The Use of Telemedicine in Burn Care: Development of a Mobile System for TBSA Documentation and Remote Assessment

Overview

Journal Ann Burns Fire Disasters

Date 2015 Jul 15

PMID 26170783

Citations 7

Authors

D Parvizi

M Giretzlehner

J Dirnberger

R Owen

H L Haller

M V Schintler

P Wurzer

D B Lumenta

L P Kamolz

Affiliations

Soon will be listed here.

Abstract

The requirements for accurate documentation within the process of burn assessment have increased dramatically over the years. TBSA (total body surface area) and burn depth are commonly determined by visual inspection, especially in the emergency or acute care setting. However, inexperience often results in incorrect estimation of these factors. In 2001, BurnCase 3D was initiated in order to develop a tool for objective burn assessment and documentation on mobile devices (Apple iPhoneTM). The centerpiece is a 3D model representing the actual patient. At two international burn meetings, a survey containing three pictures of patients was conducted and this data was collected. A patient-specific 3D model adapted to the height and weight of the real patient was created and the digital picture was superimposed in the computer system. The burns were transferred to the model and the TBSA in % was calculated by the software BurnCase 3D. The preferred methods of the 80 respondents for burn extent estimation were: the Rule of Nines (38%), the Rule of Palm (37%) and the Lund-Browder chart (18%). Analysis showed very high deviations of TBSA within the participants, even among the group of experts. In comparison to a computer-aided method we found massive overestimation of up to 230%. The use of BurnCase 3D could have a true impact on the quality of treatment in burns. In the acute care setting for burn injuries, telemedicine has great potential to help guide decisions regarding triage and transfer based on TBSA, burn depth, patient age and injury mechanism.

Citing Articles

Utility of Telehealth Platforms Applied to Burns Management: A Systematic Review.

Garcia-Diaz A, Vilardell-Roig L, Novillo-Ortiz D, Gacto-Sanchez P, Pereyra-Rodriguez J, Saigi-Rubio F Int J Environ Res Public Health. 2023; 20(4).

PMID: 36833860 PMC: 9968161. DOI: 10.3390/ijerph20043161.

3D PED BURN app: A precise and easy-to-use pediatric 3D burn surface area calculation tool.

Meevassana J, Sumonsriwarankun P, Suwajo P, Nilprapha K, Promniyom P, Iamphongsai S Health Sci Rep. 2022; 5(4):e694.

PMID: 35755413 PMC: 9203995. DOI: 10.1002/hsr2.694.

Telehealth and Burn Care: From Faxes to Augmented Reality.

Park C, Cho Y, Harvey J, Arnoldo B, Levi B Bioengineering (Basel). 2022; 9(5).

PMID: 35621489 PMC: 9137829. DOI: 10.3390/bioengineering9050211.

Practical Computer Vision Application to Compute Total Body Surface Area Burn: Reappraising a Fundamental Burn Injury Formula in the Modern Era.

Choi J, Patil A, Vendrow E, Touponse G, Aboukhater L, Forrester J JAMA Surg. 2021; 157(2):129-135.

PMID: 34817552 PMC: 8613700. DOI: 10.1001/jamasurg.2021.5848.

Technical and Medical Aspects of Burn Size Assessment and Documentation.

Giretzlehner M, Ganitzer I, Haller H Medicina (Kaunas). 2021; 57(3).

PMID: 33807630 PMC: 7999209. DOI: 10.3390/medicina57030242.

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