logo
搜索
菜单

Bridging the Technology Divide in the COVID-19 Era: Using Virtual Outreach to Expose Middle and High School Students to Imaging Technology

作者: Kevin D. Phelan1, Mohsin Syed1, Noor Akhter1, Tiffany W. Huitt1, Gregory R. Snead2, Billy R. Thomas3, Karen L. Yanowitz4 1Division of Clinical Anatomy, Department of Neurobiology and Developmental Sciences, College of Medicine,University of Arkansas for Medical Sciences, 2Department of Emergency Medicine, College of Medicine,University of Arkansas for Medical Sciences, 3Department of Pediatrics, College of Medicine,University of Arkansas for Medical Sciences, 4Department of Psychology and Counseling,Arkansas State University
简介:

Overview

This article presents an overview of how synchronous web-based virtual outreach can be used to expose 6th-12th grade students to advanced imaging technologies such as ultrasound, computerized tomography, and electroencephalography. The integrated approach used in virtual STEM outreach presentations aims to engage students and promote interest in STEM careers.

Key Study Components

Area of Science

  • Neuroscience
  • Biomedical Imaging
  • STEM Education

Background

  • Virtual outreach can bridge the technology gap for students in rural areas.
  • It provides critical access to STEM role models.
  • The approach aims to diversify the STEM pipeline.
  • Professional quality live streaming enhances student engagement.

Purpose of Study

  • To promote student interest in STEM careers.
  • To provide access to advanced imaging technologies.
  • To develop an effective virtual outreach model for education.

Methods Used

  • Live streaming of imaging technologies.
  • Use of video switchers and HDMI connections for presentations.
  • Demonstration of ultrasound, CT, and EEG technologies.
  • Engagement of students through interactive sessions.

Main Results

  • Increased student engagement in STEM subjects.
  • Successful demonstration of imaging technologies.
  • Positive feedback from participants on the outreach model.
  • Enhanced understanding of complex imaging techniques.

Conclusions

  • Synchronous virtual outreach is effective for STEM education.
  • It can serve as a recruitment tool for underserved populations.
  • The model can be replicated in various educational settings.

Frequently Asked Questions

What imaging technologies are covered in the outreach?
The outreach covers ultrasound, computerized tomography (CT), and electroencephalography (EEG).
How does virtual outreach benefit students?
It promotes interest in STEM careers and provides access to role models.
What equipment is essential for the virtual presentations?
A video switcher and HDMI connections are key components.
Can this model be used in rural areas?
Yes, it effectively bridges the technology gap for students in rural locations.
What is the main goal of the outreach?
To engage students and increase participation in STEM-related fields.
How is student engagement measured?
Engagement is assessed through feedback and participation levels during sessions.

This article presents an overview of how synchronous web-based virtual outreach can be used to expose 6th-12th grade students to advanced imaging technologies such as ultrasound, computerized tomography, and electroencephalography. The paper discusses the methods and equipment needed to livestream integrated educational sessions for effective student engagement in STEM.

标签: Technology Divide,    COVID-19 Era,    Virtual Outreach,    Imaging Technology,    Student Interest,    STEM Career,    Rural Areas,    STEM Role Models,    Underserved Populations,    STEM Pipeline,    Video Switcher,    HDMI Switcher,    3D Anatomy Visualization,    Electroencephalographic Station,    EEG Headset,   
In Vivo Luminal Measurement of Distension-Evoked Urothelial ATP Release in Rodents 10.3791/64227-v 09:17 min
In Vivo Luminal Measurement of Distension-Evoked Urothelial ATP Release in Rodents
Establishment of a Simple and Effective Rat Model for Intraoperative Parathyroid Gland Imaging 10.3791/64222-v 07:12 min
Establishment of a Simple and Effective Rat Model for Intraoperative Parathyroid Gland Imaging
Extracting the Cochlea from a Human Temporal Bone: A Cadaveric Protocol 10.3791/64208-v 06:42 min
Extracting the Cochlea from a Human Temporal Bone: A Cadaveric Protocol
Surgical Tips and Tricks for Performing Porcine Pancreas Transplantation 10.3791/64203-v 10:32 min
Surgical Tips and Tricks for Performing Porcine Pancreas Transplantation
Delivery of Cardioactive Therapeutics in a Porcine Myocardial Infarction Model 10.3791/64177-v
Delivery of Cardioactive Therapeutics in a Porcine Myocardial Infarction Model
The Miniature Pig: A Large Animal Model for Cochlear Implant Research 10.3791/64174-v 06:16 min
The Miniature Pig: A Large Animal Model for Cochlear Implant Research
Occlusion of the Great and Small Saphenous Vein Using Copolymeric Glue Based on N-Butyl Cyanoacrylate and Methacryloxy Sulfolane 10.3791/64170-v
Occlusion of the Great and Small Saphenous Vein Using Copolymeric Glue Based on N-Butyl Cyanoacrylate and Methacryloxy Sulfolane
Isolation of Murine Intestinal Mesenchyme Resulting in a High Yield of Telocytes 10.3791/64169-v
Isolation of Murine Intestinal Mesenchyme Resulting in a High Yield of Telocytes
返回顶部