In this paper the concept of molecular imaging is introduced, and its importance is addressed. Besides, the key points of molecular imaging are briefly reviewed from a view of engineering. Particular emphasis is given to the analysis of the function and the position of traditional medical imaging modalities in the era of molecular imaging. Finally a discussion is made for the further development of medical imaging modalities along the line of molecular imaging.
Diagnostic Imaging ; methods ; Molecular Imaging

Magnetic Particle Imaging (MPI) is a new medical imaging tool, which was born at the beginning of the 21st century. Compared with traditional imaging techniques, the preliminary research indicates that MPI shows higher sensitivity, resolution and imaging speed. This article presents the principle of MPI, its recent development from three different perspectives is introduced.
Diagnostic Imaging ; Magnetic Phenomena ; Magnetic Resonance Imaging ; methods ; Molecular Imaging

At the summer workshop of the Korean Endocrine Society held in 2016, some examples of protein experiments were discussed in the session entitled “All about working with proteins.” In contrast to what the title suggested, it was unrealistic to comprehensively discuss all protein analytical methods. Therefore, the goal was to outline protein experimental techniques that are useful in research or in bench work. In conversations with clinicians, however, I have always felt that researchers who do not engage in bench science have different demands than those who do. Protein research tools that are useful in bench science may not be very useful or effective in the diagnostic field. In this paper, I provide a general summary of the protein analytical methods that are used in basic scientific research, and describe how they can be applied in the diagnostic field.
Chromatography ; Education ; Immunoenzyme Techniques ; Methods* ; Molecular Imaging

Atherosclerosis plaque is the underline cause of ischemic stroke and acute coronary syndrome. In this article, the applications of molecular imaging in vulnerable plaque are reviewed.
Atherosclerosis ; diagnosis ; pathology ; Humans ; Molecular Imaging ; methods

In vivo fluorescence molecular imaging plays a more and more important role in the observation of diseases, drug research and biology research because of its low cost, simplicity and no ionizing radiation to biological tissue. Herein, the most important parts of the optical fluorescence molecular imaging and their advances are summarized, including fluorescent molecular probes, imaging systems and reconstruction algorithms. The application and development trend of this technology are also introduced in this paper.
Algorithms ; Fluorescent Dyes ; Molecular Imaging ; methods

Nanobodies are derived from the variable domain of the heavy-chain antibodies (HCAbs) that occur naturally in the serum of camels. Using nanobody-based probes, several imaging techniques such as radionuclide-based, optical and ultrasound have been employed for visualization of target expression in various disease models. Combined with application and clinical data of nanobody in molecular imaging in recent years, this paper introduces its application in the diagnosis of diseases and the future development as a novel molecular imaging tool.
Humans ; Immunoglobulin Heavy Chains ; Molecular Imaging ; methods ; Molecular Probes ; Nanotechnology

Advances in radionuclide tracers have allowed for more accurate imaging that reflects the actions of numerous neurotransmitters, energy metabolism utilization, inflammation, and pathological protein accumulation. All of these achievements in molecular brain imaging have broadened our understanding of brain function in Parkinson's disease (PD). The implementation of molecular imaging has supported more accurate PD diagnosis as well as assessment of therapeutic outcome and disease progression. Moreover, molecular imaging is well suited for the detection of preclinical or prodromal PD cases. Despite these advances, future frontiers of research in this area will focus on using multi-modalities combining positron emission tomography and magnetic resonance imaging along with causal modeling with complex algorithms.
Brain ; diagnostic imaging ; Humans ; Molecular Imaging ; methods ; trends ; Neuroimaging ; methods ; trends ; Parkinson Disease ; diagnostic imaging

Molecular imaging technology, an advanced research area of imaging, can provide real-time, non-invasive image information of the target site in molecular level. The key of the molecular imaging technology is molecular probe. Aptamers are short oligonucleotides with high affinity and specificity to the target molecules. The targeting ability, stability and safety of aptamers are superior to traditional antibodies so that aptamers show prosperous usages in targeting drug delivery and disease diagnostics. Therefore, aptamers are considered to be an extremely ideal probes, which can guide quantum dots, magnetic nanoparticles and ultrasound contrast agents on the targets and realize optical, magnetic resonance, ultrasonic multimodal and multifunctional imaging. All of the advantages can further promote the application of molecular imaging in disease treatment and diagnosis. In this paper, we review recent developments in the application of aptamers as molecular probes in major branches of molecular imaging.
Animals ; Aptamers, Nucleotide ; Contrast Media ; Humans ; Molecular Imaging ; methods ; trends ; Molecular Probes ; SELEX Aptamer Technique

There are many deficiencies in forensic traumatic molecular markers detected by the techniques of traditional immunohistology and molecular biology, because these markers are isolated and obscure of the mechanism of interaction. The imaging mass spectrometry (IMS) is more suitable for the forensic molecular markers using function of screening, analysis and graphical representation. In this paper, the techniques and the latest research in screening and identification of typical molecular markers by IMS based on matrix-assisted laser adsorption/ionization time-of-flight mass spectrometry (MALDI-TOF-MS) are reviewed. And its application values in forensic injury are discussed.
Biomarkers/analysis* ; Diagnostic Imaging ; Molecular Biology ; Molecular Weight ; Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization/methods*

During the last decade, researchers have made great progress in the development of new image processing technologies for gastrointestinal endoscopy. However, diagnosis using conventional endoscopy with white light optical imaging is essentially limited, and ultimately, we still rely on the histopathological diagnosis from biopsy specimens. Molecular imaging represents the most novel imaging methods in medicine, and the future of endoscopic diagnosis is likely to be impacted by a combination of biomarkers and technology. Endoscopic molecular imaging can be defined as the visualization of molecular characteristics with endoscopy. These innovations will allow us not only to locate a tumor or dysplastic lesion but also to visualize its molecular characteristics and the activity of specific molecules and biological processes that affect tumor behavior and/or its response to therapy. In the near future, these promising technologies will play a central role in endoluminal oncology.
Biological Processes ; Biopsy ; Diagnosis ; Endoscopy ; Endoscopy, Gastrointestinal ; Gastrointestinal Neoplasms ; Methods ; Molecular Imaging* ; Optical Imaging ; Biomarkers