Earn the most prestigious title in your career and develop leadership skills suited to today’s global business challenges. This online DBA program empowers you to innovate and lead at the highest levels.
Doctorate
Mar 31, 2025
36 Months
This course was designed to empower experienced professionals with advanced knowledge and research skills to enable them to drive innovation. Upon completion, learners will be awarded an DBA degree from Euro Asian, Geneva.
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Doctor Degree in Business Administration
1. Neuroanatomy and Neurophysiology
Study the organization of the central and peripheral nervous systems, including brain regions, spinal cord, and neural pathways. Understand the roles of neurons and glial cells, synaptic connections, and neurotransmission. Explore how structural components support sensory input, motor output, cognition, and behavior. Emphasize structure-function relationships in normal and diseased states.
Study the organization and function of neural circuits underlying sensory, motor, and cognitive processes. Understand synaptic transmission mechanisms, including neurotransmitter release, receptor dynamics, and synaptic plasticity. Explore excitatory and inhibitory balance, long-term potentiation (LTP), and circuit modulation. Analyze how disruptions in these processes contribute to neurological and psychiatric disorders.
Understand the structure and functions of the central nervous system (CNS) and peripheral nervous system (PNS), including the brain, spinal cord, nerves, and ganglia. Study signal transmission pathways, sensory and motor integration, and neuroglial interactions. Explore how CNS-PNS coordination regulates behavior, and how dysfunction leads to neurological diseases.
Learn the structural and functional organization of brain regions and their roles in cognition, behavior, and sensory-motor functions. Study techniques like fMRI, PET, and EEG for brain mapping. Understand neural connectivity, cortical and subcortical functions, and brain network integration. Apply this knowledge to interpret neuroimaging data in research and diagnostics.
2. Molecular and Cellular Neuroscience
Understand the types, structures, and functions of ion channels in neurons. Study their roles in generating and propagating action potentials, maintaining resting membrane potential, and synaptic transmission. Explore voltage-gated and ligand-gated channels, channelopathies, and pharmacological modulation. Analyze how ion channel dysfunctions contribute to neurological and neurodevelopmental disorders.
Understand the classification, synthesis, and release of major neurotransmitters like glutamate, GABA, dopamine, and serotonin. Study receptor types—ionotropic and metabotropic—and their signal transduction pathways. Explore how neurotransmitter-receptor interactions influence neural communication, behavior, and brain function. Analyze dysfunctions linked to neurological, psychiatric, and neurodegenerative disorders for therapeutic insights.
Examine the molecular and cellular mechanisms of neuronal development, including neurogenesis, migration, and axon guidance. Understand synaptogenesis and activity-dependent plasticity. Study critical periods of development, experience-driven changes, and long-term synaptic modifications. Explore how plasticity supports learning and memory, and how its dysregulation contributes to developmental and neuropsychiatric disorders.
Understand the molecular mechanisms of apoptosis in neurons, including intrinsic and extrinsic pathways. Study the role of oxidative stress, mitochondrial dysfunction, and protein aggregation in neurodegeneration. Explore the pathology of diseases like Alzheimer’s, Parkinson’s, and ALS. Investigate therapeutic strategies targeting cell death pathways to protect or regenerate neural tissue.
3. Cognitive and Behavioral Neuroscience
Examine the neural mechanisms underlying learning processes, memory formation, and retrieval. Understand roles of brain regions like the hippocampus, prefrontal cortex, and amygdala. Study synaptic plasticity, long-term potentiation (LTP), and reinforcement learning. Analyze how neural networks support decision-making and how dysfunctions relate to cognitive and neuropsychiatric disorders.
Explore the neural mechanisms underlying emotion, motivation, and behavior, focusing on brain regions like the amygdala, hypothalamus, and prefrontal cortex. Understand reward pathways, stress responses, and decision-making processes. Study how neurochemical systems regulate emotional states and motivated actions, and how their dysfunction contributes to mood, anxiety, and behavioral disorders.
Explore brain regions involved in executive functions, such as the prefrontal cortex. Study processes like attention, working memory, decision-making, and inhibitory control. Understand neural mechanisms underlying cognitive flexibility and goal-directed behavior. Analyze how dysfunction in cognitive control contributes to disorders like ADHD, schizophrenia, and frontal lobe impairments.
Learn to evaluate cognitive, emotional, and behavioral functions using standardized neuropsychological tests. Understand brain-behavior relationships in conditions like stroke, dementia, and traumatic brain injury. Develop skills in test selection, administration, and interpretation. Explore clinical applications in diagnosis, treatment planning, and research on neurological and psychiatric disorders affecting brain function.
