive dysfunction, a decline in daily living abilities, and behavioral changes. With the accelerating global aging population, Alzheimer's disease has become a major public health concern. Currently, more than 50 million people worldwide are living with AD. By 2050, the prevalence of dementia is expected to triple globally1. Approximately 10.8% of individuals aged 65 and older have Alzheimer's dementia. The prevalence of AD is about 5% in individuals aged 65 to 74, increasing to 33.3% in those aged 85 and older, making it one of the leading causes of death among the elderly2. Once a patient develops AD, it places a significant burden on the family3. Due to its insidious onset, patients often miss the optimal window for treatment after diagnosis. Its early detection remains a global challenge4, as the exact etiology is still not completely understood5,6. Given the complex etiology and pathways influencing AD, there is an urgent need for more accurate and early diagnostic strategies.

Conventional imaging methods such as computed tomography (CT) and magnetic resonance imaging (MRI) are used to observe atrophy or other structural changes in the brain, which may contribute to cognitive impairment. MRI, in particular, provides better soft tissue contrast than CT and offers tumor biology information without exposing patients to ionizing radiation, making it the preferred imaging modality for most neurological disorders6. MRI is a powerful imaging technique that not only provides detailed macroscopic anatomical information but also includes various functional imaging methods, such as blood oxygen level-dependent functional magnetic resonance imaging (BOLD fMRI), which can be used to observe functional brain activity6. Positron emission tomography (PET) is a non-invasive molecular imaging method that enables extensive semi-quantitative analysis of biological processes in the human brain. Hybrid PET/MRI may offer advantages over other imaging techniques for AD diagnosis7, as the use of a wide variety of PET tracers can provide additional physiological information to complement anatomical MRI images8,9.

Neurofibrillary tangles formed by the hyperphosphorylation of tau protein are one of the pathological features of AD, closely associated with the onset of neurodegeneration and the manifestation of clinical symptoms both spatially and temporally6. Tau protein is the most abundant microtubule-associated protein in vivo and is prevalent in both the peripheral and central nervous systems. The pathological progression of tau is strongly correlated with the degree of cognitive impairment and has the potential to serve as a therapeutic target for AD patients7. Non-invasive detection of tau protein deposition in specific brain regions is valuable for the early prediction and diagnosis of the disease. The use of tau radiotracers enables the visualization and localization of tau protein deposits in the brain, providing timely and accurate differential diagnosis, as well as valuable support in tracking disease progression and assessing experimental clinical treatments8,9.

Several studies have demonstrated a relationship between changes in specific proteins and functional or morphological MRI findings10,11. However, there are limited reports on combined analyses using amyloid/tau imaging and functional MRI12. The novel molecular diagnostic drug 18F-AV-1451 (7-(6-[18F]fluoropyridin-3yl)-5H-pyrido[4,3-b]indole) has been used as a radiodiagnostic agent for tau protein detection in PET-imaged brain tissue. Research on tau PET imaging is still in its developmental stage, with only a few tracers currently evaluated, including 18F-T807 (18F-AV-1451), 18F-T808 (18F-AV-680)13, 11C-PBB314, 18F-THK-511715, 18F-THK-52316, and 18F-THK-510517,18. 18F-AV-1451 was commercially developed19 and has been reported for use in patients with AD20, progressive supranuclear palsy21, and dementia with Lewy bodies22. The radiosynthesis process of 18F-AV-1451 requires a complex purification step to ensure that the final product meets dosage requirements for clinical imaging studies23. With the increasing application of 18F-labeled radiotracers in PET imaging technology, there is a growing demand for the synthesis and development of new 18F-labeled radiotracers. This study presents a tau PET/MRI imaging method aimed at providing more detailed information for the diagnosis of patients with Alzheimer's disease.

Protocol

The study was approved by the local Medical Ethics Committee, and all subjects provided written informed consent prior to participation. All studies were conducted in adherence to the tenets of the Declaration of Helsinki. All subjects underwent neurological and neuropsychological evaluations by a healthcare professional within three months before and after imaging. Patients were included based on the National Institute on Aging-Alzheimer's Disease Association (NINCDS-ADRDA) criteria24 and the National Institute on Aging-Alzheimer's Association (NAA) criteria25. The details of the reagents and equipment used are listed in the Table of Materials.

