Transforming Patient Care: The Definitive Guide to the Top Benefits of a PACS System in Radiology Departments

Today’s radiology departments function under extreme and increasing pressure. Growing volumes of imaging, spurred by an aging population and the growth of diagnostic capabilities, have established an environment in which efficiency is not only desirable, but necessary for survival.1 In this high-stakes environment, the Picture Archiving and Communication System (PACS) has matured from a cutting-edge technology to the necessary central nervous system of any modern medical imaging operation. It is a basic transition from the clunky, error-ridden, and wasteful paradigm of physical film to a sleek, digital environment.

3 A contemporary pacs radiology system is much more than an electronic filing cabinet; it’s an active platform with the potential to revolutionize clinical workflows, enhance diagnostic precision, facilitate collaboration, and ultimately, revolutionize the quality of patient care. This report offers a comprehensive guide to the comprehensive advantages of a pacs system radiology departments can harness, analyzing its operational, clinical, and financial effects, and looking at its path ahead in an age of cloud computing and AI.

First, What is PACS System? Breaking Down the ‘PACS Meaning Medical’ Experts Should Know

Fundamentally, the pacs meaning medical experts know is an abbreviation for Picture Archiving and Communication System.5 It is an advanced imaging device in the medical field designed to facilitate economical storage, quick retrieval, easy access, and safe distribution of diagnostic images from a variety of modalities.8 The key and most revolutionary role of a pacs radiology system has the function of acting as a total, computer-based replacement for the functions of traditional radiological film so that the manual, physical steps which characterized imaging departments for decades would be eliminated.

10 The technological foundation on which a pacs system radiology installation is able to operate together is the DICOM (Digital Imaging and Communications in Medicine) standard.8 DICOM is the medical imaging lingua franca, an internationally accepted protocol that specifies the format for the storage, printability, and transport of images, along with their related data.7 Standardization is the key driver of interoperability, making sure that images created by a Siemens CT scanner, a GE MRI unit, and a Philips X-ray machine are all able to be acquired, stored, viewed, and processed seamlessly within one integratedpacs radiology environment.

12 Film Jackets to Digital Files: The Central Reason for PACS Radiology

The most fundamental modification brought by a pacs radiology system is the transformation of “hard copy replacement”.8 Such technology completely eliminates the process of manually filing, retrieving, searching for, and physically moving film jackets from storerooms to reading rooms and clinical wards.5 This change has immediate and profound effects. It releases large tracts of valuable hospital real estate once committed to cumbersome film archives and, most importantly, reduces the ongoing and expensive risk of films’ loss, misplacement, or damage—a frequent cause of delay and frustration with the analog system.

6 By digitizing the entire imaging chain, a pacs radiology system quite literally reduces the physical and temporal barriers of film-based workflows. It provides authorized clinicians with instant access to images and accompanying reports from anywhere on the network, be it within the hospital or even around the world.8 This instant access is the enabling feature upon which virtually all other operational and clinical benefits are predicated, transmogrifying a linear, delay-ridden process into an active, on-demand service.

The Four Pillars of a Contemporary PACS System Radiology Departments Rely Upon

A contemporary pacs system radiology departments rely on is not one application of software but an integrated platform of four critical elements functioning together.6 The strength and dependability of the overall system are only as good as its weakest component, which makes an integrated understanding of this architecture pivotal to successful implementation and administration.

Image Acquisition Modalities and Gateways: This is where the digital journey begins. It consists of the imaging devices themselves—i.e., Magnetic Resonance Imaging (MRI), Computed Tomography (CT), Positron Emission Tomography (PET), and Digital Radiography (DR)—as well as the acquisition gateway computers. The gateways take the raw image information from the modality, translate it to the DICOM standard format, and send it to the PACS server for storage in a secure manner.

 8 The Secure Network: This is the communications spine of the pacs radiology system. It is a fast, secure network with the charge of moving vast amounts of image data among the acquisition modalities, the central archive, and the diagnostic workstations. Its design needs to be strong and contain adequate bandwidth to support the large file sizes of contemporary imaging studies without causing performance bottlenecks that would slow down patient care.

12 Diagnostic Workstations: These are the control centers for radiologists and other medical professionals. A workstation is made up of high-resolution medical-grade monitors and powerful computer servers running specialized pacs radiology software. Such software offers a rich set of tools for viewing, manipulating, analyzing, and reporting images, with the support for a detailed and interactive diagnostic process.

