Curriculum Requirements
Bachelor of Science in Biochemistry
General Education
| Foundations | Credits: | |
| FCWR 101 | Writing I: Foundations of College Composition | 3 |
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Prerequisite: Prerequisite: WRIT 100 or Writing Placement Exam A course introducing students to the fundamentals of college composition. Topics include writing process, rhetorical strategies, basics of critical reading and thinking, analytical writing, and argumentative writing. This course serves as a foundation to prepare students to succeed in other academic writing contexts. Coursework includes a computer lab component. Classroom Hours - Laboratory and/or Studio Hours – Course Credits: 3-0-3 |
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| FCWR 151 | Writing II: Foundations of Research Writing | 3 |
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Prerequisite: Prerequisite: FCWR 101 or WRIT 101 Further development of the academic writing process, critical thinking, and analytical reading skills taught in FCWR 101. Focus on academic research planning, source evaluation skills, and audience awareness leading to a documented research paper. Specific attention to academic integrity in research writing. Classroom Hours - Laboratory and/or Studio Hours – Course Credits: 3-0-3 |
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| FCWR 302 | Communication for Healthcare Careers | 3 |
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Prerequisite: Prerequisite: Take one course in each group: Group 1 (FCWR 101 or FCWR 111 or WRIT 101 or WRIT 111) and Group 2 (FCWR 151 or FCWR 161 or WRIT 151 or WRIT 161) Building on courses taken in their majors, students will learn and apply concepts of effective written and oral expression appropriate for careers in the health and biology professions. In addition to closely examining a variety of texts across the discipline, students will develop public speaking skills while also learning to collaborate on grant proposals, literature reviews, pamphlets and posters, and a research paper. Topics covered include the rhetoric of writing in the health professions, ethics, images in the sciences, grant- and abstract writing, and researching and writing publishable manuscripts. Course work includes a computer lab component. Classroom Hours - Laboratory and/or Studio Hours – Course Credits: 3-0-3 |
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| –OR– | ||
| Please view all course descriptions: http://www.nyit.edu/courses | ||
| FCWR 304 | Communication for Technical Professions | 3 |
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Prerequisite: Prerequisite: Take one course in each group: Group 1 (FCWR 101 or FCWR 111 or WRIT 101 or WRIT 111) and Group 2 (FCWR 151 or FCWR 161 or WRIT 151 or WRIT 161) Building on courses taken in their majors, students will learn and apply concepts of effective written and oral expression appropriate for careers in the technology professions, such as engineering and computer science. In addition to modes of technical discourse (definition, description, analysis, interpretation), this course emphasizes strategies for effective business communication in the technical professions and stylistics of technical communication. Methods and procedures of research are explored in depth. Course work includes a computer lab component, oral presentation of final reports using presentation software, and exploration of appropriate technology for technical communication. Classroom Hours - Laboratory and/or Studio Hours – Course Credits: 3-0-3 |
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| Total: 9 Credits | ||
| Data Literacy | Credits: | |
| DATA 101 | Making Sense of a Data-Oriented Society | 3 |
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This course introduces students to the power of data as applied to real-life problems in today's data-driven world. Students will learn basic statistical concepts, how to identify reliable data, and to think critically about how to extract meaning from data. The course will discuss various biases, including social biases, how they affect data gathering and analysis, and how to address these biases. The course will also address ethical and moral issues associated with statistics, data collection and visualization, and data analysis. Students will learn how to present a narrative supported by data. Classroom Hours - Laboratory and/or Studio Hours – Course Credits: 3-0-3 |
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| Seminars (select courses from at least three of the four areas) | Credits: | |
| ICBS 3XX | Behavioral Science choice | 3 |
| Please view all course descriptions: http://www.nyit.edu/courses | ||
| ICLT 3XX | Literature choice | 3 |
| Please view all course descriptions: http://www.nyit.edu/courses | ||
| ICPH 3XX | Philosophy choice | 3 |
| Please view all course descriptions: http://www.nyit.edu/courses | ||
| ICSS 3XX | Social Science choice | 3 |
| Please view all course descriptions: http://www.nyit.edu/courses | ||
| Total: 12 Credits | ||