1. 18F-AV-1451 synthesis

NOTE: Follow the principles of biological and radiological occupational protection, as well as the principles of medical and radioactive waste disposal, during operations.

  1. Synthetic details
    1. Synthesize 2.5 mL of [18F] fluoride using the 18O(p, n)18F nuclear reaction by employing a particle accelerator, with protons at integrated currents up to 45 µA bombarding for 40 min. Add [18F] fluoride to the automated synthesis module via the transfer pipeline, facilitated by helium gas overpressure. Operate the synthesis module in the order shown in Figure 1.
    2. Trap [18F] fluoride on an ion-exchange column (pre-activate with 1 mL of ethanol and 2 mL of water) while retaining the 18O water in the recovery vessel.
    3. Allow potassium carbonate solution from No.1 vessel (Figure 1) to flow through designated valves and ion-exchange column to exchange with [18F] fluoride, then elute into the reaction vessel. See Table 1 for solutions in the different vessels.
    4. Dissolve [18F] fluoride and a cryptand-based phase-transfer catalyst pre-loaded into the No.2 vessel in the reaction vessel.
    5. Open the designated valve. Subject the reaction mixture to vacuum distillation under nitrogen blowing at 85 °C for 8 min, followed by nitrogen blowing at 110 °C for 4 min to eliminate residual water.
    6. Add the precursor from the No.3 vessel into the No.12 vessel and heat to 130 °C for 10 min. The radiosynthesis of 18F-AV-1451 is shown in Figure 2.
    7. Cool the reaction mixture to 50 °C, then open the designated valves to restore atmospheric pressure.
    8. Flush the reaction mixture into the No.14 vessel using a volume of 3 mL HPLC mobile phase (25% ethanol aqueous solution, pH adjusted to 2.0) sourced from No.5 and No.6 vessels. Open the designated valves to enable the ingress of the mixture into the HPLC loop under helium pressure.
      1. Introduce the product into the HPLC semi-preparative column and elute with the mobile phase at a flow rate of 5 mL/min. Observe the eluent using UV (λ = 254 nm) and radioactivity counters.
    9. Collect the product into the round-bottom flask via the designated valve.
    10. Entrap and retain the product within the C18 column (activated by 5 mL of ethanol and 10 mL of water).
    11. Open the designated valve, wash the column with water from the No.9 vessel into the waste container, and then rinse into the product bottle with solution from No.8 and No.7 vessels.
    12. Pass 18F-AV-1451 through a 0.22 µm liquid filter membrane into the collection bottle in the dispensing hot cell under helium pressure.
  2. Quality control
    NOTE: Perform quality control on three consecutive batches of the product. Ensure that the quality control of the product meets the 2020 edition of Pharmacopoeia of the People's Republic of China criteria (see Table of Materials).
    1. Conduct visual inspection by placing the product behind lead glass and inspecting the color and clarity.
    2. Determine the pH value of the product using precision pH test paper.
    3. Use HPLC to analyze the radiochemical purity of the product8,16.
    4. Analyze the radioactive nuclear purity of the product using the gamma spectrometer method17.
    5. Measure the half-life of the product accurately according to the Pharmacopoeia of the People's Republic of China13.
    6. Apply a pressure of 0.34 MPa to the sterile filter membrane (step 1.1.12) to test its sealing and integrity.
    7. Perform sterility and endotoxin tests using bacterial culture and the horseshoe crab reagent method23.
    8. Test the cryptand-based phase-transfer catalyst residue using the potassium iodoplatinate method. Analyze the content of acetone, acetonitrile, and DMSO in the product using a gas chromatograph8,16.
      NOTE: Ensure that no other peaks appear except 0.511 MeV and 1.022 MeV.