6 The Archive and Server: This is the core of the PACS—a centralized, secure repository for all digital images and related reports. Contemporary archives tend to use a tiered storage architecture. Newer, more-frequently used studies are stored on “short-term” storage (e.g., high-speed disk arrays) for quick retrieval, while older, less-frequently used prior studies are moved to less-expensive “long-term” storage devices.

12 These four pillars are not independent of each other; they exist in a tightly coupled system whose performance affects each other. As an example, replacing a CT scanner with a newer version that captures images of higher resolution and more slices will create much larger data files.12 One such decision creates the ripple effect throughout the entire PACS environment. The network needs to be able to handle these large files without delay.19 The short-term archive needs to be capable of ingesting and storing them.20 Lastly, the diagnostic workstation needs the processing capability to load and work with these huge datasets efficiently.

8 A failure to account for these downstream effects when adding one component can create disastrous workflow bottlenecks, with a radiologist sitting waiting for images to come up and spoiling the advantage of the new scanner. This illustrates the fact that a decision to buy and implement a pacs system radiology environment should be informed by a systems-thinking strategy, as a unified, cohesive platform instead of as a series of disparate products.

The Operational Revolution: How PACS Radiology Streamlines Your Workflow

Breaking Down Bottlenecks and Speeding Diagnosis

The most direct and tangible operational advantage of a pacs radiology system is the significant speeding up of the entire process of diagnosis. Through offering instant access to images seconds after they are taken, PACS does away with the ubiquitous “film hunt,” during which employees would waste precious time physically searching for, retrieving, and moving film jackets.7 This one adjustment eliminates a significant cause of delay in patient treatment.

This increased efficiency has a direct impact on a dramatic reduction in report turnaround time (TAT)—the most important measure of the interval between exam completion and the resultant final diagnostic report available to the referring physician. By eliminating the logistical delays of film management and optimizing the presentation of images and information to the radiologist, a pacs system radiology environment can dramatically minimize this interval. These gains have been documented in studies, with one installation realizing an impressive 45% reduction in TAT for radiography within a single year of having adopted PACS.3 Quicker diagnoses result in quicker decision-making for treatment, and this directly enhances patient outcomes.

Smooth Integration with Your Current Hospital Systems (RIS, HIS, EHR)

Although having a stand-alone pacs radiology system is advantageous in itself, its full potential as a transformative tool is realized by integrating it thoroughly into other primary hospital information systems. When a PACS is well integrated with the Radiology Information System (RIS), the Hospital Information System (HIS), and the Electronic Health Record (EHR), it builds a harmonious and holistic patient record.3 This integration, normally made possible by the Health Level Seven (HL7) messaging standard, promotes a two-way exchange of information, connecting diagnostic images directly with reports, physician orders, lab results, and the entire patient history.

16 This integration provides strong workflow automation, which de-burdens repetitive tasks and can also minimize errors due to human intervention. For instance, when an imaging order is entered by a physician in the RIS or HIS, it can trigger automatically to fill a worklist on the respective modality of imaging (a feature referred to as Modality Work List). This eliminates the necessity for a technologist to re-key patient demographics, a frequent source of error that may cause mislabeled studies.15 With the exam completed and images in the PACS, it is possible for the system to automatically populate the RIS with the exam status.

8 Such a degree of integration does not simply make the department more efficient. It reframes the radiology department as a solitary, specialized diagnostic service, repositioning it instead as a core, essential hub within the larger data environment of the hospital. Information flow is not simply uni-directional; radiology gets electronic orders and, reciprocally, pushes mission-critical visual information and expert analysis back into the master patient record, where they are available to every other clinical service, from the emergency department to surgery and oncology.

2 By becoming the single source and distributor of diagnostic imaging information, an integrated radiology department then becomes a vital node in virtually all patient care paths. This data-driven position raises the strategic value of the department, and the PACS administrator and radiology leadership become central stakeholders in hospital-wide decisions related to patient flow, clinical protocols, and even financial performance

.

Power of a Centralized PACS Dashboard for Effective Management

The contemporary pacs dashboard acts as the command and control hub for the entire imaging operation, providing customized views for varying user roles. For a PACS administrator, the pacs dashboard offers real-time, high-level system health and performance. It shows important metrics like storage usage and capacity, network bandwidth, image transfer speed, and user activity logs. This permits proactive system administration, allowing administrators to spot and respond to potential problems—such as running out of storage space or network overload—before they affect clinical operations.