| Students must take four seminar courses from at least three different areas of study. | ||
| Math and Science Requirement | Credits: | |
| MATH 170 | Calculus I | 4 |
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Prerequisite: Prerequisite: MATH 141 or Math Placement Exam. Study of lines and circles. Functions, limits, derivatives of algebraic functions, introduction to derivatives of trigonometric functions. Application of derivatives to physics problems, related rates, maximum-minimum word problems and curve sketching. Introduction to indefinite integrals. The conic sections. Classroom Hours - Laboratory and/or Studio Hours – Course Credits: 5-0-4 |
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| BIOL 110 | General Biology | 4 |
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The similarity in living things is demonstrated by a molecular and cellular approach to biology. After introductory biochemistry, the cell as the basic unit of life is studied structurally and metabolically. Life functions are examined from a cellular and from a vertebrate-organismic viewpoint. The central theme is the flow of energy between the biosphere and the ecosphere. The scientific method and hypothesis-testing are stressed as a means of investigation and forming conclusions. Collaborative laboratory assignments will include microscopic studies of the cell, its functions, and the dissection of a fetal pig. Classroom Hours - Laboratory and/or Studio Hours – Course Credits: 3-3-4 |
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| Total: 8 Credits | ||
Major Requirements
| Biology | Credits: | |
| BIOL 150 | General Biology II | 4 |
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Prerequisite: Prerequisite: BIOL 110 The variety of living things is demonstrated by a study of representative plants and animals, emphasizing the viewpoints of taxonomy, phylogeny, morphology, and physiology. The continuity of life is demonstrated through studies in reproduction, genetics, and organic evolution. Scientific inquiry and critical thinking strategies are emphasized. Collaborative laboratory assignments include the dissection and study of fixed and living specimens representing the whole range of life. Classroom Hours - Laboratory and/or Studio Hours – Course Credits: 3-3-4 |
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| BIOL 233 | Genetics | 4 |
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Prerequisite: Prerequisites: BIOL 150, CHEM 150 A study of the fundamental theories, methods, and application of genetics. Mendelian genetics, the foundation for the discipline, will be discussed as well as recent advances, including recombinant DNA research and cloning. Operational or modern genetics will be compared to traditional theories. Other topics will include: the operon, microbial genetics, the triplet code, complementation analysis, extra chromosomal inheritance, and population genetics. Classroom Hours - Laboratory and/or Studio Hours – Course Credits: 3-3-4 |
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| BIOL 250 | Biostatistics | 3 |
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Prerequisite: Prerequisites: BIOL 110, MATH 136 or greater This course provides students with a foundation in statistics with special focus on biomedical applications such as epidemiology, combined with an introduction in R, a robust and widely used statistical package. Topics covered include: descriptive statistics, probabilities, frequency distributions, hypothesis testing, Fisher and Chi-square tests, Z-score, data normalization and T-test. Additionally, more elaborated strategies including Analysis of Variance, correlation, linear regression and Bayesian statistics will be introduced, as these methods are considered essential tools for biomedical sciences. Classroom Hours - Laboratory and/or Studio Hours – Course Credits: 3-0-3 |
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| BIOL 336 | Molecular Biology | 3 |
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Prerequisite: Prerequisite: BIOL 335 or BIOL 233 Molecular Biology explores the nature of gene structure and function. This course will focus on how proteins and nucleic acids interact to control intracellular processes and cellular behavior in general. Emphasis will be on various molecular mechanisms that include DNA replication, recombination, repair, transposition, transcription, translation, as well as chromatin structure and function, splicing. The course will also include information on gene/genome editing techniques and the effect of non-coding RNAs on gene regulation. Classroom Hours- Laboratory and/or Studio Hours- Course Credits: 3-0-3 Classroom Hours - Laboratory and/or Studio Hours – Course Credits: 3-0-3 |
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| BIOL 340 | Biochemistry | 4 |
