BME/ME 476 - BIOFLUID MECHANICS

James B. Grotberg, Ph.D., M.D.

Department of Biomedical Engineering

Class time: 4:30-6:30pm M,W

Class location: 1123 LBME

Text: Class notes, posted at end of each section

Website: Canvas

Email:

Course grading:

Exams

Distribution: 1 midterm, 1 final.

Format: Take-home. Problems selected from exam-eligible homework problems (see below).

Homeworks

Skill HWs:assigned with solutions, collected and graded check+, check, check-

Exam-eligible HWs: assigned, not collected, exams will be a subset of these.

Final grade based on Exams, 50% each, assuming Skill HWs satisfactory.

Office Hours:

Time: Monday 3-4pm, Wednesday 11am-12pm

Location: 1100 Gerstacker

Historically there is a strong correlation between the final grade and participation in office hours where HW problems are discussed.

Outline of Class Notes

ChapterTopic

1Introduction

2Variables, Parameters, Scalings

2.1 The Dropped Ball

2.2 Impact Time: Theory and Experiments

2.3 Scalings and Dimensionless Variables

2.4 The Thrown Ball: A Dimensionless Parameter

2.5 Scaling a Mechanical System: The Buckingham Pi Theorum

2.6 Thrown Ball Revisited: Scaling the Governing Equations First

2.7 Viscous and Buoyancy Effects of a Dropped Particle: Erythrocyte Sedimentation Rate

2.8 Microfluidic Cell Sorting

3Kinematics, Lagrangian &Eulerian Frames

3.1 Lagrangian and Eulerian Variables

3.2 Mappings and Inverse Mappings

3.3 Functions in Lagrangian and Eulerian Reference Frames

3.4 Partial derivatives in Eulerian and Lagrangian frames

3.5 Mapping Example: Stagnation Point Flow

3.6 Streamlines

3.7 Streaklines

3.8 Timelines

3.9 Aerosol Particle Deposition in the Lung

3.10 Numerical Methods

4Conservation of Mass

4.1 Mass Conservation from an Eulerian Control Volume

4.2 Incompressible Fluids

4.3 The Stream Function

4.4 Streamlines and Stream tubes

4.5 Conservation of Mass for a Soluble Species

4.6 Different Coordinate Systems

4.7 Kinematics of Fluid Deformation

4.8 The Reynolds Transport Theorum

4.9 Mass Conservation from a Lagrangian Control Volume

5Conservation of Momentum

5.1 Linear Momentum Conservation from an Eulerian Control Volume

5.2 Cauchy Momentum Equation

5.3 The Stress Tensor

5.4 Angular Momentum Conservation

5.5 Fluid Pressure

5.6 Stress Tensor and Momentum Conservation in Other Coordinate Systems

6Constitutive Equations I: Inviscid and Newtonian Fluids

6.1 Inviscid Fluid: Euler Equations

6.2 Bernoulli Equation

6.3 Newtonian Viscous Fluid

6.4 Constitutive Equation in Other Coordinate Systems

6.5 Navier-Stokes Equations

6.6 Scaling the Navier-Stokes Equations

6.7 Kinematics of a Fluid Element

6.8 Navier-Stokes Equations in other Coordinate Systems

7Steady Newtonian Viscous Flow

7.1 Hagen-Poiseuille Flow in a Circular Tube

7.2 Applying Poiseuille Law: Vascular Hemodynamics

7.3 Gravity and Boundary Driven Flow: Respiratory Mucociliary Clearance

7.4 Core-Annular Two-Phase Flow in a Circular Cylinder:Vascular and Respiratory Applications

7.5 Flow and Anatomical Evolution: Murray’s Law

7.6 Murray’s Law with Variable Length and Branch Angle

7.7 Flow in a Rectangular Duct: Microfluidic Channels

8Unsteady Newtonian Viscous Flow

8.1 Stokes First Problem

8.2 Stokes Second Problem

8.3 Oscillatory Flow in a Channel

8.4 High Frequency Ventilation

8.5 Oscillatory Flow in a Tube

8.6 Pulsatile Flow in a Tube

8.7 Mucus Transport from Cough

9Flow in Flexible Tubes

9.1 Steady Viscous Flow in a Flexible Tube

9.2 The Nonlinear Tube Law

9.3 Viscous Flow Limitation

9.4 Wave Speed and Inviscid Flow Limitation

9.5 Pulse Propagation in a Flexible Tube

9.6 Pulsatile Flow and Wave Propagation

9.7 Solutions to the Wave Equation

9.8 Waves at a Bifurcation: Transmission and Reflection

9.9 Flow Induced Oscillations

10Constitutive Equations II: Generalized Newtonian Fluids

10.1 Rheology and Constitutive Equations

10.2 Cauchy Equation for Generalized Newtonian Fluids

10.3 Power-Law Fluids

10.4 Herschel-Bulkley Fluids

10.5 Casson Fluid Model for Blood

10.6 Casson Fluid Flow in a Tube

10.7 More Constitutive Models

10.8 Viscometers and Viscometric Flows

11Lubrication Theory

11.1 The Slide Block

11.2 Slide Block Forces and Flows

11.3 A Model RBC in a Capillary

11.4 RBC Model Forces and Flow

11.5 Microcirculation and Apparent Blood Viscosity

11.6 Filtration Flow in a Capillary

11.7 Squeeze Film: Flow in Joints

11.8 Non-Newtonian Squeeze Film

12Laminar Boundary Layers

12.1 Boundary Layer Flow over a Flat Plate

12.2 Polynomial Approximations to Boundary Layer Flow

12.3 Entrance Flow in a Tube: Airways and Blood Vessels

12.4 Inspiratory Flow in the Tracheobronchial Tree

12.5 Flow in a Curved Tube

12.6 Flow Through a Bifurcation

12.7 Viscous Stagnation Point Flow

13Turbulence

13.1 Examples of Turbulent Flows in Biofluid Mechanics

13.2 Analysis of Turbulence

13.3 Fully Developed Turbulent Pipe Flow: The Moody Diagram

13.4 Turbulent Flow Near a Boundary

13.5 Turbulent Entrance Flow

13.6 Turbulent Boundary Layer on a Flat Plate

13.7 Integral Balances for Boundary Layer Flow over a Flat Plate

13.8 Solutions to the Momentum Integral Equation

14Constitutive Equations III: Viscoelastic Fluids

14.1 Viscoelastic Materials: Mucus and Blood

14.2 Maxwell Fluid Response to Step Inputs

14.3 Kelvin-Voigt Viscoelastic Solid: Biological Tissues

14.4 Maxwell Fluid - Oscillatory Forcing

14.5 Complex Fluid Viscosity

14.6 Kelvin-Voigt Solid - Oscillatory Forcing

14.7. Maxwell Constitutive Model in the Cauchy Equation

14.8 The Equivalent Approach for Fading Memory Fluid

14.9 Oscillating Flow over a Mucus Film: Respiratory Clearance

14.10 Oscillatory Squeeze Film with a Maxwell Fluid: Synovial Fluid

15Flow from Boundary Motion

16.Flow in Poroelastic Media:

17.Surface Tension & Stability: