FileTitleManuscript Id
Chapter Introductionlodish8e_ch2_1.html57223d4c757a2e0053000000
DLAP questionslodish8e_ch2_1_dlap.xml57223d4c757a2e0053000000
2.1 Covalent Bonds and Noncovalent Interactions lodish8e_ch2_2.html57223d4c757a2e0053000000
DLAP questionslodish8e_ch2_2_dlap.xml57223d4c757a2e0053000000
The Electronic Structure of an Atom Determines the Number and Geometry of the Covalent Bonds It Can Make lodish8e_ch2_3.html57223d4c757a2e0053000000
DLAP questionslodish8e_ch2_3_dlap.xml57223d4c757a2e0053000000
Electrons May Be Shared Equally or Unequally in Covalent Bonds lodish8e_ch2_4.html57223d4c757a2e0053000000
DLAP questionslodish8e_ch2_4_dlap.xml57223d4c757a2e0053000000
Covalent Bonds Are Much Stronger and More Stable Than Noncovalent Interactions lodish8e_ch2_5.html57223d4c757a2e0053000000
DLAP questionslodish8e_ch2_5_dlap.xml57223d4c757a2e0053000000
Ionic Interactions Are Attractions Between Oppositely Charged Ions lodish8e_ch2_6.html57223d4c757a2e0053000000
DLAP questionslodish8e_ch2_6_dlap.xml57223d4c757a2e0053000000
Hydrogen Bonds Are Noncovalent Interactions That Determine the Water Solubility of Uncharged Molecules lodish8e_ch2_7.html57223d4c757a2e0053000000
DLAP questionslodish8e_ch2_7_dlap.xml57223d4c757a2e0053000000
Van der Waals Interactions Are Weak Attractive Interactions Caused by Transient Dipoles lodish8e_ch2_8.html57223d4c757a2e0053000000
DLAP questionslodish8e_ch2_8_dlap.xml57223d4c757a2e0053000000
The Hydrophobic Effect Causes Nonpolar Molecules to Adhere to One Another lodish8e_ch2_9.html57223d4c757a2e0053000000
DLAP questionslodish8e_ch2_9_dlap.xml57223d4c757a2e0053000000
Molecular Complementarity Due to Noncovalent Interactions Leads to a Lock-and-Key Fit Between Biomolecules lodish8e_ch2_10.html57223d4c757a2e0053000000
DLAP questionslodish8e_ch2_10_dlap.xml57223d4c757a2e0053000000
Key Concepts of Section 2.1lodish8e_ch2_11.html57223d4c757a2e0053000000
DLAP questionslodish8e_ch2_11_dlap.xml57223d4c757a2e0053000000
2.2 Chemical Building Blocks of Cells lodish8e_ch2_12.html57223d4c757a2e0053000000
DLAP questionslodish8e_ch2_12_dlap.xml57223d4c757a2e0053000000
Amino Acids Differing Only in Their Side Chains Compose Proteins lodish8e_ch2_13.html57223d4c757a2e0053000000
DLAP questionslodish8e_ch2_13_dlap.xml57223d4c757a2e0053000000
Five Different Nucleotides Are Used to Build Nucleic Acids lodish8e_ch2_14.html57223d4c757a2e0053000000
DLAP questionslodish8e_ch2_14_dlap.xml57223d4c757a2e0053000000
Monosaccharides Covalently Assemble into Linear and Branched Polysaccharides lodish8e_ch2_15.html57223d4c757a2e0053000000
DLAP questionslodish8e_ch2_15_dlap.xml57223d4c757a2e0053000000
Phospholipids Associate Noncovalently to Form the Basic Bilayer Structure of Biomembranes lodish8e_ch2_16.html57223d4c757a2e0053000000
DLAP questionslodish8e_ch2_16_dlap.xml57223d4c757a2e0053000000
Key Concepts of Section 2.2lodish8e_ch2_17.html57223d4c757a2e0053000000
DLAP questionslodish8e_ch2_17_dlap.xml57223d4c757a2e0053000000
2.3 Chemical Reactions and Chemical Equilibrium lodish8e_ch2_18.html57223d4c757a2e0053000000
DLAP questionslodish8e_ch2_18_dlap.xml57223d4c757a2e0053000000
A Chemical Reaction Is in Equilibrium When the Rates of the Forward and Reverse Reactions Are Equal lodish8e_ch2_19.html57223d4c757a2e0053000000
DLAP questionslodish8e_ch2_19_dlap.xml57223d4c757a2e0053000000