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Prerequisite: Prerequisite: BIOL 110 and CHEM 210. Life Sciences Osteopathy majors: Prerequisite BIOL 150 and co-requisite CHEM 210. A practical introduction to the fundamentals of the structure and properties of the biomolecules in close context with their metabolism. Major emphasis is placed on the dynamic nature of biochemistry and the interrelationships of the various metabolic pathways that make up the totality of life. Work in the laboratory illustrates the more common biochemistry techniques and principles encountered in the lecture. Classroom Hours - Laboratory and/or Studio Hours – Course Credits: 3-3-4 |
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| BIOL 370 | Advanced Biochemistry | 3 |
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Prerequisite: Prerequisites: BIOL 340, CHEM 250 A practical introduction to the fundamentals of the structure and properties of the biomolecules in close context with their metabolism. Major emphasis is placed on the dynamic nature of biochemistry and the interrelationships of the various metabolic pathways that make up the totality of life. Classroom Hours - Laboratory and/or Studio Hours – Course Credits: 3-0-3 |
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| BIOL 432 | Cell Biology | 3 |
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Prerequisite: Prerequisite: BIOL 340 Biochemical and biophysical aspects of cellular structures and functions are covered. Classroom Hours - Laboratory and/or Studio Hours – Course Credits: 3-0-3 |
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| Total: 24 Credits | ||
| Chemistry | Credits: | |
| CHEM 110 | General Chemistry | 4 |
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Prerequisite: Co-requisite: MATH 135 or TMAT 135, MATH 136 or TMAT 155, MATH 141, MATH 161, or MATH 170 An introduction to theoretical and inorganic chemistry. Studies include: types of matter, atomic structure, the periodic table, chemical bonding, states of matter, solutions, chemical reactions, gas laws, and chemical calculations. Laboratory work illustrates common laboratory techniques as well as chemical principles. Classroom Hours - Laboratory and/or Studio Hours – Course Credits: 3-3-4 |
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| CHEM 150 | General Chemistry II | 4 |
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Prerequisite: Prerequisite: CHEM 110 A continuation of CHEM 110. Topics to be covered include thermochemistry, chemical kinetics, chemical equilibria, acids and bases, ionic equilibria, oxidation-reduction reactions, and electrochemistry. Laboratory work illustrates the principles discussed in the lecture. Classroom Hours - Laboratory and/or Studio Hours – Course Credits: 3-3-4 |
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| CHEM 210 | Organic Chemistry I | 4 |
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Prerequisite: Prerequisite: CHEM 150 This course includes the study of the stereochemistry and electronic structure of aliphatic and aromatic compounds, and the properties of their functional groups. Laboratory work consists of the determination of physical constants and the preparation of various organic compounds. Classroom Hours - Laboratory and/or Studio Hours – Course Credits: 3-3-4 |
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| CHEM 250 | Organic Chemistry II | 4 |
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Prerequisite: Prerequisite: CHEM 210 A continuation of Organic Chemistry I. Studies include: the advanced theoretical treatment of reaction mechanisms, spectroscopic properties of organic compounds, and configurations of some important biological systems. Laboratory work consists of more advanced organic syntheses and qualitative organic analysis. Classroom Hours - Laboratory and/or Studio Hours – Course Credits: 3-3-4 |
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| CHEM 340 | Bioanalytical Chemistry | 3 |
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Prerequisite: Prerequisites: BIOL 110, CHEM 150, CHEM 250 This course presents the fundamentals of bioanalytical chemistry and provides an overview of the separation, detection, identification and quantification of biological samples in different settings. Emphasis is placed on techniques commonly employed to study the structure, function, and interactions of biomolecules. Classroom Hours - Laboratory and/or Studio Hours – Course Credits: 3-0-3 |
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| CHEM 410 | Physical Chemistry I | 4 |
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Prerequisite: Prerequisite: CHEM 310 and Co- requisite : MATH 170 A study of the fundamental principles of modern physical chemistry. Topics include: the kinetic theory of gases, thermodynamics, thermochemistry, properties of solutions, and chemical kinetics. Laboratory work is designed to illustrate the fundamental laws and basic physicochemical methods. Classroom Hours - Laboratory and/or Studio Hours – Course Credits: 3-0-4 |
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| CHEM 450 | Physical Chemistry II | 4 |
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Prerequisite: Prerequisite: CHEM 410, Co-requisite: MATH 180 A continuation of Physical Chemistry I. Topics include: electrochemistry, chemical bonding, spectroscopy, photochemistry, physical biochemistry, and nuclear chemistry. Laboratory work consists of electrode phenomena, spectrophotometric measurements, chemical catalysis, and radiochemistry. Classroom Hours - Laboratory and/or Studio Hours – Course Credits: 3-3-4 |
