This program facilitates the analysis of auditory evoked responses (tested with auditory brainstem responses and compound action potentials). You can visualize the waveform series collected during a single experiment, and identify the threshold and extract the amplitude and latency of each of the individual peaks in the waveform.
The program works with the fillowing file formats:
- ABR data generated by the Eaton Peabody Laboratories Cochlear Function Test Suite (EPL CFTS).
- ABR data generated by psiexperiment.
- ABR data generated by the Intelligent Hearing Systems (IHS) text export.
Individal research groups have also adapted the program to work with their own file formats.
The simplest way to get started is to download the Anaconda Python Distribution. Once installed, you will have new programs available in your start menu. One of these is called Anaconda Prompt
. Open the Anaconda Prompt
and you will get a command window. Type the following sequence of commands:
conda create -n abr python=3.10
conda activate abr
pip install abr
Open the Anaconda Prompt
and type:
conda activate abr
abr
conda activate abr
pip install --upgrade abr
There are two main interfaces to the ABR analysis program. The first is the basic interface where you manually drag files from your file browser and drop them on the window. You can drag one file or multiple files. Each file will be opened in a separate tab. The second interface is an automatic one that will loop through all unprocessed ABR files found in a folder and present each file to you individually for analysis. Once you save the analysis, it will immediately move to the next file.
Both interfaces are accessed via the launcher. When you first open the launcher, you will specify:
- Your name (i.e., the "analyzer")
- The file format. For many of you, you will pick the EPL CFTS unless you are using my software, psiexperiment for data acquisition.
- Which waves you want to analyze. If none are checked, we will assume that you only wish to mark threshold.
- Filter settings to use. The original version of this program (distributed via the EPL website), filters waveforms using a 300 to 3000 Hz bandpass butterworth filter.
Each waveform is bandpass filtered using a butterworth filter (filter order and highpass and lowpass cutoffs are specified via command-line options). This filtering process removes the baseline shift as well as high-frequency noise that may interfere with the peak-finding algorithm. To prevent the waveform from being filtered, use the --nofilter option; however, be aware that this may degrade the efficacy of the automated peak. Important note: since the algorithm uses a forward and reverse filter (to minimize phase shift), the actual order is double the requested order.
An initial estimate of P1-5 is computed and presented for correction. You may navigate through the waveform stack via the up/down arrows and select a point via the corresponding number (1-5). Once a point is selected (it will turn to a white square), you can move it along the waveform using the right/left arrow keys. Since the algorithm relies on the location of P1-5 to compute the best possible estimate of N1-5, you should correct the location of P1-5 before asking the algorithm to estimate N1-5. You may also specify threshold by navigating to the appropriate waveform (via the up/down arrows) and hitting the "t" key.
The amplitude and latency of each point are saved along with the threshold of the series. If the point is part of a subthreshold waveform, the additive inverse of the latency is saved (i.e. when parsing the file, subthreshold data can be recognized by negative latencies). Amplitudes from subthreshold points can be used to estimate the noise floor if desired.
The current waveform is displayed as a thick, black line. Once a threshold is specified, subthreshold waveforms are indicated by a dashed line. The selected point is indicated by a white square. Negativities are indicated by triangles, positivities as squares. Red is P1/N1, yellow is P2/N2, green is P3/N3, light blue is P4/N4, and dark blue is P5/N5.
Instructions for using the program are included in the user interface.
Code relating to marking points unscoreable and/or shifting waveforms up/down to ensure they don't run off the plot are adapted from work performed for the United States government and, therefore, are in the public domain. All other part of the code remain licensed under the BSD 3-clause.