The history of magnetic resonance imaging and its reflections in Acta Radiologica.

The first reports in Acta Radiologica on magnetic resonance imaging (MRI) were published in 1984, four years after the first commercial MR scanners became available. For the first two years, all MR papers originated from the USA. Nordic contributions started in 1986, and until 2020, authors from 44 different countries have published MR papers in Acta Radiologica. Papers on MRI have constituted, on average, 30%-40% of all published original articles in Acta Radiologica, with a high of 49% in 2019. The MR papers published since 1984 document tremendous progress in several areas such as magnet and coil design, motion compensation techniques, faster image acquisitions, new image contrast, contrast-enhanced MRI, functional MRI, and image analysis. In this historical review, all of these aspects of MRI are discussed and related to Acta Radiologica papers.

The development of musculoskeletal radiology for 100 years as presented in the pages of Acta Radiologica.

During the last 100 years, musculoskeletal radiology has developed from bone-only radiography performed by everyone to a dedicated subspecialty, still secure in its origins in radiography but having expanded into all modalities of imaging. Like other subspecialties in radiology, it has become heavily dependent on cross-sectional and functional imaging, and musculoskeletal interventions play an important role in tumor diagnosis and treatment and in joint diseases. All these developments are reflected in the pages in Acta Radiologica, as shown in this review.

The development of breast radiology: the Acta Radiologica perspective.

The encouraging results of modern breast cancer care builds on tremendous improvements in diagnostics and therapy during the 20th century. Scandinavian countries have made important footprints in the development of breast diagnostics regarding technical development of imaging, cell and tissue sampling methods and, not least, population screening with mammography. The multimodality approach in combination with multidisciplinary clinical work in breast cancer serve as a role model for the management of many cancer types worldwide. The development of breast radiology is well represented in the research published in this journal and this historical review will describe the most important steps.

MRI exploiting frequency-modulated pulses and their nonlinear phase.

Frequency-modulated (FM) pulses can provide several advantages over conventional amplitude-modulated pulses in the field of MRI; however, the manner in which spins are manipulated imprints a quadratic phase on the resulting magnetization. Historically this was considered a hindrance and slowed the widespread adoption of FM pulses. This article seeks to provide a historical perspective of the different techniques that researchers have used to exploit the benefits of FM pulses and to compensate for the nonlinear phase created by this class of pulses in MRI. Expanding on existing techniques, a new method of phase compensation is presented that utilizes nonlinear gradients to mitigate the undesirable phase imparted by this class of pulses.

CMR publications from China of the last more than 30 years.

Cardiovascular magnetic resonance (CMR) is a non-invasive imaging technology, gradually playing an irreplaceable role in the diagnosis and treatment of cardiovascular diseases. This review demonstrates the progress and research highlights of Chinese CMR publications of the last more than 30 years. At initial stage (1988 to 1997), CMR was introduced to evaluate cardiac anatomy, blood flow and ventricular function roughly in China. In the development stage (1998-2007), CMR began to play an important role in the diagnosis of cardiovascular and pericardial disease with the emergence of new techniques, such as myocardial perfusion imaging and magnetic resonance angiography. Since 2008, the development of CMR in China has reached a prosperous period. Cardiovascular disease can be both qualitatively and quantitatively assessment by CMR "one-stop" multi-parameter imaging, including the morphology, function, myocardial perfusion, tissue characteristics, metabolism and even the microstructure of myocardial fibers, which provides comprehensive assessment of the severity, risk stratification and prognosis of cardiovascular disease. Although CMR in China developed very rapidly in recent years, China still needs to put more efforts in CMR research and make greater contributions to the development of CMR in the world.

Mapping language dominance through the lens of the Wada test.

The sodium amytal test, or Wada test, named after Juhn Wada, has remained a pillar of presurgical planning and is used to identify the laterality of the dominant language and memory areas in the brain. What is perhaps less well known is that the original intent of the test was to abort seizure activity from an affected hemisphere and also to protect that hemisphere from the effects of electroconvulsive treatment. Some 80 years after Paul Broca described the frontal operculum as an essential area of expressive language and well before the age of MRI, Wada used the test to determine language dominance. The test was later adopted to study hemispheric memory dominance but was met with less consistent success because of the vascular anatomy of the mesial temporal structures. With the advent of functional MRI, the use of the Wada test has narrowed to application in select patients. The concept of selectively inhibiting part of the brain to determine its function, however, remains crucial to understanding brain function. In this review, the authors discuss the rise and fall of the Wada test, an important historical example of the innovation of clinicians in neuroscience.

Story telling of myocarditis.

Myocarditis was discovered as heart disease at autopsy with the use of microscope. In 1900, with the name of acute interstitial myocarditis, Carl Ludwig Alfred Fiedler first reported the history of a sudden cardiac heart failure, in the absence of coronary, valve, pericardial disease or classical specific infections with multiorgan involvement. He postulated a peculiar isolated acute inflammation of the myocardium with poor prognosis due to invisible microorganisms, which years later would have been identified as viruses. Subsequent revision of Fiedler original histologic slides by Schmorl showed cases with either lymphocytic or giant cell infiltrates. The in vivo diagnosis became possible with the right heart catheterism and endomyocardial biopsy. Employment of immunohistochemistry and molecular techniques improved the diagnosis and etiology identification. The mechanism of myocyte injury by coxsackie virus was identified in protease 2A coded by the virus and disrupting the dystrophin in the cytoskeleton. Both RNA and DNA viruses may be cardiotropic, and coxsackie and adenovirus share a common receptor (CAR). Unfortunately, vaccination is not yet available. Cardiac Magnetic Resonance is a revolutionary diagnostic tool by detecting edema, of myocardial inflammation. However endomyocardial biopsy remains the gold standard for etiological and histotype diagnosis, with limited sensitivity due to sampling error. Viral lymphocytic fulminant myocarditis may not be fatal and the employment of mechanical assistant device - ECMO in acute phase for temporary support may be lifesaving with good prognosis.

History of Subcortical Cognitive Impairment.

The representation of cognitive function in the cerebral cortex has a long and cherished history, but much evidence also supports a critical role of subcortical structures in the operations of cognition. The idea of subcortical dementia, first proposed in 1932 and substantially expanded in the 1970s, is the most prominent formulation intended to capture the phenomenology of cognitive impairment attributable to subcortical involvement. Despite criticism highlighting its imprecision, subcortical dementia has endured as a useful general concept assisting the classification of dementia syndromes based on the primary site(s) of neuropathology. As neuroscientific knowledge expanded with the advent of modern structural and functional neuroimaging, a more detailed understanding of the contributions of specific subcortical regions emerged, such that the cognitive affiliations of the basal ganglia, thalamus, cerebellum, brainstem, and white matter are all better defined. Important advances have been made by the study of both neurodegenerative diseases and focal lesions. Today, the complex admixture of cortical and subcortical foundations of cognition is increasingly well appreciated, and has been conceptually organized within the broadly inclusive notion of distributed neural networks. These networks are thought to integrate cortical and subcortical gray and white matter structures throughout the brain into functional neuronal ensembles subserving various domains of cognition. In this light, specific disorders of subcortical regions produce cognitive sequelae that can be usefully analyzed within the context of networks that involve key cortical regions as well. The study of subcortical contributions to cognition has been highly informative in expanding neurobehavioral thinking to include regions beyond the cerebral cortex, adding nuance and sophistication to the conceptualization of brain-behavior relationships.

Low-field MRI: An MR physics perspective.

Historically, clinical MRI started with main magnetic field strengths in the ∼0.05-0.35T range. In the past 40 years there have been considerable developments in MRI hardware, with one of the primary ones being the trend to higher magnetic fields. While resulting in large improvements in data quality and diagnostic value, such developments have meant that conventional systems at 1.5 and 3T remain relatively expensive pieces of medical imaging equipment, and are out of the financial reach for much of the world. In this review we describe the current state-of-the-art of low-field systems (defined as 0.25-1T), both with respect to its low cost, low foot-print, and subject accessibility. Furthermore, we discuss how low field could potentially benefit from many of the developments that have occurred in higher-field MRI. In the first section, the signal-to-noise ratio (SNR) dependence on the static magnetic field and its impact on the achievable contrast, resolution, and acquisition times are discussed from a theoretical perspective. In the second section, developments in hardware (eg, magnet, gradient, and RF coils) used both in experimental low-field scanners and also those that are currently in the market are reviewed. In the final section the potential roles of new acquisition readouts, motion tracking, and image reconstruction strategies, currently being developed primarily at higher fields, are presented. Level of Evidence: 5 Technical Efficacy Stage: 1 J. Magn. Reson. Imaging 2019.

Contributions of Magnetic Resonance Imaging to Gastroenterological Practice: MRIs for GIs.

MRI has transformed from the theoretical, investigative realm to mainstream clinical medicine over the past four decades and has become a core component of the diagnostic toolbox in the practice of gastroenterology (GI). Its success is attributable to exquisite contrast and the ability to isolate specific proton species through the use of different pulse sequences (i.e., T1-weighted, T2-weighted, diffusion-weighted) and exploiting extracellular and hepatobiliary contrast agents. Consequently, MRI has gained preeminence in various GI clinical applications: liver and pancreatic lesion evaluation and detection, liver transplantation evaluation, pancreatitis evaluation, Crohn's disease evaluation (using MR enterography) rectal cancer staging and perianal fistula evaluation. MR elastography, in concert with technical innovations allowing for fat and iron quantification, provides a noninvasive approach, or "MRI virtual liver biopsy" for diagnosis and management of chronic liver diseases. In the future, the arrival of ultra-high-field MR systems (7 T) and the ability to perform magnetic resonance spectroscopy in the abdomen promise even greater diagnostic insight into chronic liver disease.

Focused ultrasound in neurosurgery: a historical perspective.

Focused ultrasound (FUS) has been under investigation for neurosurgical applications since the 1940s. Early experiments demonstrated ultrasound as an effective tool for the creation of intracranial lesions; however, they were limited by the need for craniotomy to avoid trajectory damage and wave distortion by the skull, and they also lacked effective techniques for monitoring. Since then, the development and hemispheric distribution of phased arrays has resolved the issue of the skull and allowed for a completely transcranial procedure. Similarly, advances in MR technology have allowed for the real-time guidance of FUS procedures using MR thermometry. MR-guided FUS (MRgFUS) has primarily been investigated for its thermal lesioning capabilities and was recently approved for use in essential tremor. In this capacity, the use of MRgFUS is being investigated for other ablative indications in functional neurosurgery and neurooncology. Other applications of MRgFUS that are under active investigation include opening of the blood-brain barrier to facilitate delivery of therapeutic agents, neuromodulation, and thrombolysis. These recent advances suggest a promising future for MRgFUS as a viable and noninvasive neurosurgical tool, with strong potential for yet-unrealized applications.