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'''Haldane's decompression model''' is a [[
Haldane
<ref name=":1">{{Cite book |last1=Lang |first1=Michael A. |url=https://semspub.epa.gov/work/10/100006143.pdf |title=Diving for Science 2009: Proceedings of the American Academy of Underwater Sciences 28th Symposium |last2=Brubakk |first2=Alf O. |date=2009 |publisher=American Academy of Underwater Sciences |editor-last=Pollock |editor-first=N.W. |pages=112–124 |language=en |chapter=The Haldane Effect |chapter-url=https://www.tecvault.t101.ro/Haldane%20effect.pdf}}</ref>
Haldane observed that goats, saturated to depths of {{convert|165|ft|m}} of sea water, did not develop [[decompression sickness]] (DCS) if subsequent [[Decompression (diving)|decompression]] was limited to half the ambient pressure. Haldane constructed schedules which limited the critical supersaturation ratio to "2", in five hypothetical body tissue compartments characterized by their halftime. Halftime is also termed [[Half-life]] when linked to [[Exponential decay|exponential processes]] such as [[radioactive decay]]. Haldane's five compartments (halftimes: 5, 10, 20, 40, 75 minutes) were employed in decompression calculations and staged procedures for fifty years.▼
▲Haldane observed that goats, saturated to depths of {{convert|165|ft|m}} of sea water, did not develop [[decompression sickness]] (DCS) if subsequent [[Decompression (diving)|decompression]] was limited to half the ambient pressure. Haldane constructed schedules which limited the critical supersaturation ratio to "2", in five hypothetical body tissue compartments characterized by their halftime. Halftime is also termed [[Half-life]] when linked to [[Exponential decay|exponential processes]] such as [[radioactive decay]]. Haldane's five compartments (halftimes: 5, 10, 20, 40, 75 minutes) were
Previous theories to Haldane worked on "uniform compression", as Paul Bert pointed in 1878 that very slow decompression could avoid the [[caisson disease]], then Hermann von Schrötter defined in 1895 the safe "uniform decompression" rate to be of "one [[Atmosphere (unit)|atmosphere]] per 20 minutes". Haldane in 1907 worked on "''staged Decompression''" and proved it to be safer than "''uniform decompression''" and produced his decompression tables on that basis.▼
▲Previous theories to Haldane worked on "uniform compression", as Paul Bert pointed in 1878 that very slow decompression could avoid the [[caisson disease]], then Hermann von Schrötter
==Previous work==
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===Paul Bert===
[[Paul Bert]] (17 October 1833 – 11 November 1886) was a French physiologist who graduated at Paris as doctor of medicine in 1863, and doctor of science in 1866. He was appointed professor of physiology successively at Bordeaux (1866) and the Sorbonne (1869). Paul Bert was given the nickname of "Father of Aviation Medicine" after his work, ''La Pression barometrique'' (1878), a comprehensive investigation on the physiological effects of air-pressure, which pointed out that the symptoms of [[caisson disease]] could be avoided by means of very slow decompression. However, his work did not furnish data about safe decompression rates.<ref>
===Schrötter===
[[Hermann von Schrötter|Anton Hermann Victor Thomas Schrötter]] (5 August 1870 – 6 January 1928), an Austrian physiologist and physician who was a native of Vienna, was a pioneer of aviation and [[hyperbaric medicine]],<ref>[http://austria-forum.org/af/Wissenssammlungen/Essays/Medizin/Familie_Schr%C3%B6tter3 Die Familie Schrötter]</ref> and made important contributions in the study of [[decompression sickness]]. He studied medicine and [[natural science]]s at the Universities of [[University of Vienna|Vienna]] and [[University of Strasbourg|Strasbourg]], earning his medical degree in 1894, and during the following year receiving his [[Doctor of Philosophy|doctorate of philosophy]]. He was active in many fields of medicine and [[physiology]]. His first interest from 1895 was the investigation and combating of caisson disease, and during his tenure in [[Nussdorf, Vienna|Nussdorf]] he studied the numerous diseases that have occurred and was looking for ways of treatment and prevention.
His published report in 1900 with Dr. Richard Heller and Dr. Wilhelm Mager, on air pressure disease is considered the basic German-language work of diving and [[hyperbaric medicine]]. Schrötter, Heller and Mager framed rules for safe decompression and believed that the decompression rate of one atmosphere (atm) per 20 minutes would be safe. [[Leonard Erskine Hill]] and Greenwood decompressed themselves without serious symptoms after exposure to {{convert|6|atm|abbr=on}}.
