Your search keyword '"J. Asp"' showing total 3 results

1. A Low-Cost Humidity Control System to Protect Microscopes in a Tropical Climate

Author

J. Luis Lujan, Anders J. Asp, Christina M. Webber, Evan N. Nicolai, Ephraim I. Ben-Abraham, John W. Wilson, Gabriel Martínez-Gálvez, and Victoria S. Marks

Subjects

Fungal growth, Infectious and parasitic diseases, RC109-216, Improper storage, Hygroscopic Agents, Toxicology, 03 medical and health sciences, 0302 clinical medicine, Tropical climate, Diagnostic equipment, Humans, Relative humidity, 030212 general & internal medicine, High humidity, Original Research, Microscopy, Tropical Climate, 030503 health policy & services, Fungi, Humidity, food and beverages, General Medicine, Silicon Dioxide, Belize, 6. Clean water, humanities, Equipment and Supplies, 13. Climate action, Costs and Cost Analysis, Equipment Contamination, Environmental science, Public aspects of medicine, RA1-1270, 0305 other medical science

Abstract

Introduction: A clean and functional microscope is necessary for accurate diagnosis of infectious diseases. In tropical climates, high humidity levels and improper storage conditions allow for the accumulation of debris and fungus on the optical components of diagnostic equipment, such as microscopes. Objective: Our objective was to develop and implement a low-cost, sustainable, easy to manage, low-maintenance, passive humidity control chamber to both reduce debris accumulation and microbial growth onto the optical components of microscopes. Methods: Constructed from easily-sourced and locally available materials, the cost of each humidity control chamber is approximately $2.35 USD. Relative humidity levels were recorded every 30 minutes over a period of 10 weeks from two chambers deployed at the Belize Vector and Ecology Center and the University of Belize. Results: The humidity control chamber deployed at the University of Belize maintained internal relative humidity at an average of 35.3% (SD = 4.2%) over 10 weeks, while the average external relative humidity was 86.4% (SD = 12.4%). The humidity control chamber deployed at the Belize Vector and Ecology Center effectively maintained internal relative humidity to an average of 54.5% (SD = 9.4%) over 10 weeks, while the average external relative humidity was 86.9% (SD = 12.9%). Conclusions: Control of relative humidity is paramount for the sustainability of medical equipment in tropical climates. The humidity control chambers reduced relative humidity to levels that were not conducive for fungal growth while reducing microscope contamination from external sources. This will likely extend the service life of the microscopes while taking advantage of low-cost, locally sourced components.

Published

2020

2. Developing Strategies for Sustainable Medical Equipment Maintenance in Under-Resourced Settings

Author

Sara Aristizabal, Anders J. Asp, Gabriel Martínez-Gálvez, Christina M. Webber, J. Luis Lujan, Maria A. Gonzalez Porras, Manuela Lopera Higuita, John W. Wilson, Ephraim I. Ben-Abraham, and Brent M. Berry

Subjects

Process management, Maintenance, Organizations, Nonprofit, Developing country, Medical equipment, Infectious and parasitic diseases, RC109-216, Original research, 03 medical and health sciences, 0302 clinical medicine, Stakeholder Participation, Health care, Humans, 030212 general & internal medicine, Developing Countries, Sustainable solutions, business.industry, Teaching, 030503 health policy & services, General Medicine, Preventive maintenance, Editorial, Equipment and Supplies, Sustainability, Health Resources, Public aspects of medicine, RA1-1270, 0305 other medical science, business, Equipment and Supplies Utilization, Limited resources, Needs Assessment, Program Evaluation

Abstract

Engineering technology plays a pivotal role in the delivery of health care in under-resourced countries by providing an infrastructure to improve patient outcomes. However, sustainability of these technologies is difficult in these settings oftentimes due to limited resources or training. The framework presented in this editorial focuses on establishing medical and laboratory equipment sustainability in developing countries and is comprised of four steps: 1) establishing reliable in-country relationships with stakeholders, 2) identifying needs for sustainable solutions locally, 3) exploring potential solutions and assessing their effort-to-impact ratios, and 4) working with strategic partners to implement solutions with clear performance metrics. By focusing on the sustainability of donated equipment instead of the equipment itself, this method presented distinguishes itself from other philanthropic endeavors in the field by seeking to establish preventive maintenance habits that can impact clinical outcomes of a community long term. Application of this methodology is reported in the Original Research Article “A Low-Cost Humidity Control System to Protect Microscopes in a Tropical Climate” by Asp et. al.

Published

2020

3. A Low-Cost Humidity Control System to Protect Microscopes in a Tropical Climate

Author

Anders J. Asp, Christina M. Webber, Evan N. Nicolai, Gabriel Martínez-Gálvez, Victoria S. Marks, Ephraim I. Ben-Abraham, John W. Willson, and J. Luis Luján

Subjects

Infectious and parasitic diseases, RC109-216, Public aspects of medicine, RA1-1270

Abstract

Introduction: A clean and functional microscope is necessary for accurate diagnosis of infectious diseases. In tropical climates, high humidity levels and improper storage conditions allow for the accumulation of debris and fungus on the optical components of diagnostic equipment, such as microscopes. Objective: Our objective was to develop and implement a low-cost, sustainable, easy to manage, low-maintenance, passive humidity control chamber to both reduce debris accumulation and microbial growth onto the optical components of microscopes. Methods: Constructed from easily-sourced and locally available materials, the cost of each humidity control chamber is approximately $2.35 USD. Relative humidity levels were recorded every 30 minutes over a period of 10 weeks from two chambers deployed at the Belize Vector and Ecology Center and the University of Belize. Results: The humidity control chamber deployed at the University of Belize maintained internal relative humidity at an average of 35.3% (SD = 4.2%) over 10 weeks, while the average external relative humidity was 86.4% (SD = 12.4%). The humidity control chamber deployed at the Belize Vector and Ecology Center effectively maintained internal relative humidity to an average of 54.5% (SD = 9.4%) over 10 weeks, while the average external relative humidity was 86.9% (SD = 12.9%). Conclusions: Control of relative humidity is paramount for the sustainability of medical equipment in tropical climates. The humidity control chambers reduced relative humidity to levels that were not conducive for fungal growth while reducing microscope contamination from external sources. This will likely extend the service life of the microscopes while taking advantage of low-cost, locally sourced components.

Published

2020