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| Total: 27 Credits | ||
| Mathematics | Credits: | |
| MATH 180 | Calculus II | 4 |
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Prerequisite: Prerequisite: MATH 170. Students in BS Electrical and Computer Engineering and BS Mechanical Engineering must earn a grade of C or better in MATH 170. Riemann sums, the definite integral, the fundamental theorem of the calculus. Area, volumes of solids of revolution, arc length, work. Exponential and logarithmic functions. Inverse trigonometric functions. Formal integration techniques. L'Hopital's rule, improper integrals. Polar coordinates. Classroom Hours - Laboratory and/or Studio Hours – Course Credits: 5-0-4 |
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| Physics | Credits: | |
| PHYS 170 | General Physics I | 4 |
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Prerequisite: Co-requisite: MATH 170 A basic course covering vectors, Newton's laws of motion, particle kinematics and dynamics, work, energy, momentum, and rotational motion. Classroom Hours - Laboratory and/or Studio Hours – Course Credits: 4-2-4 |
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| —OR— | ||
| Please view all course descriptions: http://www.nyit.edu/courses | ||
| PHYS 175 | General Physics for Pre-Med I | 5 |
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Prerequisite: Co-requisite: MATH 170 A basic course in physics for the student in the Combined Baccalaureate/Osteopathic Physician Program. Covers vectors, forces and torques, dynamics, energy momentum, fluids, gasses, liquids, solids, heat and thermodynamics. Classroom Hours - Laboratory and/or Studio Hours – Course Credits: 5-2-5 |
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| PHYS 180 | General Physics II | 4 |
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Prerequisite: Prerequisite: PHYS 170. Co-requisite: MATH 180. Students in BS Electrical and Computer Engineering and BS Mechanical Engineering must earn a grade of C or better in PHYS 170. A continuation of PHYS 170. Topics include fluids, wave motion, electric fields and electric potential, DC circuits, magnetic fields, capacitance and inductance, AC circuits, and electromagnetic waves. Classroom Hours - Laboratory and/or Studio Hours – Course Credits: 4-2-4 |
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| —OR— | ||
| Please view all course descriptions: http://www.nyit.edu/courses | ||
| PHYS 185 | General Physics for Pre-Med II | 5 |
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Prerequisite: Prerequisite: PHYS 175 A continuation of PHYS 175. Includes waves, sound, light, optics, electricity, current, magnetism, instrumentation, atoms and nuclei. Classroom Hours - Laboratory and/or Studio Hours – Course Credits: 5-2-5 |
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| Total: 8–10 Credits | ||
| Students choose between general physics or physics for pre-med sequence and take PHYS 170 and 180 OR PHYS 175 and 185. | ||
| Project Lab or Research* | Credits: | |
| BIOL/CHEM 395 | Introduction to Research Literature (required) | 3 |
| Please view all course descriptions: http://www.nyit.edu/courses | ||
| BIOL/CHEM 48X | Research Project Lab choice | 3 |
| Please view all course descriptions: http://www.nyit.edu/courses | ||
| –OR– | ||
| Please view all course descriptions: http://www.nyit.edu/courses | ||
| BIOL/CHEM 49X | Independent Research choice | 3 |
| Please view all course descriptions: http://www.nyit.edu/courses | ||
| Total: 6 Credits | ||
| * All students take BIOL/CHEM 395, then choose between a biology or chemistry project lab or independent research. | ||
| Biology Pool Electives (choose at least one) | Credits: | |
| BIOL 315 | Neuroscience | 3 |
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Prerequisite: Prerequisite: BIOL 310 or BIOL 311 The student will acquire a basic understanding of the anatomy of the nervous system and its functioning. Histology of nervous tissue, major divisions of the central and peripheral nervous systems and embryological development are introduced. The topographic and intimal anatomy of the central nervous system, including the spinal cord, brainstem, midbrain, diencephalon and forebrain, are then discussed. Functional aspects are emphasized and examples of common clinical problems are given. A systems approach is also used to introduce the special senses, including vision, audition, olfaction, and the general systems of sensation and motor functioning. The hypothalamus, the autonomic nervous system and the limbic areas are also presented. Neuroscience and clinical subjects are also emphasized, as well as higher cognitive functioning, reflex activity and circadian rhythms. Classroom Hours - Laboratory and/or Studio Hours – Course Credits: 3-0-3 |
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| BIOL 331 | Virology | 3 |
