1 Convert the molar format of the Gibbs force of reaction, Δ_kF_nO2 [kJ/mol], into the electrical format, Δ_kF_eO2 [V]. Which physicochemical constant is required?

2 What is the meaning of the symbol z_O2?

3 How are the units of electric energy [J] and electric force [V] related?

4 Express -460 kJ/mol O₂ as electrical force in units of volt [V].

5 Why should we do that?

1 The Oroboros-O2k is primarily designed for which type of research?

2 Peter Mitchell's chemiosmotic coupling theory places fundamental importance on what concept for bioenergetics?

3 Which is NOT a parameter measured by integrating fluorometry into high-resolution respirometry?

4 The statement that mitochondrial fitness "solely depends on the genetic makeup of the individual" is:

5 What does the term "bioblasts" refer to in the context of mitochondrial physiology?

6 Which of the following is NOT a result of a measurement by the Oroboros-O2k?

7 What components constitute the protonmotive force (pmF) essential for ATP synthesis in mitochondria?

8 High-resolution respirometry (HRR) is primarily used for what purpose?

9 Oxygen concentration impacts mitochondrial respiratory control by:

10 The "Q-junction" in mitochondrial respiratory control serves as:

11 SUIT protocols in mitochondrial research are designed to:

12 NADH-linked substrates are used in physiological respiratory states to:

13 The primary purpose of integrating fluorometry with high-resolution respirometry is to:

14 Which statement accurately describes the significance of LEAK respiration in the context of mitochondrial function?

15 In mitochondrial research, the term "ET capacity" refers to:

16 Which of the following is NOT a direct measurement capability of the Oroboros-O2k?

17 The addition of fluorescent dyes in O2k-FluoRespirometer measurements allows for the assessment of:

18 The primary purpose of substrate-uncoupler-inhibitor titration (SUIT) protocols in mitochondrial research is to:

1 Given the formula for protonmotive force (pmF) as Δp = Δψ - 2.303 (RT/F) (ΔpH), where Δψ is the mitochondrial membrane potential, R is the gas constant, T is temperature in Kelvin, F is Faraday's constant, and ΔpH is the pH gradient across the mitochondrial membrane. If Δψ = 150 mV, T = 310 K, and ΔpH = 1, calculate the pmF in millivolts (mV). Assume R = 8.314 J/mol·K and F = 96485 C/mol.

2 The P/O ratio is an indicator of the efficiency of ATP synthesis relative to oxygen consumption. If 10 moles of ATP are produced for every 5 moles of oxygen consumed, what is the P/O ratio? What does this imply about the mitochondrial oxidative phosphorylation efficiency?

3 Assuming the standard reduction potential (E°') for NADH → NAD+ is -0.320 V and for O2 → H2O is +0.815 V, calculate the ΔE°' for the electron transport from NADH to O2. What does ΔE°' indicate about the potential energy available for ATP synthesis?

4 If the inner mitochondrial membrane has a surface area of 5.0 × 10^6 μm^2 per mg of protein and each Complex I can pump 4 protons across the membrane, how many protons are pumped per second assuming a turnover number of 100 s^-1 for Complex I?

5 Using the Gibbs free energy equation ΔG = ΔG°' + RT ln(Q), where ΔG°' is the standard free energy change, R is the gas constant, T is the temperature in Kelvin, and Q is the reaction quotient. Calculate the ΔG for ATP synthesis if ΔG°' = -30.5 kJ/mol, T = 310 K, and the ATP/ADP ratio (Q) is 10. Assume R = 8.314 J/(mol·K).

6 The efficiency of mitochondrial oxidative phosphorylation can be described by the equation η = (ΔG_ATP/ΔG_O2) × 100%, where ΔG_ATP is the free energy change for ATP synthesis, and ΔG_O2 is the free energy change for oxygen reduction. If ΔG_ATP = -50 kJ/mol and ΔG_O2 = -200 kJ/mol, what is the efficiency (η) of oxidative phosphorylation?

7 Consider a mitochondrial uncoupling scenario where the membrane potential (Δψ) is decreased by 50% without altering the proton gradient (ΔpH). Using the Nernst equation for protons, E = (RT/zF)ln([H+]out/[H+]in), predict how this change affects the pmF. Assume R, T, F, and z values remain constant.

1 Which mitochondrial preparation technique is most suitable for studying the effects of specific drugs on ATP production?

2 In the context of mitochondrial diseases, why is it crucial to maintain the integrity of mitochondrial membranes during preparation?

3 Match the mitochondrial preparation with its primary research application. Select the best match for "isolated mitochondrial fractions."

4 Considering the role of mitochondria in apoptosis, which aspect of mitochondrial preparations is crucial for studying their involvement in cell death mechanisms?

5 Which statement best reflects the importance of studying mitochondrial bioenergetics in the context of metabolic diseases?

6 In the process of selectively permeabilizing cells for mitochondrial studies, what is the main goal?

7 How does the concept of "bioblasts" relate to modern mitochondrial research?

8 What advantage does using tissue homogenates offer in mitochondrial bioenergetic studies?

9 In mitochondrial preparations, why is the assessment of ATP synthesis capacity critical for understanding diseases like Parkinson's and Alzheimer's?

10 Reflecting on the chapter's discussion, how do advancements in mitochondrial isolation techniques enhance our ability to treat metabolic disorders?