4. Computational Neuroscience and Neuroinformatics
Learn to construct computational models of neurons and neural networks to simulate brain function and dynamics. Understand mathematical frameworks like Hodgkin-Huxley and integrate-and-fire models. Explore simulation tools for studying neural coding, plasticity, and oscillations. Apply models to interpret experimental data and predict brain behavior in health and disease conditions.
Learn the principles behind brain-machine interfaces (BMIs), including neural signal acquisition, decoding algorithms, and device control. Explore applications in neuroprosthetics, communication for paralyzed individuals, and cognitive enhancement. Understand challenges in neural integration, plasticity, and ethics. Gain hands-on experience with invasive and non-invasive BMI technologies and real-time neural data processing.
Learn to handle and analyze large-scale neuroscience datasets, including neuroimaging, electrophysiology, and genomics data. Understand data preprocessing, dimensionality reduction, and statistical modeling. Apply machine learning techniques to identify neural patterns and brain-behavior relationships. Develop skills in data integration, visualization, and reproducible research to derive insights from complex neural data.
Learn how artificial intelligence aids brain research through neural data analysis, brain-computer interfaces, and modeling cognitive functions. Explore machine learning for pattern recognition in neuroimaging and electrophysiology. Understand AI-driven diagnostics for neurological disorders and its role in simulating neural networks, enhancing our understanding of brain function and neurodegenerative disease mechanisms.
5. Developmental Neuroscience
Understand the properties, sources, and regulation of neural stem cells. Study the processes of neurogenesis during development and in the adult brain. Explore signaling pathways, transcription factors, and environmental cues influencing differentiation. Investigate the role of neurogenesis in brain repair, plasticity, cognitive function, and its implications in neurodegenerative diseases.
Examine brain development from embryonic stages to aging, focusing on neurogenesis, synaptogenesis, and myelination. Understand critical periods, cortical maturation, and plasticity. Study age-related changes in structure and function, including cognitive decline and neurodegeneration. Explore genetic, environmental, and epigenetic factors influencing brain development and lifelong neurological health.
Understand how genes control brain development, from neural induction to circuit formation. Study key regulatory genes, transcription factors, and signaling pathways guiding cell fate, migration, and differentiation. Explore the role of epigenetics and non-coding RNAs. Examine genetic mutations and their links to neurodevelopmental disorders like autism and intellectual disabilities.
Examine the genetic, molecular, and environmental factors contributing to developmental brain disorders such as autism, ADHD, and intellectual disabilities. Understand abnormal neurodevelopmental pathways, synaptic dysfunction, and neural circuit alterations. Explore diagnostic biomarkers, animal models, and emerging therapies aimed at early intervention and improving cognitive, behavioral, and neurological outcomes.
6. Neuropharmacology and Psychopharmacology
Learn how drugs interact with neural receptors, ion channels, and signaling pathways to alter brain function. Understand pharmacodynamics and pharmacokinetics in the central nervous system. Study how psychoactive drugs influence mood, cognition, and behavior. Explore drug effects in treating neurological disorders and the mechanisms underlying tolerance, dependence, and side effects.
Understand the roles of neurotransmitters like dopamine, serotonin, glutamate, and GABA in brain function and behavior. Explore how imbalances and dysregulation contribute to mental disorders such as depression, schizophrenia, and anxiety. Study neurochemical pathways, receptor mechanisms, and pharmacological interventions to develop targeted therapies and improve psychiatric treatment outcomes.
Understand drug absorption, distribution, metabolism, and excretion (pharmacokinetics) in the context of brain function. Learn how drugs interact with neural targets to produce effects (pharmacodynamics), including dose-response relationships and receptor binding. Explore blood-brain barrier dynamics, drug efficacy, side effects, and implications for developing treatments for neurological and psychiatric disorders.
Learn the stages of CNS drug development, from target identification to clinical trials. Understand blood-brain barrier challenges, pharmacokinetics, and pharmacodynamics. Study high-throughput screening, in vitro and in vivo models, and neurotoxicity assays. Explore strategies for designing drugs that modulate neurotransmission and treat neurological or psychiatric disorders effectively and safely.
7. Systems Neuroscience
Understand the neural pathways and mechanisms underlying sensory perception and motor control. Study sensory modalities like vision, hearing, touch, and pain processing. Explore motor planning, coordination, and execution through spinal and cortical circuits. Investigate how sensory-motor integration enables behavior and how dysfunctions contribute to neurological and movement disorders.
Examine the neurobiology of sleep stages, sleep regulation, and brain activity patterns during rest. Understand circadian rhythms, their molecular clock mechanisms, and their synchronization to environmental cues. Study the impact of sleep and circadian disruption on cognition, mood, and health. Explore sleep disorders and potential therapeutic interventions.
