Olney's lesions

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Olney's lesions, also known as NMDA receptor antagonist neurotoxicity (NAN), are a form of potential brain damage due to drugs that have been studied experimentally and have produced neuronal damage, yet are administered by doctors to humans in the settings of pharmacotherapy and of anesthesia. They are named after John Olney, who conducted a study in 1989 to investigate neurotoxicity caused by PCP and related drugs.[1] They are important for two reasons. Firstly, NMDA receptor antagonist are physician-prescribed drugs for therapeutic treatment of human diseases such as memantine for Alzheimer's disease and amantadine for Parkinson's disease, and also occur as street drugs that are taken recreationally. Secondly in the field of anesthesiology, the dissociative anesthesia of many general anesthetics is due to NMDA receptor antagonist properties. Because the neuronal vacuolation of Olney's lesions evolves into neuronal necrosis or death of neurons, it is important to determine whether Olney's lesions occur in humans, not only in experimental animals. The essential question is whether an NMDA receptor antagonist drug is to be considered a human neurotoxin or not. The patient safety implications for pharmacotherapy and for anesthesia would each be profound, if the answer is affirmative.

History[]

In 1989, Olney et al. discovered that neuronal vacuolation and other cytotoxic changes ("lesions") occurred in brains of rats administered NMDA antagonists, including PCP, MK-801 (dizocilpine) and ketamine.[2] Examination of neurons in the posterior cingulate and retrosplenial cortices by electron microscopy revealed apparent lytic breakdown of mitochondria in the large vacuoles which had become apparent 2 hours after administration of an NMDA antagonist. After administration of 1.0 (mg/kg sc) MK-801 to rats, these neurotoxic changes became more apparent until about 12 hours post-dose, but the morphology of most cells appeared normal by light microscope about 24 hours post-dose. With 10 (mg/kg sc) doses of MK-801, the vacuolation reaction was still visible by light microscope 48 hours post-dose. After repeated doses of the NMDA antagonists MK-801 and PCP, the vacuolation reaction appeared consistent with the reaction after a single dose, so there was no evidence of a cumulative neurotoxic effect or that the reaction proceeded to an irreversible stage with repeated doses. The lowest doses of ketamine and tiletamine that produced neurotoxic changes visible by light microscope 4 hours post dose were 40 (mg/kg sc) and 10 (mg/kg sc), respectively. The potency of the drugs in producing these neurotoxic changes corresponded with their potency as NMDA antagonists: i.e. MK-801 > PCP > tiletamine > ketamine.

Researcher conducted similar studies to look at the correlation between age and sex and the development of NMDA receptor antagonist neurotoxicity in test rats. Older rats experienced a much higher mortality rate after the development of NAN. Female rats were found, at all ages, to have a higher incidence of necrotic (dead) neurons as a result of NAN.[3]

Nitrous oxide, a common anesthetic for humans (especially in dentistry), has also been shown to cause vacuolization in rats' brains, but caused no irreversible lesions.[4]

Dextromethorphan, a common antitussive often found in cough medicines, has been shown to cause vacuolization in rats' brains when administered at doses of 75 mg/(kg ip).[5] However, oral administration of dextromethorphan hydrobromide (DXM HBr) to female rats in single doses as high as 120 mg/kg did not result in detectable neurotoxic changes at 4–6 hours or 24–26 hours post-dose (female rats are more sensitive to NMDA antagonist neurotoxicity).[6] The same researchers also found no evidence of neurotoxic changes in retrosplenial or cingulate cortices of male rats orally administered up to 400 mg/(kg day) DXM HBr or female rats orally administered 120 mg/(kg day) DXM HBr, both for 30 days. Carliss et al. (2007) also found that rats administered 9 mg/(kg day sc) (+)-MK-801 hydrogen maleate for 30 days did produce detectable vacuolation as expected. When 30 mg/(kg ip) dextrorphan was administered to male rats, neurotoxic changes were observed only 30 minutes post-dose.[7]

Even if the hypothesis of gross neural apoptosis proves to be false in humans, NMDA antagonists certainly have potential to permanently alter synaptic structure due to effects upon long term potentiation, a process in which NMDA receptors plays a crucial role. Perhaps, with repeated usage, this would manifest, due to tolerance, thus downregulation, of the NMDA receptor system. This could feasibly alter the function/relationship of various structures, specifically the ventral visual stream, perhaps a cause of the anecdotal reports of hallucinogen persisting perception disorder (HPPD) from such chronic users of novel psychoactive substances.[8][original research?]

