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Inhaled Medications

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Inhaled medications are crucial for managing chronic obstructive pulmonary disease (COPD) and asthma. They are essential for effective treatment and control, ensuring optimal respiratory health and well-being. Inhaled medication delivers drugs directly to the lungs, providing a rapid onset of action and reducing systemic side effects compared to oral or injectable medications. Three primary types of inhalation devices are used to administer these medications: nebulizers, metered-dose inhalers...
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Endocarditis III: Medical Management01:18

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Infective endocarditis management involves a multifaceted approach encompassing infection prevention, lifestyle modifications, pharmacological therapy, and surgical management.Infection Prevention:Hand Hygiene: Thorough handwashing is crucial to prevent the spread of infection. Hand hygiene should be performed regularly, especially before and after using the restroom.Oral Hygiene: Good oral hygiene is essential. It includes brushing teeth immediately after waking up and before bed, flossing...
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Myocarditis III: Medical Management01:14

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Myocarditis: Comprehensive Medical ManagementMyocarditis, the heart muscle inflammation, requires a comprehensive medical management strategy that addresses the underlying cause, provides supportive care, manages symptoms, and reduces cardiac workload.Infections and Autoimmune CausesAdminister appropriate antimicrobial therapy when an infectious agent causes myocarditis. For instance, penicillin treats infections caused by Group A Streptococcus. In cases where autoimmune processes are...
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Pericarditis III: Medical Management01:17

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The primary objectives of managing pericarditis are to determine the underlying cause, provide effective therapy for treatment and symptom relief, and promptly detect signs and symptoms of cardiac tamponade. The following outlines the essential aspects of medical management for pericarditis:ObjectivesDetermine the Cause: Identifying the underlying cause of pericarditis is crucial for targeted treatment. Causes include viral infections, autoimmune diseases, post-cardiac injury syndrome, and...
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Heart Failure V: Medical Management01:30

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Medical Management of Acute Decompensated Heart Failure (ADHF)The primary goals of therapy for patients hospitalized with acute decompensated heart failure (ADHF) include:Relieving symptomsOptimizing volume statusSupporting oxygenation and ventilationMaintaining cardiac output (CO) and end-organ perfusionIdentifying and addressing the cause of ADHFPreventing complicationsProviding patient education on factors precipitating HF exacerbationPlanning for dischargeOngoing monitoring and assessment...
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Appendicitis-II: Diagnostic Studies and Management01:29

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Diagnosing and managing appendicitis requires a structured and comprehensive approach that spans from initial assessment to postoperative care. Here is an overview of the process:
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Related Experiment Video

Updated: Feb 2, 2026

Rapid and Low-cost Prototyping of Medical Devices Using 3D Printed Molds for Liquid Injection Molding
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3D-Printed Biosensor Arrays for Medical Diagnostics.

Mohamed Sharafeldin1,2, Abby Jones3, James F Rusling4,5,6,7

  • 1Department of Chemistry (U-3060), University of Connecticut, 55 North Eagleville Road, Storrs, CT 06269, USA. mohamed.sharafeldin@uconn.edu.

Micromachines
|November 15, 2018
PubMed
Summary
This summary is machine-generated.

Low-cost 3D printing is revolutionizing biomedical diagnostics by enabling the creation of complex, affordable tools. This technology facilitates the development of sensitive diagnostic devices, including microfluidics and bioprinted systems incorporating living cells.

Keywords:
3D printingbioprintingdiagnosticselectronicsmicrofluidicsoptics

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Area of Science:

  • Biomedical Engineering
  • Medical Diagnostics
  • Additive Manufacturing

Background:

  • 3D printing technology offers accessible fabrication for bioanalytical research.
  • Its versatility allows for materials with diverse properties, enabling strategic design options.
  • Applications span from medical implants to diagnostic devices.

Purpose of the Study:

  • To review the impact of 3D printing on biomedical diagnostics.
  • To highlight the development of low-cost, sensitive, and geometrically complex diagnostic tools.
  • To explore emerging applications, including 3D bioprinting with living cells.

Main Methods:

  • Review of current literature on 3D printing applications in diagnostics.
  • Analysis of 3D printing's role in fabricating microfluidics and diagnostic components.
  • Examination of 3D bioprinting techniques for diagnostic systems.

Main Results:

  • 3D printing enables the cost-effective production of sophisticated diagnostic tools.
  • It facilitates the integration of microfluidics, optical, and electronic components.
  • 3D bioprinting allows for the incorporation of living cells and biomaterials.

Conclusions:

  • 3D printing is a transformative technology for advancing biomedical diagnostics.
  • It supports the creation of accessible, high-performance diagnostic solutions.
  • Future directions include advanced bioprinted diagnostic systems.