==Haldane's work==
The [[British Admiralty|Admiralty]] Committee needed to frame definite rules for safe decompression in the shortest possible time for [[deep diving]], and hence, Haldane was commissioned in 1905 by the UK [[Royal Navy]] for this purpose, to design [[Decompression practice#Decompression tables|decompression tables]] for divers ascending from deep water.▼
▲The [[Admiralty]] Committee needed to frame definite rules for safe decompression in the shortest possible time for [[deep diving]], and hence, Haldane was commissioned in 1905 by the UK [[Royal Navy]] for this purpose, to design [[Decompression practice#Decompression tables|decompression tables]] for divers ascending from deep water.
In 1907 Haldane made a [[Diving chamber|decompression chamber]] to help make deep-sea divers safer and produced the first decompression tables after extensive experiments with animals. In 1908 Haldane published the first recognized decompression table for the British Admiralty. His tables remained in use by the Royal Navy till 1955.
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===Outline===
Haldane ran his experiments on some animals, illustrating the difference between different kinds of animals such as goats, guinea-pigs, mice, rats, hens and rabbits, but his main work and results were
Haldane stated in his
* When humans or animals are placed in compressed air, the blood passing through lungs takes up an amount of gas in simple solution. This amount increases in proportion to the increase in partial pressure of each gas present in the alveolar air.
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:* As regards to carbon dioxide, the experiments of Haldane and Greenwood showed that partial pressure of CO<sub>2</sub> in the alveolar air remains constant with the rise of atmospheric pressure, hence, there can be no increase in CO<sub>2</sub> in blood during exposure to compressed air.
:* As regards to nitrogen, considerations should be taken for the saturation in body tissues.
* [[File:From Haldane's Book - Figure-1 N2 Saturation.jpg|thumb
* If the pressure is rapidly diminished to normal after exposure to saturation in compressed air, the venous blood will give off the whole of its excess of dissolved nitrogen during its passage to the lungs. If gas bubbles are formed in consequence of too rapid decompression, they will increase in size by diffusion into them, and thus cause blocking of small vessels. In order to avoid the risk of bubbles being formed during decompression, the decompression should be slow, and the rate of blood circulation can be increased considerably by muscular exertion.
* [[File:Haldane's Desat of N2 with different parts of the body with half-sat in 5-10-20-40-75 minutes.jpg|thumb
* Diving period:
:* For short diving periods of less than seven to eight minutes with no repetitive dive: Haldane's experiments on goats showed that sudden decompression in less than a minute after exposures up to four minutes at {{convert|75|psi|bar|abbr=on}}, equivalent to {{convert|42|m|ft}} of sea water, goats did not develop any symptoms, even when exposures were raised to six minutes in some cases. This coincides with reports at that time from the Mediterranean of skilled Greek divers, diving to {{convert|30|fathom|m}} who, should their gear become entangled on the bottom, will cut their air-pipe and line, and blow themselves up to the surface in less than a minute.
:* With dives exceeding a few minutes or brief repetitive dives: Hill and
[[File:Haldane - Bends of fore-leg in a goat.jpg|thumb|220px|right|One of Haldane's bent goats. Note the bend in the left foreleg.<ref name=haldane>{{Cite journal |date=June 1908 |journal=The Journal of Hygiene |volume=8 |pages=342–443 |number=3 |pmid=20474365 |pmc=2167126 |last1=Boycott |first1=A. E. |title=The Prevention of Compressed-air Illness |last2=Damant |first2=G. C. |last3=Haldane |first3=J. S. |url=http://archive.rubicon-foundation.org/7489 |
* Experiments continued on goats, and symptoms observed on goats were noted each time on appropriated schedule to record the presence of symptoms not the presence of bubbles:
:* Bends, the commonest symptom. The limb, most commonly the fore-leg.
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:* Dyspnoea and death
:* Mechanical symptoms are not important, if goat suffered ear troubles during compression
* Experiments on goats included:<ref name="haldane" />
:* staged decompression on different pressures, and different decompression times, and included also comparison with uniform decompression. Results showed that a certain minimum pressure is required to give symptoms on goats and that duration of exposure to high pressures with different decompression times had also an influence.
:* Experiments compared between different types of animals and their susceptibility to decompression symptoms, and compared influence of size between short and long exposures, and decompression time.
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===Main results of Haldane’s work===
This work is published in "The Prevention of Compressed-air Illness" book. Results are published in same book under "Summary" in pages 424 and 425. The main conclusions of his decompression model are:<ref name="haldane" />
* In page 354, Haldane concluded: "It is clear that the rate of desaturation might be hastened by either (1) increasing the difference in nitrogen pressure between the venous blood and the air in the lungs, or (2) increasing the rate of blood circulation". So, in order to achieve faster desaturation, Haldane concluded that muscular exertion can considerably increase the rate of blood circulation, and thus "there should also be muscular exertion during decompression".