In 1999 an autopsy study by Johannes Kornhuber of 8 patients who had received amantadine therapy looked at the selectively vulnerable brain regions where Olney's lesions occur, the cingulate and retrosplenial cortex, and found no evidence of Olney's lesions.[9]

In 2013 a study using magnetic resonance imaging showed brain lesions in ketamine addicts (using from 0.2g twice a week up to 1g daily for 0.5 up to 12 years) with severity depending on the duration of addiction and daily intake of ketamine. Cortical atrophy and holes in superficial white matter are seen early on. After 4 years of addiction lesions spread throughout the brain and damage is evident in the pons and other deeper brain structures.[10]

Prevention[]

In medical settings, NMDA receptor antagonists are used as anesthetics, so GABAA receptor positive allosteric modulators are used to effectively prevent any neurotoxicity caused by them.[11] Drugs that work to suppress NAN include anticholinergics,[12] benzodiazepines, barbiturates[13] and Alpha-adrenergic agonists, such as clonidine. Conversely, coadministration of NMDA-antagonists with alpha-2 adrenergic antagonists, like yohimbine, could theoretically potentiate NAN.

Controversy[]

In Karl L. R. Jansen's book, Ketamine: Dreams and Realities, unpublished studies are cited on monkey brains. The opinion that DXM caused Olney's Lesions therefore came under fire. Jansen writes:

injected the common squirrel monkey with Dizocilpine, or MK-801 and was unable to produce any vacuoles.[14]

The brain regions where Olney's lesions occur show hypermetabolism[15] [R]ats have rates of brain metabolism that are almost twice as high as those in humans to start with.[16] It is because of this higher basal rate of cerebral metabolism that lesions may appear in rodents but not in large, mature primate brains. Ketamine causes over-excitement and euphoria in rats at doses below those at which it activates shutdown systems.

Frank Sharp also works in this area. I discussed with Sharp how this issue stood in 1998. His view was that reversible toxic changes in the rat started to appear at 40mg/kg and reached a level at which no further changes occurred (a plateau) at 100mg/kg, when a little cell death could be seen - but matters would not progress beyond this point. Extensive attempts to produce toxic changes in monkeys had been a total failure at doses up to 10mg/kg i.m. These Gorilla studies are unpublished.

I sought the view of Olney's colleague, Dr Nuri Farber. The work of his team indicated that N-P receptors must be blocked for at least 2 hours to cause reversible changes, and at least 24 hours to produce some cell death, in rats. [...][H]e thought that the methods used in monkey studies so far were unsatisfactory, because the animals were probably too young. Only adult rats show the toxic changes. He was not prepared to accept a clean bill of health for the drug in primates until this work with elderly Gorillas had been done, and until the drug companies published their Gorilla studies to support their claims of harmlessness.

There is thus no published evidence at this time (January 2000) that ketamine can produce toxic cell changes in monkeys. The unpublished monkey data that we know about, that of Frank Sharp, actually shows that there is no damage at doses up to 10mg/kg.

— Karl Jansen, Ketamine: Dreams and Realities (2004)[17]

See also[]

References[]