25 To clinicians, the pacs dashboard represents the principal user interface to perform their daily tasks. For radiologists, this appears as a smart and perhaps configurable worklist that sorts cases by priority, modality, or some other attribute, reducing the time required to find the next study to read.23 A simple interface with efficient navigation, robust search features, and single-click access to high-level tools is intended to minimize cognitive load and the number of mouse clicks per study to enable radiologists to concentrate their attention on diagnosis instead of on system operation.

27 Boosting Clinical Excellence: The Diagnostic Advantages of a PACS Radiology System

In addition to the substantive operational benefits, a pacs radiology system empowers clinicians with robust tools that bolster their diagnostic abilities, resulting in more accurate and confident diagnoses and promoting a more collaborative style of patient care.

Advanced Image Analysis and Manipulation Tools

A digital pacs system radiology environment propels diagnosis far beyond the fixed limitations of a physical lightbox. The pacs radiology software provides clinicians with a dynamic set of image manipulation capabilities heretofore impossible with film.7 User-friendly standard tools enable instant zooming in on tiny details, panning across broad images, and rotating or flipping orientation to get the best anatomical view.30 A powerful capability is adjusting brightness and contrast (window/level), as it enables the viewer to digitally alter the grayscale range to emphasize various tissue densities. This can uncover subtle pathologies, such as soft tissue abnormalities or faint fractures, that may be undetectable on a routine film image.

6 Advanced visualization is also present in contemporary pacs radiology software. Multiplanar Reconstruction (MPR) enables radiologists to take volumetric data from a CT or MRI scan and reformat it into other anatomical planes (e.g., sagittal, coronal) without the need to re-scan the patient. 3D volume rendering produces interactive, three-dimensional reconstructions of organs or vascular structures, something that is extremely useful for planning surgery. Additionally, accurate digital measurement tools allow for reproducible and accurate tracking of lesion size over time, an important function in oncology for evaluating response to therapy.

7 These tools revolutionize the nature of radiologic interpretation. Film is a static, fixed image. The radiologist’s function is largely one of passive observation and pattern recognition. With a PACS, the radiologist is an active investigator, interrogating dynamically the dataset. They are able to dissect virtually a 3D volume, tweak viewing parameters to respond to particular clinical queries, and modify the data to elicit the most diagnostic information. This converts the diagnostic process from a straightforward observation to an interactive quest, requiring greater involvement and proficiency but delivering far more comprehensive diagnostic product.

Enhancing Diagnostic Accuracy and Confidence

Perhaps the most significant clinical advantage of a pacs radiology system is the capability to present immediate access to a patient’s entire imaging history. With a few mouse clicks, a radiologist can access and project previous studies side-by-side with the current examination.30 This temporal comparison is crucial for nearly all aspects of interpretation. It enables examination of disease progression, evaluation of response to treatment, detection of new findings, and verification of stability. Access to this background information so readily available significantly enhances diagnostic certainty and accuracy.

Consistent access to images taken in the past also directly affects patient safety. If a clinician is assured that they can access a patient’s prior exams, they are much less likely to request an unnecessary or redundant repeat exam. This procedure not only saves healthcare expenses but, more significantly, decreases the patient’s total exposure to ionizing radiation from modalities such as CT and X-ray.6 In addition, the higher quality and manipulability of digital images decrease the rate of retakes due to technical difficulties such as under- or over-exposure, which were the major problems in film-based radiography.

17 Encouraging Collaboration for Improved Patient Outcomes

An actual film is only able to be in one location at once, providing a strong bottleneck for collaboration. A pacs radiology system breaks this impediment. Digital images are easily accessible to many approved users from various physical locations at the same time.6 This feature makes it possible for a radiologist in the reading room, a surgeon in the operating room, and a referring physician in his/her outpatient clinic simultaneously browse the same complicated case in real-time. The concurrent collaboration enables quicker, better-informed, and more thorough decision-making that is of utmost importance to complicated patient care.