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Prerequisite: Prerequisite: BIOL 150 This course examines the fundamental principles of virology. Viral replications strategies will be covered in depth for selected viral families, with the intention of broadening students' understanding of gene regulation and nucleic acid replication. Viral structure, pathogenesis, epidemiology, antivirals and laboratory methods will be taught for a broad range of viruses. Students will apply their knowledge towards the understanding of molecular biotechnology and development of commercial applications. Classroom Hours - Laboratory and/or Studio Hours – Course Credits: 3-0-3 |
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| BIOL 332 | Developmental Biology | 3 |
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Prerequisite: Prerequisites: BIOL 150 and (BIOL 335 or BIOL 233) A study of the development of the vertebrate organism from ovum to adult. Topics include cleavage, organogenesis, fertilization, regeneration, and comparative developmental patterns. Laboratory exercises include work with living and preserved specimens. Classroom Hours - Laboratory and/or Studio Hours – Course Credits: 3-3-4 |
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| BIOL 341 | Genetic Engineering | 3 |
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Prerequisite: Prerequisite: BIOL 335 or BIOL 233 An introduction into the realm of molecular bioengineering with specific focus on genetic engineering. This course introduces the structure and function of DNA, the flow of genetic information in a cell, genetic mechanisms, the methodology involved in recombinant DNA technology and its application in society in terms of cloning and genetic modification of plants and animals (transgenics), biotechnology (pharmaceutics), bioprocessing (production and process engineering with a specific focus on the production of genetically engineered products), and gene therapy. Further, societal issues involving ethical and moral considerations, consequences of regulation, as well as risks and benefits of genetic engineering will be discussed. Classroom Hours - Laboratory and/or Studio Hours – Course Credits: 3-0-3 |
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| BIOL 346 | Immunology | 3 |
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Prerequisite: Prerequisite: BIOL 310, BIOL 330 This course will explore how the body defends itself from pathogens and foreign bodies with an emphasis on the cellular and non-cellular components of the human immune system and the ways in which these components interact to resist disease. Classroom Hours - Laboratory and/or Studio Hours – Course Credits: 3-0-3 |
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| BIOL 350 | Bioinformatics | 3 |
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Prerequisite: Prerequisites: BIOL 233, BIOL 250 This course covers a large spectrum of computational biology, and teaches students the foundations of bioinformatics, genomics, molecular evolution, and machine learning. Topics include: introduction to UNIX systems and commands, multiple sequence alignments and phylogenetics, next generation sequencing and gene expression analysis, and basic concepts of machine learning, such as sensitivity, specificity and ROC curve. Optimization and classification strategies such as principal component analysis will also be covered. Classroom Hours - Laboratory and/or Studio Hours – Course Credits: 3-0-3 |
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| BIOL 456 | Pharmacology | 3 |
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Prerequisite: Prerequisite: (BIOL 310 or BIOL 311) and (CHEM 215 or BIOL 340) This course will examine drugs' mechanism of action on a cellular and molecular level, and how they produce their therapeutic and adverse effects. In addition, the way in which drugs are administered, what the drug does to the body and what the body does to the drug, including influencing their absorption,distribution, metabolism and excretion, will be discussed. Classroom Hours - Laboratory and/or Studio Hours – Course Credits: 3-0-3 |
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| BIOL 461 | Cancer Biology | 3 |
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Prerequisite: Prerequisite: BIOL 335 or BIOL 233 This course covers the molecular and cellular mechanisms of cancer development. It builds on the fundamentals of cell biology and explains the basic mechanisms underlying cell growth, differentiation, and development, and how these processes are altered in cancer cells. Key concepts include cell cycle, mutation and DNA repair, signaling pathways, oncogenes and tumor suppressor genes, cancer-causing viruses, and a summary of diagnosis, treatment rational and therapies. Literature-based research assignment topics include environmental carcinogens such as chemicals and radiation, and agents that may prevent cancer. Student completing this course will acquire and understanding of cancer development and various anticancer therapies. Classroom Hours - Laboratory and/or Studio Hours – Course Credits: 3-0-3 |
