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Development of Power Law Kinetic Models of Human Coagulopathies and E. coli Cell-Free Transcription.
Development of Power Law Kinetic Models of Human Coagulopathies and E. coli Cell-Free Transcription.
- 자료유형
- 학위논문
- Control Number
- 0017163125
- International Standard Book Number
- 9798384051442
- Dewey Decimal Classification Number
- 660
- Main Entry-Personal Name
- Vadhin, Sandra.
- Publication, Distribution, etc. (Imprint
- [S.l.] : Cornell University., 2024
- Publication, Distribution, etc. (Imprint
- Ann Arbor : ProQuest Dissertations & Theses, 2024
- Physical Description
- 206 p.
- General Note
- Source: Dissertations Abstracts International, Volume: 86-03, Section: B.
- General Note
- Advisor: Varner, Jeffrey.
- Dissertation Note
- Thesis (Ph.D.)--Cornell University, 2024.
- Summary, Etc.
- 요약Mathematical modeling is a tool that enables the investigation of phenomena that may be hard to measure or emulate experimentally. Traditional biochemical network modeling approaches are often complex and nonlinear and require the estimation of a large number of unknown parameters. The power-law formalism - or biochemical systems theory (BST) - which is based on generic model descriptions and yields reduced systems of non-linear ordinary differential equations, has become an area of interest since it was proposed in the 1960s by Savageau. The development of accurate lower-order models of biochemical kinetics would potentially streamline the modeling process in many applications. Toward this goal, we developed dynamic power-law models in two overarching topics: coagulopathies and cell-free systems. In this work, our models describe coagulatory and fibrinolytic pathways in pregnant patients, quantifying hypercoagulability at various stages of pregnancy. We then developed models of coagulation in hemophilia patients and were able to predict clotting dynamics. Finally, we developed a model of sequence-specific gene transcription in a cell-free system and successfully captured mRNA dynamics. Taken together, we have developed lower-order models that could be used in clinical, academic, and industrial applications.
- Subject Added Entry-Topical Term
- Chemical engineering.
- Subject Added Entry-Topical Term
- Biochemistry.
- Subject Added Entry-Topical Term
- Bioinformatics.
- Index Term-Uncontrolled
- Mathematical modeling
- Index Term-Uncontrolled
- Biochemical kinetics
- Index Term-Uncontrolled
- Cell-free system
- Index Term-Uncontrolled
- Hemophilia patients
- Added Entry-Corporate Name
- Cornell University Chemical Engineering
- Host Item Entry
- Dissertations Abstracts International. 86-03B.
- Electronic Location and Access
- 로그인을 한후 보실 수 있는 자료입니다.
- Control Number
- joongbu:657260