Understand the neural regulation of vital physiological functions like heart rate, blood pressure, respiration, and body temperature. Study the autonomic nervous system's sympathetic and parasympathetic divisions. Explore hypothalamic control of homeostasis, neuroendocrine integration, and stress response. Examine how dysfunctions contribute to disorders such as hypertension, anxiety, and metabolic syndromes.
Understand how different neural systems—sensory, motor, cognitive, and autonomic—interact to produce coordinated behavior and maintain homeostasis. Study brain regions involved in integration, such as the thalamus and cortex. Explore neural network dynamics, cross-modal processing, and feedback mechanisms. Analyze dysfunctions linked to integrative failures in neurological and psychiatric conditions.
8. Neurogenetics and Epigenetics
Understand how genetic mutations, polymorphisms, and epigenetic alterations contribute to neurological disorders. Study inherited and sporadic conditions like Alzheimer’s, Parkinson’s, and Huntington’s disease. Learn techniques such as genome-wide association studies (GWAS), whole-genome sequencing, and CRISPR gene editing. Explore gene-environment interactions and potential for genetic therapies in neurodegenerative diseases.
Understand how gene expression regulates brain development, function, and plasticity. Learn techniques like RNA sequencing and in situ hybridization to study spatial and temporal patterns. Explore transcriptional regulation in neurons and glia, activity-dependent gene expression, and epigenetic influences. Investigate gene expression changes in neurological disorders and potential therapeutic targets.
Understand how epigenetic modifications like DNA methylation, histone acetylation, and non-coding RNAs regulate gene expression in neurons. Explore their roles in brain development, synaptic plasticity, learning, and memory. Study how epigenetic dysregulation contributes to neurological disorders, and examine emerging epigenetic therapies targeting neurodegenerative and psychiatric conditions.
Learn how GWAS identify genetic variants associated with neurological and psychiatric traits. Understand study design, statistical methods, and population genetics. Explore interpretation of single-nucleotide polymorphisms (SNPs), linkage disequilibrium, and functional annotation. Apply GWAS findings to uncover disease mechanisms, risk prediction, and personalized medicine approaches in brain and behavioral research.
9. Clinical and Translational Neuroscience
Learn principles and applications of neuroimaging techniques like MRI, fMRI, PET, and DTI. Understand how these tools visualize brain structure, function, and connectivity. Analyze imaging data for diagnosing neurological and psychiatric disorders. Explore their role in research on brain development, cognition, and treatment monitoring in clinical neuroscience.
Understand the molecular and cellular mechanisms underlying neurodegenerative diseases such as Alzheimer's and Parkinson's. Study protein misfolding, aggregation, oxidative stress, and neuroinflammation. Explore genetic and environmental risk factors, disease biomarkers, and diagnostic tools. Examine current therapeutic strategies, experimental models, and emerging approaches for prevention, treatment, and neuroprotection in clinical research.
Examine the neurobiological basis of psychiatric disorders such as depression, schizophrenia, anxiety, and bipolar disorder. Understand alterations in brain circuits, neurotransmitter systems, and genetic factors. Study diagnostic tools, biomarkers, and neuroimaging findings. Explore therapeutic interventions, including pharmacological and behavioral treatments, and their impact on brain function and mental health.
Understand how preclinical models simulate human neurological and psychiatric disorders for studying disease mechanisms and testing treatments. Learn to design and evaluate translational models using animals, stem cells, and organoids. Explore therapeutic strategies like gene therapy, neurostimulation, and pharmacological interventions. Focus on bridging lab discoveries to clinical applications in brain health.
10. Research Methodology and Ethics in Neuroscience
Learn to design rigorous neuroscience experiments with clear hypotheses, control groups, and reproducibility standards. Understand statistical methods for data analysis, including ANOVA, regression, and multivariate techniques. Gain skills in interpreting results, managing variability, and avoiding bias. Emphasize data visualization, power analysis, and ethical considerations in experimental research.
Learn key electrophysiological techniques like EEG, patch-clamp, and multi-unit recordings to study neuronal activity. Understand imaging methods such as MRI, fMRI, PET, and two-photon microscopy for brain structure and function analysis. Explore their applications in mapping neural networks, monitoring brain dynamics, and investigating neurological disorders at various spatial resolutions.
Understand the principles of honesty, transparency, and accountability in research. Learn ethical practices in data collection, analysis, and publication. Recognize issues like plagiarism, data fabrication, and authorship misconduct. Emphasize responsible conduct in human and animal research, informed consent, and adherence to institutional and international ethical guidelines in neuroscience.
Develop skills to write compelling grant proposals, including hypothesis formulation, research design, and budgeting. Learn to identify appropriate funding sources and align proposals with agency priorities. Master scholarly communication through clear, concise writing, data presentation, and publication ethics. Enhance abilities in scientific presentations, peer review, and interdisciplinary collaboration.