2. Pre-examination guidelines

NOTE: Participants were included if they had a present concern regarding a change in cognition and exhibited impairment in one or more cognitive domains while maintaining independence in functional abilities25. Eligibility required a Mini-Mental State Examination (MMSE) score between 0 and 20 and amyloid protein positivity, confirmed through an abnormal cerebrospinal fluid (CSF) Aβ42 or Aβ42/Aβ40 ratio or a positive amyloid positron emission tomography (PET) scan6,20. Exclusion criteria encompassed a diagnosis of vascular disease, depression, traumatic brain injury, psychotic disorders, or other conditions associated with cognitive decline5. Participants with contraindications to pacemakers, ferromagnetic substances, or foreign objects posing a mobility hazard, as well as those unable to undergo MRI imaging, were excluded. Additional exclusion criteria included intolerance to gadolinium contrast agents and the presence of severe renal insufficiency21.

  1. Instruct subjects to refrain from alcohol, caffeine, medication, or any strenuous exercise or activity for 24 h before the study. Maintain a stable physiological state (e.g., biorhythms, brain function tasks) to ensure data accuracy.
  2. Allow subjects to consume water and food before the examination, as these do not interfere with tau PET/MR imaging.
  3. Discontinue neurologic-related drugs for at least 12 h before imaging.
  4. Advise subjects to avoid wearing metal jewelry or clothing with metal buttons or zippers on the day of the examination.
    NOTE: Ensure that the patient is accompanied by a family member, brings previous examination records, and informs medical staff about medication use.

3. Preparation for scanning

  1. Verify the application form to confirm general information, examination purpose, and program. Ensure that all necessary preparations have been completed. Register and file the details.
  2. Obtain informed consent for PET/MR imaging from the subject or a family member. Inform the subject of the purpose, procedure, risks, and benefits.
  3. Conduct a detailed medical history review, record the subject's height, weight, and blood concentration, and confirm the absence of contraindications to MR examination. 
  4. Establish an intravenous line in a peripheral superficial vein or access a port catheter.
  5. Before administering 18F-AV-1451, verify all information again to prevent errors.
  6. Inject 18F-AV-1451 at 3.7-5.5 MBq/kg slowly through the intravenous access. Flush the tube with an appropriate amount of saline to minimize radioactive tracer residue. Apply compression to the injection site to prevent fluid leakage.
  7. Record the injection time, site, and activity.
  8. After completing the injection, initiate audio-visual closure. Dim the lights in the waiting
    room and set the temperature to approximately 22 °C. Instruct the subject to rest in bed with eyes closed for 80 min, avoiding talking, eating, or chewing during this period.

4. PET/MRI scanning

  1. Instruct the subject and companion to remove all metallic objects, including mobile phones, headgear, dentures, glasses, watches, wallets, and coins, before the examination. Do not allow wheelchairs, stretchers, examination beds, oxygen cylinders, or monitoring equipment in the examination room.
  2. Provide earplugs to the subject and position them supine on the PET/MRI table with a head/neck coil enclosing the cervical region. Use a specialized headrest or sponge pad to stabilize the head, minimizing movement and ensuring comfort.
    NOTE: Administer an appropriate dose of sedative medication, if necessary, based on neurological evaluation.
  3. Position the subject with arms down and instruct them to use the alarm device in case of discomfort.
  4. Review the images to confirm that the head is centered in the scanner, aligned with the center of the coil, and positioned consistently relative to the neck.
  5. Use an 8-channel head and neck union coil for imaging.
  6. Acquire 3D brain volumetric T1-weighted sequences with high resolution and high signal-to-noise ratio (SNR) using a spoiled gradient-recalled sequence. Set the following parameters:
    1. Repetition time (TR) = 8.5 ms; Echo time (TE) = 3.2 ms; Inversion time (TI) = 450 ms; Flip angle = 12°; Voxel size = 1 × 1 × 1 mm³; Field of view (FOV) = 256 mm; Matrix size = 256 × 256; Slice thickness = 1 mm.
    2. Acquire axial PROPELLER T2-weighted sequences with the following parameters: TR = 6837 ms; TE = 132 ms; Flip angle = 142°; FOV = 240 mm; Matrix size = 416 × 416; Slice thickness = 5 mm.
      NOTE: PET scanning uses a single bed position, covering the entire brain from the foramen magnum to the top of the skull.
  7. Acquire 20-min PET images simultaneously.
  8. Perform PET scanning in 3D acquisition mode.
  9. Use volumetric scanning for PET imaging.
  10. Perform MR imaging attenuation correction using a zero echo time (ZTE) pulse sequence to segment bone, air, and soft tissue.
  11. Acquire PET data using the time-of-flight ordered subset expectation maximization (OSEM) for image reconstruction20,23. Use the following parameters:
    1. Matrix size = 192 × 192; 28 subsets with 6 iterations; FOV = 350 × 350 mm; Full-width at half maximum (FWHM) = 3.0 mm.
  12. Calculate standardized uptake value (SUV) using the formula20,23:
    SUV = (Sphere activity (Bq/ml) × Body weight (kg)) / Injected dose.