4 This distant reach is also the underlying technology that makes teleradiology possible. Images taken at a small, rural medical center can be transmitted securely across the network to be read by a subspecialist radiologist in a large academic center hundreds of miles distant.8 This gives patients in underserved communities access to a level of diagnostic capability that would otherwise be unattainable, leveling the field for those seeking high-quality care.

36 A Tale of Two Infrastructures: Cloud PACS Cloud Based PACS vs. On-Premise PACS

If a healthcare organization is considering implementing or replacing a pacs radiology system, perhaps the most basic decision an organization has to make is the deployment model: a conventional, locally installed on premise pacs or a contemporary, web-accessible Cloud pacs cloud based pacs.

The Traditional Approach: Understanding the On-Premise PACS

An on premise pacs is an infrastructure model in which all the fundamental components—servers, storage hardware, network equipment, and software—are physically hosted in the hospital’s own data center.37 The healthcare institution buys, owns, and manages the entire system using this model.

The on premise pacs’ main benefits are direct control and independence of the network. The hospital’s IT department exercises total control over the data, security settings, and system upkeep. Since the system is on the local network, it works even in the event of an external internet failure, providing continuous access to on-site users. For those inside the hospital building, performance can be quicker and smoother as well, since data does not cross the public internet and therefore is less subject to latency-related problems.

37 But there are major negative aspects as well. Most inhibitive of the whole is the significant upfront capital cost (CapEx) needed to buy servers, storage arrays of high performance, and software licenses. Aside from the initial investment, there is considerable recurring operational expense of power, cooling, and the necessity of having a dedicated, specialized IT staff to administer, support, and update the system. Scalability is also a key challenge: growing storage capacity or increasing the number of users is typically a difficult, disruptive, and costly initiative that involves buying and implementing new hardware.

37 The Modern Standard: The Agility of Cloud PACS Cloud Based PACS

A Cloud pacs cloud based pacs solution is a paradigm change in infrastructure management. Under this model, the PACS software and, above all, the enormous image archive reside on remote servers that are controlled by a third-party vendor. The services are accessed securely from the internet.

6 The benefits of this approach are powerful and are compatible with current IT strategies:

Cost-Effectiveness: The Cloud The cloud based pacs model significantly alters the cost equation. It does away with a substantial initial capital outlay and is run on a subscription-based, operational expenditure (OpEx) paradigm. This standard monthly or annual fee usually encompasses software access, storage, maintenance, and support, rendering budgeting simpler and releasing capital for other clinical opportunities.

36 Effortless Scalability: This is likely the most meaningful operational benefit. With a Cloud pacs cloud based pacs, storage and computing capacities can be increased or decreased virtually in an instant as needed. As imaging volumes expand, the organization can merely upgrade its subscription level without the requirement of disruptive and expensive hardware purchasing and installation projects.

42 Greater Accessibility and Collaboration: By definition, a Cloud pacs cloud based pacs is intended to be accessed remotely. It allows approved users “anywhere, anytime” access to images and reports using any device connected to the internet. This is a huge facilitator for teleradiology, remote reading, and smooth collaboration among specialists across different facilities.

24 Strong Disaster Recovery and Security: Major cloud providers have highly advanced data centers with physical security, redundancy, and cybersecurity skills that are hard and costly for a single hospital to match. Data tends to be automatically copied and stored in backup locations dispersed across different geographic areas, which create strong, intrinsic disaster recovery abilities.

42 The main concerns for a cloud solution are its reliance on the availability of a solid, high-speed internet connection to function well and possible issues with long-term subscription fees, vendor lock-in, and sovereignty of data, based on the location of the vendor’s data centers.

51 Making the Right Choice for Your Facility

The choice between an on premise pacs and a Cloud pacs cloud based pacs is not one-size-fits-all. It is based on a meticulous consideration of the institution’s particular needs, which may encompass its size and volume of studies, the presence and competence of its IT resources, its economic model (preference for CapEx or OpEx), and its plans for future growth and expansion.39 The table below sets out in plain, at-a-glance terms a comparison of the two models on decision-making criteria of importance.