* In summary, page 424,
* Haldane published his "Decompression Tables" [[Media:Haldane's Decompression table-I in ft and psi.jpg|Table I]] and [[Media:Haldane's Decompression table-II in ft and psi.jpg|Table II]], on pages 442 and 443. For ease of use, convert feet to meters by multiplying by 0.3048, and from psi to [[Bar (unit)|bar]] by multiplying by 0.0689475729. These tables allow divers to ascend to half of their ambient absolute pressure and remain for a calculated decompression time before ascending further to half of the absolute pressure of the last stage. Haldane divided his schedules into Table I for "ordinary exposures" and Table II for "delay beyond the ordinary limits of time". Currently, when assessed, Table II decompression times were associated with great risk of decompression sickness.
* Haldane divided body tissues into different categories, and measured the nitrogen desaturation in each. This led to fast tissues and slow tissues concept, where some tissues fill up with gas and empty it out rapidly; these are the fast tissues. On the other hand, slow tissues are slow filling up and slow emptying out. Haldane portrayed the logarithmic trend of these tissues to fill up and empty out.
==Further developments on Haldane's principles==
The 2:1 ratio proposed by Haldane was found to be too conservative for fast tissues (short dives) and not conservative enough for slow tissues (long dives). The ratio also seemed to vary with depth. The ascent rates used on older tables were {{convert|18|m/min}}, but newer tables now use {{convert|9|m/min}}.<ref>{{
* Haldane introduced decompression tables based on five tissue compartments with half times of 5, 10, 20, 40 and 75 minutes.
* The [[US Navy]] refined Haldane's tables and introduced a model with nine tissues. They also introduced calculations for half-times starting from 5 minutes and reaching up to 240 minutes.
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==Haldane's related work and research==
{{see also|John Scott Haldane#Accomplishments}}
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Haldane had many other related researches:
* Established ''The Journal of Hygiene''<ref>
* Manufactured a decompression device to facilitate assistance to deep divers<ref name=":02">{{
* Established decompression procedures for air diving to 200 feet or 65 meters for the Royal Navy in 1907, after many animal experiments
* Described the [[Haldane effect]], a property of hemoglobin<ref name=":1" /><ref name=":03">{{Cite journal |last1=Sekhar |first1=K.C. |last2=Rao |first2=S.S.C. Chakra |date=2014 |title=John Scott Haldane: The father of oxygen therapy |journal=Indian Journal of Anaesthesia |volume=58 |issue=3 |pages=350–352 |doi=10.4103/0019-5049.135087 |issn=0019-5049 |pmc=4091013 |pmid=25024490 |doi-access=free}}</ref>
* Proposed a formula to determine the coefficients of saturation of different tissues in the body, his equation is based on [[Henry's law]]:
:<math>T_{N_2} = T_0 + (T_f - T_0) \left (1 - (1/2)^{t/t_0} \right )</math>
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==Contradicting work==
Although Haldane's model remains the basis for [[Decompression practice|modern decompression tables]], Haldane's first decompression tables proved to be far from ideal.<ref name=":1" /> Haldane's equation is used by many dive tables and dive computers today, even though
::* Asymmetry of saturation phenomena of inert gases (uptake and elimination),<ref name=":0" /><ref name=":2">{{Citation |last=Rusoke-Dierich |first=Olaf |title=Decompression Theory |date=2018 |work=Diving Medicine |pages=57–79 |editor-last=Rusoke-Dierich |editor-first=Olaf |url=https://doi.org/10.1007/978-3-319-73836-9_9 |access-date=2024-06-04 |place=Cham |publisher=Springer International Publishing |language=en |doi=10.1007/978-3-319-73836-9_9 |isbn=978-3-319-73836-9|url-access=subscription }}</ref>
::* Desaturation according to Hempleman's memorandum and those of Thalmann, taking into account circulating bubbles, VPM, [[Reduced gradient bubble model]].<ref>{{Cite journal |last=Hugon |first=J. |date=2014 |title=Decompression models: review, relevance and validation capabilities |journal=Undersea & Hyperbaric Medicine |volume=41 |issue=6 |pages=531–556 |issn=1066-2936 |pmid=25562945}}</ref><ref name=":2" /><ref>{{Cite journal |last1=Doolette |first1=David J. |last2=Mitchell |first2=Simon J. |date=2001-01-01 |title=The Physiological Kinetics of Nitrogen and the Prevention of Decompression Sickness |url=https://doi.org/10.2165/00003088-200140010-00001 |journal=Clinical Pharmacokinetics |language=en |volume=40 |issue=1 |pages=1–14 |doi=10.2165/00003088-200140010-00001 |pmid=11236806 |issn=1179-1926|url-access=subscription }}</ref>
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{{Reflist}}
{{Underwater diving|scidiv}}
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[[Category:Decompression theory]]
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