xiv
Preface
tissue engineering, biological modeling, and drug screening. As more and more
people are enduring the symptoms of neurodegenerative disorders every day,
stem cells seem to hold promise for treating these conditions.
Brain tumor tissue engineering applications are covered in Chapter 3.
Glioblastoma (GBM) in particular is the deadliest of these tumors because
of its aggressiveness, ability to invade, and late diagnosis, all of which neces-
sitate the use of modern biotechnologies. The range of GBM diagnosis and
treatment modalities now employed in clinics calls for the enhancement of
current care. Tissue engineering can be a very useful tool for researchers and
doctors to better understand the biology of the tumor and increase patient’s
life.
The focus of Chapter 4 is imaging-based brain tumor detection. Early brain
tumor identification is essential for an early diagnosis and a well-thought-out
treatment plan. Over the past few years, MRI scanning has played an in-
creasingly important role in medical research. Digital image processing plays
a major role in medical image analysis. Image segmentation is a crucial step in
image processing since it makes data extraction from complex medical images
easier. Dividing of aberrant brain tissue (a tumor) from healthy brain tissue
is known as brain tumor segmentation. Brain tumor segmentation algorithms
have shown promise in the analysis and detection of tumors in clinical images.
Since the beginning locations of metastatic gliomas are unpredictable, Chap-
ter 5 focuses on spatiotemporal simulation of initial glioma growth. Several
reaction diffusion equation techniques have been used to simulate the growth
of gliomas in both the reaction and diffusion phases. The spatiotemporal state
of glioma growth has been simulated using three response equations and five
distinct diffusion techniques. The life expectancy of a patient, the future ef-
fects of brain damage on perception and attitude, and the efficacy of present
treatments can all be predicted with the use of brain tumor development sim-
ulator modeling.
In Chapter 6, fractional operators are discussed in the mathematical mod-
eling of brain tumors. Partial differential equations and ordinary differential
equations are examples of mathematical models, as are mathematical struc-
tures. Although there are several ways to solve the problem, information about
fractional operators in glioma modeling is provided in this chapter. The impact
of fractional calculus on the formation of brain tumors is also investigated.
Applications of the Brain-Computer Interface (BCI) are the main topic
of Chapter 7. The development of BCI systems has the potential to signif-
icantly improve our knowledge of, and ability to treat neuropsychiatric dis-
orders such as Parkinson’s disease, Alzheimer’s disease, and other mood and
mental disorders. The first section of the chapter explains the basic ideas be-
hind electroencephalography (EEG) and why it is useful for recording brain
activity in real time. It then explores the complex field of neurodegenerative
diseases and neuropsychiatric disorders, highlighting how EEG-based BCIs
can improve diagnostic, therapeutic, and rehabilitative approaches.
The research on brain bioinformatics utilizing RNA-seq and Microarray