FeatureOn-Premise PACSCloud PACS Cloud Based PACS
Cost ModelHigh Upfront Capital Expenditure (CapEx)Predictable Operational Expenditure (OpEx)
ScalabilityLimited & Expensive; Requires new hardwareHigh & On-Demand; Adjusts with subscription
AccessibilityLocal network; Remote access requires VPNAnywhere with internet; Native remote access
MaintenanceFull responsibility of in-house IT staffManaged by the vendor; updates are automatic
SecurityIn-house responsibility for physical & cyberShared responsibility; vendor manages infrastructure
Disaster RecoveryRequires separate, expensive in-house setupOften built-in and geographically redundant

This contrast explains the trade-offs for IT directors and hospital administrators. The decision is frequently between the overall control and network autonomy of an on-premise solution and the financial agility, scalability, and accessibility of a cloud platform. For most contemporary healthcare enterprises, the elasticity and lessened IT burden of a Cloud pacs cloud based pacs make it the more tactical long-term option.

Security and Implementation: From PACS Testing to Secure PACS Login

Creating a Fort Knox for Patient Information: Security within PACS Radiology Software

Data security in healthcare is not just a technical necessity; it is a basic ethical and legal mandate. A pacs radiology system contains a massive repository of protected health information (PHI) and thus is a cyberattack-worthy high-value target.52 As such, tight security measures are not optional. 

A contemporary pacs radiology software solution should be constructed on a foundation of fundamental security principles, beginning with end-to-end data encryption. That way, all imaging data is encrypted “at rest” within the archive and “in transit” as it travels over the network so that it is unreadable to anyone who would seek to intercept it.20 Strict adherence to local data protection laws, such as the Health Insurance Portability and Accountability Act (HIPAA) in the United States, is required.

20 Sound security also means governing who is allowed in the system and what they are able to do when they are inside. This is where the pacs login procedure and succeeding access controls come in. The important features are:

Role-Based Access Control (RBAC): This is the concept of providing users with the minimal amount of access they need to support their job roles. For instance, the referring physician can see images and reports for his or her patients but cannot delete studies or modify system settings. This “least privilege” strategy decreases the potential for accidental data alteration and reduces the harm that can come from a breached account.

53 Multi-Factor Authentication (MFA): A password is no longer adequate protection. MFA provides an important second layer of protection in the pacs login process by requiring users to authenticate through a second factor, such as a code on their mobile device. This significantly minimizes the exposure of unauthorized access due to stolen or compromised credentials.

53 Detailed Audit Trails: The system is required to have a precise, unalterable record of every user action. These audit trails document every pacs login, every study accessed, and all actions within the system, dated and linked with a specific user. These logs are crucial for accountability and are extremely useful for forensic analysis in the case of a security breach.

53 The strategic transition to more accessible, cloud-based PACS models requires an attendant change in security strategy. With users now accessing the system from remote locations and devices, the conventional security “perimeter” of the hospital’s internal network becomes increasingly irrelevant. The greater connectivity increases the potential “attack surface,” necessitating a departure from a straightforward firewall-based defense. The new paradigm is a “zero-trust” security model. This model is based on the premise that no device or user can be trusted implicitly, irrespective of whether they are inside or outside the network. Each pacs login and each request to access the data is to be stringently authenticated and authorized.

Ensuring a Smooth Go-Live: The Role of PACS Testing

Rolling out a new pacs radiology system is a complicated, high-risk, and expensive endeavor. To guarantee the achievement of such an undertaking, thorough pacs testing is not only advisable; it is necessary. Acceptance Testing (AT) is an essential step in the implementation process that acts to ensure that the system installed is safe for use in the clinical environment, behaves as anticipated, and is in compliance with all the conditions outlined in the acquisition agreement prior to the final payment by the hospital.57 The systematic testing process shields the investment of the hospital and guarantees the vendor has met its obligations.

          57 A thorough pacs testing protocol should be extensive and multidimensional. It must include end-to-end workflow tests that simulate real-world clinical scenarios, tracing the path of a study from the moment an order is placed in the RIS, through image acquisition at the modality, to archiving, distribution, and final interpretation at a radiologist’s workstation.58 The plan should also include performance benchmarking to ensure the system can handle the expected clinical load without slowdowns, as well as verification of all integrations with the RIS, HIS, and EHR. Lastly, failure and recovery testing is also essential to validate that the system’s redundancy and backup functionality operates as intended.