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| Total: 3–6 Credits | ||
| Of the four restricted electives, at least one must come from the Chemistry Pool and one from the Biology Pool. | ||
| Chemistry Pool Electives (choose at least one) | Credits: | |
| CHEM 330 | Nanoscience and Nanotechnology | 3 |
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Prerequisite: Prerequisites: CHEM 150, PHYS 225 or PHYS 185 This introductory course offers a comprehensive overview of the fundamental principles of nanoscience and their applications within the realm of nanotechnology. The curriculum delves into the instrumentation and principles that are pertinent to the nanoscale, exploring the current state-of-the-art advancements and projecting future applications. Additionally, the course covers the utilization of inorganic and biological nanomaterials in various disciplines such as chemistry, engineering, and medicine. Classroom Hours - Laboratory and/or Studio Hours – Course Credits: 3-0-3 |
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| CHEM 350 | Instrumental Analysis | 3 |
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Prerequisite: Prerequisite: CHEM 310 This course represents a study of the operational principles and application of the instrumental methods for quantitative identification of compounds and determination of their chemical structure. Students will learn about principles involved in operation and data analysis for an array of modern laboratory instruments corresponding to electrochemical, spectrophotometric, and chromatographic methods. The key aspect of the class is for students to become knowledgeable of the scope of applicability as well as advantages and disadvantages of each method. The emphasis of this course is on learning the operational features and developing the insight that is necessary to choose the right tool to provide a quantitative solution to a given chemical problem. Classroom Hours - Laboratory and/or Studio Hours – Course Credits: 3-0-3 |
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| CHEM 430 | Biophysical Chemistry | 3 |
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Prerequisite: Prerequisites: BIOL 340, MATH 170, PHYS 180 or PHYS 185 This is a one-semester class that explores biochemistry from a physical chemistry perspective. Topics covered include molecular recognition, signaling processes, protein folding kinetics, equilibrium thermodynamics, as well as separation and spectroscopic characterization methods as applied to biomolecules. The emphasis of the course is on structure-function relationships and experimental techniques for probing structure and dynamics of biological systems. When you complete the course, you will understand how scientists apply physical chemistry to study the myriad of processes inside the living cell. Classroom Hours - Laboratory and/or Studio Hours – Course Credits: 3-0-3 |
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| CHEM 455 | Computational Chemistry | 3 |
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Prerequisite: Prerequisite: CHEM 410 and CHEM 450 This course provides the basic theoretical background of computational chemistry and focuses on acquiring practical skills to perform molecular modeling in solving chemical problems. Lectures will introduce several molecular modeling methods in computational chemistry (semi-empirical and ab-initio methods, density functional theory, molecular mechanics, molecular dynamics), which are used to investigate molecular geometries (conformations and the absolute configuration) as well as predict molecular and spectroscopic properties. Through hands on project based exercises, students will become familiar with different molecular modeling software packages and associated visualization programs: Gaussian, Gauss-view, Spartan, Macromodel, Schrodinger, suite of applets. Class will be also engaged in discussion of recent applications from selected journal articles. The emphasis will be made on understanding and critically assessing the applicability of computational methods to specific chemistry problems, rather than memorization of specific theoretical details regarding algorithms. Upon completion of the course, students will become familiar with essential computational chemistry methods, the key existing software and how to select the right method for the particular chemical problem. Classroom Hours - Laboratory and/or Studio Hours – Course Credits: 3-0-3 |
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| CHEM 470 | Inorganic Chemistry | 3 |
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Prerequisite: Prerequisite: CHEM 410 Inorganic Chemistry (Chemistry 470) is a one semester course that presents contemporary theories about molecular structure and reactivity and applies them to inorganic materials, catalysis, nanotechnology, and bioinorganic chemistry. The course extends the application of fundamental chemical theories of structure, bonding, thermodynamics, and kinetics that are developed in prerequisite courses (Organic Chemistry I and II (Chem 210/250), Physical chemistry I and II (Chem 410/450) to current problems in the chemistry of main group and transition elements. Group theory will be introduced to elucidate the symmetry, structure, bonding, and spectroscopy of the d-block elements. The course prepares students for advanced study in chemistry, biology, or biochemistry and provides an introduction to topics of interest for students preparing for careers in chemical industry. Classroom Hours - Laboratory and/or Studio Hours – Course Credits: 3-0-3 |