5. Image interpretation

  1. Visually assess all PET/MR images independently by at least two experienced nuclear medicine physicians blinded to the clinical diagnosis.
  2. Identify brain lobes exhibiting abnormal structural changes and protein deposition.
  3. Repeat the visual assessment until a final consensus is reached.
  4. Define a "positive scan" as an increased 18F-AV-1451 uptake in any or all cortical regions. Define a "negative scan" as the absence of 18F-AV-1451 uptake in all cortical regions.
  5. Define atrophy in the medial temporal lobe, particularly in the hippocampus on MRI, as neurodegeneration20,25.

תוצאות

18F-AV-1451 synthesis results
The one-step synthesis of 18F-AV-1451 under optimized reaction conditions increased the synthesis yield to 25.7% ± 5.8%. The total reaction time was 70 min. A typical semi-preparative HPLC and UV spectrum is shown in Figure 3, where peak 2 represents the product peak.

Quality test results
For three consecutive batches, the quality control results were as follows:...

Discussion

In this methodological manuscript, we have introduced an updated radiosynthesis of 18F-AV-1451 for tau PET imaging and the techniques for 18F-AV-1451 PET/MRI image acquisition, and provided the potential utility of 18F-AV-1451 PET/MR for evaluating AD. Conventional brain CT or MRI usually provides macroscopic anatomic structural assessment, which limits the assessment of disease progression and prediction of prognosis. PET is a neuroimaging tool that makes it possible to me...

Disclosures

The authors have no conflict of interest to declare.

Acknowledgements

This work was supported by grants from the Key Research and Development Plan of Liaoning Province (2019JH/10300010) and the Applied Basic Research Program of Liaoning Province (2022JH2/101500011).

Materials

NameCompanyCatalog NumberComments
18O-rich waterTaiyo Nippon Sanso,Japan24-0091
2020 edition of Pharmacopoeia of the People's Republic of China NAhttps://english.nmpa.gov.cn/2020-07/03/c_538689.htm
AcetonitrileABX,GermanyTF-A1-231207002
air filter membrane (Millex-25)Merck,GermanySLFGN25VS
Boc-protected-precursor Huayi,Jiangsu,ChinaNPPI-95-0001A
C18 columnWaters,USA186004770
CyclotronGE,USAMINITRACE
Dimethyl sulfoxide (DMSO)Bailing Wei Technology,Beijing,China984549
EtOHABX,Germany10009216
EtOH for isolationSinopharm Chemical Reagent,Shanghai,China400212682
Gas chromatographyTianmei,Shanghai,ChinaGC-7900 
HPLCSYKNM,GermanyS-1122
Hydrochloric acidSinopharm Chemical Reagent,Shanghai,China10011018
K2CO3 SolutionABX,GermanyTF-K1-230724001
Kryptofix[2.2.2](K222)ABX,Germany800
liquid filter membrane (Millex-GV)Merck,GermanySLGVR33RB
Oasis HLB solid-phase extraction (SPE) columnWaters,USA186003908
PET/MRGE,USASigna
QMA columnWaters,USA186002350
Radionuclide activityCapintec,USACRC-25R

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