Conduct original research to address a real-world business problem. Learn to formulate research questions, apply theoretical frameworks, and contribute to academic and professional knowledge. Every Learner will go through these following six simple steps to complete their Thesis with the help of a Professional Expert.
What Our Learners Have To Say About Us
Pursuing my Doctorate in Business Administration was more than just an academic pursuit—it was a transformational journey. The research support and global exposure helped me establish myself as a thought leader in strategic management.
Analyze how Amazon or Netflix navigated shifting market conditions through strategic foresight, innovative thinking, and effective change management. Examine key decisions, adaptations to technology and consumer behavior, and leadership in driving transformation. Highlight lessons in resilience, long-term vision, and innovation that enabled sustained competitive advantage.
Analyze Satya Nadella’s transformational leadership at Microsoft, focusing on how his leadership style influenced employee motivation and drove cultural change. Examine key initiatives, communication strategies, and leadership behaviors that reshaped the company’s vision, collaboration, and innovation. Evaluate outcomes through performance improvements, employee engagement, and organizational culture transformation.
Analyze how Apple maintained supply chain resilience during COVID-19, focusing on logistics optimization, risk management strategies, and supplier relationship management. Examine disruptions faced, Apple’s response, and lessons learned. Highlight how Apple adapted operations, diversified suppliers, and leveraged technology to ensure continuity and meet global demand during the pandemic.
In this case study, analyze Tesla’s approach to raising capital and taking financial risks. Evaluate its valuation methods, capital structure decisions, and strategic financial choices. Assess how these influenced growth, investor confidence, and market positioning, while considering implications for long-term sustainability and competitive advantage in the electric vehicle industry.
In this case study, analyze how Airbnb achieved rapid growth through disruptive innovation. Focus on its unique business model, how it scaled operations globally, and secured funding to fuel expansion. Examine key strategies, challenges faced, and the impact of innovation on the hospitality industry’s traditional dynamics.
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Analyze how Coca-Cola tailors its branding and marketing strategies to different regions using consumer psychology insights and data-driven approaches. Examine specific regional campaigns, cultural adaptations, and how consumer behavior influences branding decisions. Highlight the effectiveness of personalized marketing and the role of data in shaping Coca-Cola’s global yet local brand presence.
Analyze the Volkswagen emissions scandal by examining the ethical lapses, failures in compliance, and the role of the board. Evaluate how decisions were made, who was responsible, and how stronger governance could have prevented it. Recommend strategies to enhance ethical decision-making, regulatory compliance, and board accountability in corporate settings.
Frequently Asked Questions
This is a doctoral-level program for professionals who want to lead through research and
innovation. It blends academic depth with real-world impact, helping you turn workplace
challenges into meaningful, research-driven solutions.
Yes, absolutely. It's built with your schedule in mind. You can pursue this PhD alongside your
job, with flexible study hours and a structure that respects your work-life balance.
This is a blended program, primarily conducted online. You'll learn through a mix of live virtual
sessions, recorded lectures, guided mentorship, and independent research. No campus visits
required—unless you choose to attend optional events.
You’ll learn from globally recognized faculty—experienced researchers, tenured professors, and
industry experts. They’ll not only teach you but guide your research journey with real insight and
personalized attention.
Instead of a traditional thesis, you’ll work on a Practicum Research Project. It’s based on a real
issue from your work or industry. With your advisor’s help, you’ll research it rigorously and may
even publish it, depending on your goals.
Not at all. This PhD is designed for professionals, not career academics. You’ll be supported
through every research step—from forming questions to analyzing data—with practical
guidance tailored to your experience level.
Most learners complete the program in about 2.5 to 3 years, depending on how much time you
dedicate. The flexible design means you can move at your own pace, balancing study with your
personal and professional life.
Yes. The degree is awarded by Euro Asian University in Estonia, a recognized institution within
the European Higher Education Area. It holds academic value across Europe, the U.S., and
beyond.
Publishing is not required but highly encouraged. If your work has practical or academic value,
your advisor can guide you in submitting it to journals or presenting it at conferences.
The cohort includes senior executives, consultants, educators, entrepreneurs, and mid-career
professionals. Everyone brings unique experiences, making for rich peer discussions and
networking opportunities.
Whether you want to teach, lead strategic transformation, consult, or start your own research
firm, this PhD helps position you as a subject matter expert and decision-maker in your domain.
The application is simple. Share your academic and professional background, express your
research interests, and have a short conversation with our admissions team. From there, we’ll
guide you through every step
Our advisors are available around the clock to answer questions and support your educational journey. Connect with us today to explore how upGrad can help you meet your career goals.
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