The Equilibrium Constant Reflects the Extent of a Chemical Reaction lodish8e_ch2_20.html57223d4c757a2e0053000000
DLAP questionslodish8e_ch2_20_dlap.xml57223d4c757a2e0053000000
Chemical Reactions in Cells Are at Steady State lodish8e_ch2_21.html57223d4c757a2e0053000000
DLAP questionslodish8e_ch2_21_dlap.xml57223d4c757a2e0053000000
Dissociation Constants of Binding Reactions Reflect the Affinity of Interacting Molecules lodish8e_ch2_22.html57223d4c757a2e0053000000
DLAP questionslodish8e_ch2_22_dlap.xml57223d4c757a2e0053000000
Biological Fluids Have Characteristic pH Values lodish8e_ch2_23.html57223d4c757a2e0053000000
DLAP questionslodish8e_ch2_23_dlap.xml57223d4c757a2e0053000000
Hydrogen Ions Are Released by Acids and Taken Up by Bases lodish8e_ch2_24.html57223d4c757a2e0053000000
DLAP questionslodish8e_ch2_24_dlap.xml57223d4c757a2e0053000000
Buffers Maintain the pH of Intracellular and Extracellular Fluids lodish8e_ch2_25.html57223d4c757a2e0053000000
DLAP questionslodish8e_ch2_25_dlap.xml57223d4c757a2e0053000000
Key Concepts of Section 2.3lodish8e_ch2_26.html57223d4c757a2e0053000000
DLAP questionslodish8e_ch2_26_dlap.xml57223d4c757a2e0053000000
2.4 Biochemical Energetics lodish8e_ch2_27.html57223d4c757a2e0053000000
DLAP questionslodish8e_ch2_27_dlap.xml57223d4c757a2e0053000000
Several Forms of Energy Are Important in Biological Systems lodish8e_ch2_28.html57223d4c757a2e0053000000
DLAP questionslodish8e_ch2_28_dlap.xml57223d4c757a2e0053000000
Cells Can Transform One Type of Energy into Another lodish8e_ch2_29.html57223d4c757a2e0053000000
DLAP questionslodish8e_ch2_29_dlap.xml57223d4c757a2e0053000000
The Change in Free Energy Determines If a Chemical Reaction Will Occur Spontaneously lodish8e_ch2_30.html57223d4c757a2e0053000000
DLAP questionslodish8e_ch2_30_dlap.xml57223d4c757a2e0053000000
The ΔG°′ of a Reaction Can Be Calculated from Its Keqlodish8e_ch2_31.html57223d4c757a2e0053000000
DLAP questionslodish8e_ch2_31_dlap.xml57223d4c757a2e0053000000
The Rate of a Reaction Depends on the Activation Energy Necessary to Energize the Reactants into a Transition State lodish8e_ch2_32.html57223d4c757a2e0053000000
DLAP questionslodish8e_ch2_32_dlap.xml57223d4c757a2e0053000000
Life Depends on the Coupling of Unfavorable Chemical Reactions with Energetically Favorable Ones lodish8e_ch2_33.html57223d4c757a2e0053000000
DLAP questionslodish8e_ch2_33_dlap.xml57223d4c757a2e0053000000
Hydrolysis of ATP Releases Substantial Free Energy and Drives Many Cellular Processes lodish8e_ch2_34.html57223d4c757a2e0053000000
DLAP questionslodish8e_ch2_34_dlap.xml57223d4c757a2e0053000000
ATP Is Generated During Photosynthesis and Respiration lodish8e_ch2_35.html57223d4c757a2e0053000000
DLAP questionslodish8e_ch2_35_dlap.xml57223d4c757a2e0053000000
NAD+ and FAD Couple Many Biological Oxidation and Reduction Reactions lodish8e_ch2_36.html57223d4c757a2e0053000000
DLAP questionslodish8e_ch2_36_dlap.xml57223d4c757a2e0053000000
Key Concepts of Section 2.4lodish8e_ch2_37.html57223d4c757a2e0053000000
DLAP questionslodish8e_ch2_37_dlap.xml57223d4c757a2e0053000000
Key Terms lodish8e_ch2_38.html57223d4c757a2e0053000000
DLAP questionslodish8e_ch2_38_dlap.xml57223d4c757a2e0053000000
Review the Concepts lodish8e_ch2_39.html57223d4c757a2e0053000000
DLAP questionslodish8e_ch2_39_dlap.xml57223d4c757a2e0053000000
References lodish8e_ch2_40.html57223d4c757a2e0053000000
DLAP questionslodish8e_ch2_40_dlap.xml57223d4c757a2e0053000000