57 In addition to technical validation, thorough user education is a foundation of a successful PACS implementation. All the parties—radiologists, technologists, PACS administrators, referring physicians, and clinical staff—need to be provided with formal, role-based education. Not only will this allow them to effectively and efficiently utilize the new system on day one but also encourage user adoption and optimize return on this major technological investment.59

The Future is Now: AI Integration in Modern PACS Radiology

Beyond Storage: PACS as a Smart Platform

The development of pacs radiology is moving towards a new and fascinating stage. For decades, the main role of a PACS was that of archiving and communicating images. Today, it is evolving from a passive storehouse into an intelligent, active platform that helps clinicians in the process of diagnosis itself.2 This is being fueled by the embedding of Artificial Intelligence (AI).

AI applications are being integrated natively into the pacs radiology software to streamline workflows and offer strong diagnostic assistance. For workflow, AI has the ability to serve as an intelligent triage agent. AI can process incoming studies in real-time and automatically mark up studies with suspected critical findings—such as an intracranial hemorrhage, a large vessel occlusion stroke, or a pulmonary embolism—and put them high up on the radiologist’s worklist. This guarantees that the most urgent cases are heard first, possibly saving lives.

27 To support diagnosis, AI can be used as an endless “second reader.” Machine learning algorithms on large datasets can identify minute abnormalities that are likely to be missed by the human eye, like tiny early-stage lung cancer or slight fractures.64 AI can also perform many of the repetitive and time-consuming tasks in radiology, like tumor measurements, organ volume calculations, and comparison of current results to past studies. This automation not only saves precious time but also enhances consistency and minimizes the risk of measurement error.

68 How AI-Powered PACS Radiology Software is Reducing Burnout and Improving Care

The unrelenting growth in imaging volume has imposed unsustainable pressure on radiologists, resulting in mass burnout. AI-assisted PACS provides a potent remedy. AI liberates radiologists from the most monotonous and repetitive parts of the task by automating them, enabling them to apply their intellectual capacity and expertise to the most challenging cases, clinical judgment, and communication with other physicians. This relieves burnout, enhances job satisfaction, and enables radiologists to practice at the highest level of their licensure.

63 But the general deployment of AI in a pacs radiology setting is not free from challenges. There is an urgent need for strict clinical validation to demonstrate the safety and effectiveness of such algorithms. Establishing trust among radiologists who ultimately sign off on the diagnosis is crucial. Ensuring the privacy and security of patient data for training AI models is also a significant ethical and practical stumbling block.

 Finally, the results of the AI must be incorporated into the current diagnostic process smoothly without disruption and without the introduction of additional steps for the radiologist.63 The future probably doesn’t reside in adding dozens of disparate AI solutions in bolt-on fashion, but in creating a single AI “orchestration” platform through the PACS that can handle multiple algorithms and deliver their results to the radiologist in an integrated, intuitive fashion.

69 The integration of AI into the pacs system that radiology departments utilize will eventually reshape the radiologist’s role. While AI does more and more of the initial detection and quantification, the radiologist will transition to being a “super-reader.” They will be expert clinicians who confirm AI results, synthesize intricate imaging and clinical information, and act as key consultants to the whole care team. The PACS will be the smart platform that makes this leap possible, placing the radiologist not only as image interpreter but as a clinical data scientist who converts massive volumes of visual data into actionable information for patient care.

Conclusion: Why a Modern PACS System is an Essential Investment for Every Radiology Department

The proof is irrefutable: in the era of contemporary, information-based healthcare, a solid pacs radiology system is no longer an optional enhancement but a building block and imperative investment. The shift away from hard film to a digital environment brings monumental and quantifiable productivity gains, significantly shortening the time it takes to produce reports while eliminating the bottlenecks that had beset imaging departments. Clinically, it offers strong new analytic tools, enhances diagnostic accuracy with instant access to previous studies, and facilitates more collaborative practice that dissolves departmental silos.

Financially, the arrival of Cloud pacs cloud based pacs flexible models has democratized access to this technology, transforming capital-intensive purchases into operational expenses that can be managed and providing unprecedented scalability for the future. In addition, a contemporary pacs radiology system is the only acceptable platform for the next big jump in medical imaging: harnessing artificial intelligence. It has the infrastructure required to harness AI to optimize workflow, aid diagnoses, and most importantly, enable radiologists to perform more efficiently. 

A purchase of a contemporary pacs system radiology facilities can count on is an investment in efficiency, accuracy, and a future-proof infrastructure. It is the solution to a more efficient and intelligent way of medical imaging, a way that provides improved, accelerated, and safer care for the ultimate stakeholder: the patient.

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