Summary: A newly developed technique called parallel near-infrared interferometric spectroscopy (πNIRS) significantly improves the monitoring of cerebral blood flow throughout the brain.
Source: Institute of Physical Chemistry of the Polish Academy of Sciences
Monitoring the proper blood supply to the brain is crucial, not only to prevent neurological diseases but also to treat them. The parallel near-infrared interferometric spectroscopy technique, or simply πNIRS, could make life easier for doctors and patients worldwide.
Blood drives our entire body and is especially important for brain function. On average, about 50 ml/min/100 g flows through brain tissue – about 80-90 ml/min/100 g through the gray matter and 20-30 ml/min/100 g through the white matter. When there is a lack of oxygen and, therefore, a lack of proper blood supply, the death of nerve cells occurs – then we speak of a stroke. It affects about 70,000 people every year in Poland.
This is why it is essential to monitor cerebral blood flow in disease prevention and treatment. Neurology knows many effective methods for doing so, but many of them have their weaknesses. Now a team of neuroscientists led by ICTER researchers has developed a technique that can significantly improve the monitoring of cerebral blood flow in vivo.
It is described in a paper titled “Continuous-wave parallel interferometric near-infrared spectroscopy (CW πNIRS) with a fast two-dimensional camera,” by Saeed Samaei; Klaudia Nowacka; Anna Gerega; Zanna Pastuszak; Dawid Borycki, which appeared in the journal Biomedical Optics Express.
How to monitor cerebral blood flow?
Cerebral blood flow (CBF) uses about 15% of cardiac output to deliver the essential substances (oxygen and glucose) to the brain and take away the unnecessary ones (products of metabolism). Any deviation from the norm can cause temporary brain dysfunction and irreversible trigger diseases, with Alzheimer’s disease at the forefront. That’s why non-invasive monitoring of CBF is so important – we have several practical tools for doing so.
The first that comes to mind is functional magnetic resonance imaging (fMRI), probably the most widely used diagnostic test in the world, which also works well here. It allows monitoring local changes in brain blood supply and associated fluctuations in neuronal activity in vivo. The technique offers high-resolution images but is quite expensive and difficult to use in young children, for example. This is where optical methods come to the rescue.
Brain oxygenation can be assessed using functional near-infrared spectroscopy (fNIRS). This technique allows non-invasive measurement of regional cerebral oxygenation by using selective absorption of radiation of electromagnetic waves in the range of 660-940 nm by chromophores in the human body. It is often used as a tool to help monitor a patient’s condition, including during neurosurgery.
On the other hand, blood flow can be continuously monitored by diffuse correlation spectroscopy (DCS). Their most advanced modifications are based on continuous-wave (CW) lasers, which prevent absolute measurements. Interferometric near-infrared spectroscopy (iNIRS) can help here.
Still, previous studies have shown that this method is too slow to detect immediate changes in blood flow that translate into neuronal activity. This is because it is a single-channel system, which measures the intensity of only the single-mode of the light collected from the sample.
Innovative πNIRS
A team of researchers at ICTER decided to modify iNIRS, relying on parallel near-infrared interferometric spectroscopy (πNIRS) for multi-channel detection of cerebral blood flow. To achieve this, it was necessary to alter the iNIRS detection system. In πNIRS, the collected optical signals are recorded with a two-dimensional CMOS camera operating at an ultrafast frame rate (~1 MHz).
Each pixel in the recorded image sequence effectively becomes an individual detection channel. With this approach, it is possible to obtain similar data as with iNIRS, but much faster – even by orders of magnitude!
Such an improvement, in turn, translates into greater sensitivity of the system and accuracy of detection itself. It is possible to detect rapid changes in blood flow related to the activation of neurons, for example, in response to an external stimulus or administered drug. The solution could be helpful for diagnosing CBF-related neuronal disorders and evaluating the effectiveness of therapeutic approaches, e.g., for neurodegenerative diseases.
- This project will improve rapid, non-invasive systems for human cerebral blood monitoring in vivo. Continuous and non-invasive monitoring of blood flow could help treat significant brain diseases. In addition, quick detection of cerebral blood flow will bring us closer to developing a non-invasive brain-computer interface (BCI) that could help people with disabilities. Finally, our project will strengthen the tradition of Polish development in diffusion optics – says Dawid Borycki of ICTER.
Tests have confirmed that the technique used effectively monitors prefrontal cortex activity in vivo. Moreover, it can be further improved thanks to the development of LiDAR technology and ultrafast volumetric imaging of the eye, reducing the cost of CMOS cameras. Thus, the πNIRS technique can monitor cerebral blood flow and absorption changes from more than one spatial location.
The data obtained by the πNIRS technique can be applied to the diagnosis of cerebral circulatory disorders, which will facilitate the evaluation of the patient’s condition and allow the prediction of early and long-term treatment results.
Funding: The International Centre for Translational Eye Research (MAB/2019/12) project is carried out by the Institute of Physical Chemistry, Polish Academy of Sciences within the International Research Agendas programme of the Foundation for Polish Science co-financed by the European Union under the European Regional Development Fund.
About this neurotech research news
Author: Marcin Bernatek
Source: Institute of Physical Chemistry of the Polish Academy of Sciences
Contact: Marcin Bernatek – Institute of Physical Chemistry of the Polish Academy of Sciences
Image: The image is credited to ICTER, Karol Karnowski, PhD
Original Research: Open access.
“Continuous-wave parallel interferometric near-infrared spectroscopy (CW πNIRS) with a fast two-dimensional camera” by Dawid Borycki et al. Biomedical Optics Express
Abstract
Continuous-wave parallel interferometric near-infrared spectroscopy (CW πNIRS) with a fast two-dimensional camera
Interferometric near-infrared spectroscopy (iNIRS) is an optical method that noninvasively measures the optical and dynamic properties of the human brain in vivo.
However, the original iNIRS technique uses single-mode fibers for light collection, which reduces the detected light throughput.
The reduced light throughput is compensated by the relatively long measurement or integration times (∼1 sec), which preclude monitoring of rapid blood flow changes that could be linked to neural activation.
Here, we propose parallel interferometric near-infrared spectroscopy (πNIRS) to overcome this limitation.
In πNIRS we use multi-mode fibers for light collection and a high-speed, two-dimensional camera for light detection. Each camera pixel acts effectively as a single iNIRS channel. So, the processed signals from each pixel are spatially averaged to reduce the overall integration time.
Moreover, interferometric detection provides us with the unique capability of accessing complex information (amplitude and phase) about the light remitted from the sample, which with more than 8000 parallel channels, enabled us to sense the cerebral blood flow with only a 10 msec integration time (∼100x faster than conventional iNIRS).
In this report, we have described the theoretical foundations and possible ways to implement πNIRS. Then, we developed a prototype continuous wave (CW) πNIRS system and validated it in liquid phantoms. We used our CW πNIRS to monitor the pulsatile blood flow in a human forearm in vivo.
Finally, we demonstrated that CW πNIRS could monitor activation of the prefrontal cortex by recording the change in blood flow in the forehead of the subject while he was reading an unknown text.