  1. ^ Olney J, Labruyere J, Price M (1989). "Pathological changes induced in cerebrocortical neurons by phencyclidine and related drugs". Science. 244 (4910): 1360–2. doi:10.1126/science.2660263. PMID 2660263.
  2. ^ Olney JW, Labruyere J, Price MT (1989). "Pathological Changes Induced in Cerebrocortical Neurons by Phencyclidine and Related Drugs". Science. 244: 1360–1362. doi:10.1126/science.2660263. PMID 2660263.CS1 maint: multiple names: authors list (link)
  3. ^ Auer RN (1996). "Effect of age and sex on N-methyl-D-aspartate antagonist-induced neuronal necrosis in rats". Stroke. 27 (4): 743–746. doi:10.1161/01.str.27.4.743. PMID 8614941.
  4. ^ Jevtovic-Todorovic V, Beals J, Benshoff N, Olney J (2003). "Prolonged exposure to inhalational anesthetic nitrous oxide kills neurons in adult rat brain". Neuroscience. 122 (3): 609–16. doi:10.1016/j.neuroscience.2003.07.012. PMID 14622904.
  5. ^ Hashimoto, K; Tomitaka, S; Narita, N; Minabe, Y; Iyo, M; Fukui, S (1996). "Induction of heat shock protein Hsp70 in rat cortex following administration of dextromethorphan". Environmental Toxicology and Pharmacology. 1 (4): 235–239. doi:10.1016/1382-6689(96)00016-6. PMID 21781688.
  6. ^ Carliss RD, Radovsky A, Chengelis CP, O'neill TP, Shuey DL (2007). "Oral administration of dextromethorphan does not produce neuronal vacuolation in the rat brain". NeuroToxicology. 28 (4): 813–8. doi:10.1016/j.neuro.2007.03.009. PMID 17573115.
  7. ^ Ortiz GG, Guerrero JM, Reiter RJ, Poeggeler BH, Bitzer-Quintero OK, Feria-Velasco A (1999). "Neurotoxicity of dextrorphan". Arch Med Res. 30: 125–127. doi:10.1016/s0188-0128(98)00020-7. PMID 10372446.CS1 maint: multiple names: authors list (link)
  8. ^ Orsolini L, Papanti GD, De Berardis D, Guirguis A, Corkery JM, Schifano F (2017). "The "Endless Trip" among the NPS Users: Psychopathology and Psychopharmacology in the Hallucinogen-Persisting Perception Disorder. A Systematic Review". Frontiers in Psychiatry. 8: 1–10. doi:10.3389/fpsyt.2017.00240. PMC 5701998. PMID 29209235.
  9. ^ Kornhuber J, Jellinger K, Wiltfang J, Leblhuber F, Riederer P (1999). "The N-methyl-D-aspartate receptor channel blocker amantadine does not cause histopathological alterations in human brain tissue". Acta Neuropathologica. 98: 85–90. doi:10.1007/s004010051054. PMID 10412804.
  10. ^ Wang C, Zheng D, Xu J, Lam W, Yew DT (2013). "Brain damages in ketamine addicts as revealed by magnetic resonance imaging". Frontiers in Neuroanatomy. 7 (23). doi:10.3389/fnana.2013.00023. PMC 3713393. PMID 23882190.
  11. ^ Nakao S, Nagata A, Masuzawa M, Miyamoto E, Yamada M, Nishizawa N, Shingu K (2003). "[NMDA receptor antagonist neurotoxicity and psychotomimetic activity]". Masui. 52 (6): 594–602. PMID 12854473.
  12. ^ [D.Wozniak - NMDA Antagonist Neurotoxicity: Mechanism and Prevention]
  13. ^ Olney J, Labruyere J, Wang G, Wozniak D, Price M, Sesma M (1991). "NMDA antagonist neurotoxicity: mechanism and prevention". Science. 254 (5037): 1515–8. doi:10.1126/science.1835799. PMID 1835799.
  14. ^ Auer RN, Coupland SG, Jason GW, Archer DP, Payne J, Belzberg AJ, Ohtaki M, Tranmer BI (1996). "Postischemic therapy with MK-801 (dizocilpine) in a primate model of transient focal brain ischemia". Molecular and Chemical Neuropathology. 29 (2–3): 193–210. doi:10.1007/BF02815002. PMID 8971696.
  15. ^ Kurumaji A, McCulloch J (1989). "Effects of MK-801 upon local cerebral glucose utilisation in conscious rats and in rats anaesthetised with halothane". Journal of Cerebral Blood Flow and Metabolism. 9: 786–794. doi:10.1038/jcbfm.1989.112. PMID 2684992.
  16. ^ Blin J, Ray CA, Chase TN, Piercey MF (1991). "Regional cerebral glucose metabolism compared in rodents and humans". Brain Research. 568: 215–222. doi:10.1016/0006-8993(91)91400-u. PMID 1814569.
  17. ^ Jansen, Karl. Ketamine: Dreams and Realities. MAPS, 2004. ISBN 0-9660019-7-4

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