During most cardiac surgeries, a Cardiopulmonary bypass (CPD) is used. This is a machine which takes over the respiration and circulation functions of the heart during surgery. However, the blood supply to the heart and thus the supply of oxygen and nutrients, will be cut off whe
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During most cardiac surgeries, a Cardiopulmonary bypass (CPD) is used. This is a machine which takes over the respiration and circulation functions of the heart during surgery. However, the blood supply to the heart and thus the supply of oxygen and nutrients, will be cut off when this occurs. This is also known as myocardial ischemia, which can lead to damage to the heart tissue and could even be fatal. Therefore, it is of paramount importance to detect ischemia before it causes irreversible damage.
There are several parameters that can indicate ischemia, including pH, oxygen and lactate. This work focuses on measuring the pH level of the heart tissue, since this could be measured noninvasively and is relatively simple. In order to get a clear picture of the consequences of ischemia throughout the heart, the pH level should be measured at different locations. To achieve this an optical fluorescence sensor is designed. This sensor consists of a sensor layer, two LEDs and an optical fibre connected to a spectrometer.
The fluorescent indicator dye used in the sensor layer is 8-Hydroxypyrene-1,3,6-trisulfonic acid
trisodium salt (HPTS). This fluorescent dye has two excitation peaks, one at 405nm and one at 470nm and two emission peaks one at 440nm and one at 515nm. These different excitation and emission bands enable ratiometric sensing which improves accuracy and sensitivity. This is due to the fact that the intensity of the fluorescent emission at 515nm is directly proportional with the pH level, where the intensity of the fluorescent emission at 440nm is inversely proportional to the pH level. By taking the ratios of these measured intensities the pH can be determined.
The indicator dye is immobilized in a hydrogel which is thereafter deposited on a thin glass slide. This slide is placed above two LEDs which are matched with the excitation peaks of HPTS. Adjacent to the LEDs an optical fibre is placed to capture the fluorescent emission and direct it to the spectrometer which is connected to a computer. The designed sensor system shows a 5 fold increase in ratio of intensities over a pH range of 6.2-8.2, with a significant improvement in response time compared to other HPTS and hydrogel based pH sensors reported in literature.