Respirometry


Respirometry is a general term that encompasses a number of techniques for obtaining estimates of the rates of metabolism of vertebrates, invertebrates, plants, tissues, cells, or microorganisms via an indirect measure of heat production.

Whole-animal metabolic rates

The metabolism of an animal is estimated by determining rates of carbon dioxide production and oxygen consumption of individual animals, either in a closed or an open-circuit respirometry system. Two measures are typically obtained: standard or basal metabolic rate and maximal rate. SMR is measured while the animal is at rest under specific laboratory and subject-specific conditions. VO2max is typically determined during aerobic exercise at or near physiological limits. In contrast, field metabolic rate refers to the metabolic rate of an unrestrained, active animal in nature. Whole-animal metabolic rates refer to these measures without correction for body mass. If SMR or BMR values are divided by the body mass value for the animal, then the rate is termed mass-specific. It is this mass-specific value that one typically hears in comparisons among species.

Closed respirometry

Respirometry depends on a "what goes in must come out" principle. Consider a closed system first. Imagine that we place a mouse into an air-tight container. The air sealed in the container initially contains the same composition and proportions of gases that were present in the room: 20.95% O2, 0.04% CO2, water vapor, 78% N2, 0.93% argon and a variety of trace gases making up the rest. As time passes, the mouse in the chamber produces CO2 and water vapor, but extracts O2 from the air in proportion to its metabolic demands. Therefore, as long as we know the volume of the system, the difference between the concentrations of O2 and CO2 at the start when we sealed the mouse into the chamber compared to the amounts present after the mouse has breathed the air at a later time must be the amounts of CO2/O2 produced/consumed by the mouse. Nitrogen and argon are inert gasses and therefore their fractional amounts are unchanged by the respiration of the mouse. In a closed system, the environment will eventually become hypoxic.

Open respirometry

For an open-system, design constraints include washout characteristics of the animal chamber and sensitivity of the gas analyzers. However, the basic principle remains the same: What goes in must come out. The primary distinction between an open and closed system is that the open system flows air through the chamber at a rate that constantly replenishes the O2 depleted by the animal while removing the CO2 and water vapor produced by the animal. The volumetric flow rate must be high enough to ensure that the animal never consumes all of the oxygen present in the chamber while at the same time, the rate must be low enough so that the animal consumes enough O2 for detection. For a 20 g mouse, flow rates of about 200 ml/min through 500 ml containers would provide a good balance. At this flow rate, about 40 ml of O2 is brought to the chamber and the entire volume of air in the chamber is exchanged within 5 minutes. For other smaller animals, chamber volumes can be much smaller and flow rates would be adjusted down as well. Note that for warm-blooded or endothermic animals, chamber sizes and or flow rates would be selected to accommodate their higher metabolic rates.

Calculations

Calculating rates of VO2 and/or VCO2 requires knowledge of the flow rates into and out of the chamber, plus fractional concentrations of the gas mixtures into and out of the animal chamber. In general, metabolic rates are calculated from steady-state conditions. To know the rates of oxygen consumed, one needs to know the location of the flow meter relative to the animal chamber, and whether or not reactive gases are present.
For an open system with upstream flow meter, water and CO2 removed prior to oxygen analyzer, a suitable equation is

For an open system with downstream flow meter, water and CO2 removed prior to oxygen analyzer, a suitable equation is

where
For example, values for BMR of a 20 g mouse might be FR = 200 mL/min, and readings of fractional concentration of O2 from an oxygen analyzer are FinO2 = 0.2095, FexO2 = 0.2072. The calculated rate of oxygen consumption is 0.58 mL/min or 35 mL/hour. Assuming an enthalpy of combustion for O2 of 20.1 joules per milliliter, we would then calculate the heat production for the mouse as 703.5 J/h.

Respirometry equipment

For open flow system, the list of equipment and parts is long compared to the components of a closed system, but the chief advantage of the open system is that it permits continuous recording of metabolic rate. The risk of hypoxia is also much less in an open system.
Pumps for air flow
Flow meter and flow controllers
Tubing and chambers
Analyzers
Finally, a computer data acquisition and control system would be a typical addition to complete the system. Instead of a chart recorder, continuous records of oxygen consumption and or carbon dioxide production are made with the assistance of an analog-to-digital converter coupled to a computer. Software captures, filters, converts, and displays the signal as appropriate to the experimenter's needs. A variety of companies and individuals service the respirometry community.

Mitochondrial metabolic rates

Inside the body oxygen is delivered to cells and in the cells to mitochondria, where it is consumed in the process generating most of the energy required by the organism.
Mitochondrial respirometry measures the consumption of oxygen by the mitochondria without involving an entire living animal and is the main tool to study mitochondrial function. Three different types of samples may be subjected to such respirometric studies:
isolated mitochondria ; permeabilized cells ; and permeabilized fibers or tissues. In the latter two cases the cellular membrane is made permeable by the addition of chemicals leaving selectively the mitochondrial membrane intact. Therefore, chemicals that usually would not be able to cross the cell membrane can directly influence the mitochondria. By the permeabilization of the cellular membrane, the cell stops to exist as a living, defined organism, leaving only the mitochondria as still functional structures.
Unlike whole-animal respirometry, mitochondrial respirometry takes place in solution, i.e. the sample is suspended in a medium. Today mitochondrial respirometry is mainly performed with a closed-chamber approach.

Closed-chamber system

The sample suspended in a suitable medium is placed in a hermetically closed metabolic chamber. The mitochondria are brought into defined “states” by the sequential addition of substrates or inhibitors. Since the mitochondria consume oxygen, the oxygen concentration drops. This change of oxygen concentration is recorded by an oxygen sensor in the chamber. From the rate of the oxygen decline the respiratory rate of the mitochondria can be computed.

Applications

Basic research

The functioning of mitochondria is studied in the field of bioenergetics. Functional differences between mitochondria from different species are studied by respirometry as an aspect of comparative physiology.

Applied research

Mitochondrial respirometry is used to study mitochodrial functionality in
mitochondrial diseases or diseases with a strong link to mitochondria, e.g. diabetes mellitus type 2, obesity and cancer. Other fields of application are e.g. sports science and the connection between mitochondrial function and aging.

Equipment

The usual equipment includes a seal-able metabolic chamber, an oxygen sensor, and devices for data recording, stirring, thermostatisation and a way to introduce chemicals into the chamber. As described above for whole-animal respirometry the choice of materials is very important. Plastic materials are not suitable for the chamber because of their oxygen storage capacity. When plastic materials are unavoidable polymers with a very low oxygen permeability may be used. Remaining oxygen diffusion into or out of the chamber materials can be handled by correcting the measured oxygen fluxes for the instrumental oxygen background flux. The entire instrument comprising the mentioned components is often called an oxygraph. The companies providing equipment for whole-animal rspirometry mentioned above are usually not involved in mitochondrial respiromety. The community is serviced at widely varying levels of price and sophistication by companies like Oroboros Instruments, Hansatech, Respirometer Systems & Applications, YSI Life Sciences or Strathkelvin Instruments.