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| Total: 3–6 Credits | ||
| Of the four restricted electives, at least one must come from the Chemistry Pool and one from the Biology Pool. | ||
| Miscellaneous Pool Electives | Credits: | |
| BIOL 235 | Microbiology | 3 |
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Prerequisite: Prerequisite: BIOL 150 except BS Health & Wellness and BS Nursing A first course in microbiology which treats the anatomy, physiology, and relationships of bacteria, fungi, viruses, Rickettsiae, and protozoa. Included are discussions of the role of microorganisms in the food industry, in the environment, and in health. Classroom Hours - Laboratory and/or Studio Hours – Course Credits: 3-3-4 |
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| BIOL 238 | Introduction to Biotechnology | 3 |
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Prerequisite: Prerequisites: BIOL 150 An introduction into the realm of modern biotechnology and its application. This courses introduces the historical development of biotechnology and its contemporary applications, including, microbial fermentation/bioprocessing, bioreactors, production of fermentation products (protein therapeutics, monoclonal antibodies, vaccines, others) molecular diagnostics, bioremediation and environmental biotechnology, aquatic biotechnology, biowarfar and bioterrorism and nanobiotechnology. Further, societal issues involving ethical and moral implications, perceptions and fears, intellectual property, safety, risks and regulatory issues, as well as economics of biotechnology will be discussed. Classroom Hours - Laboratory and/or Studio Hours – Course Credits: 3-0-3 |
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| BIOL 335 | Recombinant DNA Lab | 3 |
| Please view all course descriptions: http://www.nyit.edu/courses | ||
| BIOL 441 | Contemporary Biotechnology | 3 |
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Prerequisite: Prerequisite: BIOL 440 or BIOL 341 An introduction into the realm of modern biotechnology and its application. This courses introduces the historical development of biotechnology and its contemporary applications, including, microbial fermentation/bioprocessing, bioreactors, production of fermentation products (protein therapeutics, monoclonal antibodies, vaccines, others) molecular diagnostics, bioremediation and environmental biotechnology, aquatic biotechnology, biowarfar and bioterrorism and nanobiotechnology. Further, societal issues involving ethical and moral implications, perceptions and fears, intellectual property, safety, risks and regulatory issues, as well as economics of biotechnology will be discussed. Classroom Hours - Laboratory and/or Studio Hours – Course Credits: 3-0-3 |
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| BIOL 442 | Bioprocessing | 3 |
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Prerequisite: Prerequisites: Take one course from this group (BIOL 341 or BIOL 440) and BIOL 340 BIOL 442 will provide an introduction into the realm of bioprocessing. Specifically, this course will cover the overall steps in bioprocessing development, introduction to some engineering calculations, data analysis and interpretation, fundamentals of mass and heat transfer principles, downstream processing, bioreactor design and application, sterilization, microbial growth kinetics and fermentation, and utilizing genetically modified organisms. Classroom Hours- Laboratory and/ or Studio Hours- Course Credits: 3-0-3. Classroom Hours - Laboratory and/or Studio Hours – Course Credits: 3-0-3. |
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| PHYS 366 | Biophysics | 3 |
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Prerequisite: Prerequisite: PHYS 180 This course will demonstrate how a myriad of biological processes are governed by physical laws. Beginning with a molecular perspective, transitioning to a cellular and ultimately a network level, the student will learn how mechanics, statistical mechanics, thermodynamics, and polymer dynamics govern emergent properties of biological soft matter. Classroom Hours - Laboratory and/or Studio Hours – Course Credits: 3-0-3 |
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| BIOL/CHEM 48X/49X | Research Project Lab/Independent Research | 3–4 |
| Please view all course descriptions: http://www.nyit.edu/courses | ||
| Total: 3–6 Credits | ||
| General Electives | Credits: | |
| Choose liberal arts electives in consultation with an advisor. | 9 | |
| Please view all course descriptions: http://www.nyit.edu/courses | ||
| Total Required Credits: 122–124 |