Failed remyelination of the non-human primate optic nerve leads to axon degeneration, retinal damages and visual dysfunction.

White matter disorders of the CNS such as MS, lead to failure of nerve conduction and long-lasting neurological disabilities affecting a variety of sensory and motor systems including vision. While most disease-modifying therapies target the immune and inflammatory response, the promotion of remyelination has become a new therapeutic avenue, to prevent neuronal degeneration and promote recovery. Most of these strategies are developed in short-lived rodent models of demyelination, which spontaneously repair and do not reflect the size, organization, and biology of the human CNS. Thus, well-defined non-human primate models are required to efficiently advance therapeutic approaches for patients. Here, we followed the consequence of long-term toxin-induced demyelination of the macaque optic nerve on remyelination and axon preservation, as well as its impact on visual functions. Findings from oculo-motor behavior, ophthalmic examination, electrophysiology, and retinal imaging indicate visual impairment involving the optic nerve and retina. These visual dysfunctions fully correlated at the anatomical level, with sustained optic nerve demyelination, axonal degeneration, and alterations of the inner retinal layers. This non-human primate model of chronic optic nerve demyelination associated with axonal degeneration and visual dysfunction, recapitulates several key features of MS lesions and should be instrumental in providing the missing link to translate emerging repair pro-myelinating/neuroprotective therapies to the clinic for myelin disorders such as MS.

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Selective intra-arterial brain cooling improves long-term outcomes in a non-human primate model of embolic stroke: Efficacy depending on reperfusion status

Journal of Cerebral Blood Flow & Metabolism ◽

10.1177/0271678x20903697 ◽

2020 ◽

Vol 40 (7) ◽

pp. 1415-1426 ◽

Cited By ~ 3

Author(s):

Di Wu ◽

Jian Chen ◽

Mohammed Hussain ◽

Longfei Wu ◽

Jingfei Shi ◽

...

Keyword(s):

Rhesus Macaques ◽

Motor Dysfunction ◽

Neurological Deficits ◽

Brain Cooling ◽

Long Term Outcomes ◽

Primate Model ◽

Tissue Plasminogen ◽

Human Primate ◽

Arterial Thrombolysis

Nearly all stroke neuroprotection modalities, including selective intra-arterial cooling (SI-AC), have failed to be translated from bench to bed side. Potentially overlooked reasons may be biological gaps, inadequate attention to reperfusion states and mismatched attention to neurological benefits. To advance stroke translation, we describe a novel thrombus-based stroke model in adult rhesus macaques. Intra-arterial thrombolysis with tissue plasminogen activator leads to three clinically relevant outcomes – complete, partial, and no recanalization based on digital subtraction angiography. We also find reperfusion as a prerequisite for SI-AC-induced benefits, in which models with complete or partial reperfusion exhibit significantly reduced infarct volumes, mitigated neurological deficits, improved upper limb motor dysfunction in both acute and chronic stages; however, no further neuroprotection is observed in those without reperfusion. In summary, we discover reperfusion as a crucial regulator of SI-AC-induced neuroprotection and provide insights of long-term functional benefits in behavior and imaging levels. Our findings could be important not only for the translational prerequisite and potential molecular targets, but also for this thrombus-thrombolysis model in monkeys as a powerful tool for further translational stroke studies.

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Serial MRI, functional recovery, and long-term infarct maturation in a non-human primate model of stroke

Brain Research Bulletin ◽

10.1016/s0361-9230(03)00214-4 ◽

2003 ◽

Vol 61 (6) ◽

pp. 577-585 ◽

Cited By ~ 22

Author(s):

J Marshall

Keyword(s):

Functional Recovery ◽

Primate Model ◽

Serial Mri ◽

Human Primate

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A non-human primate model of stroke reproducing endovascular thrombectomy and allowing long-term imaging and neurological read-outs

Journal of Cerebral Blood Flow & Metabolism ◽

10.1177/0271678x20921310 ◽

2020 ◽

pp. 0271678X2092131 ◽

Cited By ~ 1

Author(s):

Justine Debatisse ◽

Océane Wateau ◽

Tae-Hee Cho ◽

Nicolas Costes ◽

Inés Mérida ◽

...

Keyword(s):

Ischemia Reperfusion ◽

Fine Motor ◽

Area At Risk ◽

Primate Model ◽

Endovascular Thrombectomy ◽

Blood Brain Barrier Disruption ◽

Reperfusion Damage ◽

Brain Barrier Disruption ◽

Human Primate

Stroke is a devastating disease. Endovascular mechanical thrombectomy is dramatically changing the management of acute ischemic stroke, raising new challenges regarding brain outcome and opening up new avenues for brain protection. In this context, relevant experiment models are required for testing new therapies and addressing important questions about infarct progression despite successful recanalization, reversibility of ischemic lesions, blood–brain barrier disruption and reperfusion damage. Here, we developed a minimally invasive non-human primate model of cerebral ischemia ( Macaca fascicularis) based on an endovascular transient occlusion and recanalization of the middle cerebral artery (MCA). We evaluated per-occlusion and post-recanalization impairment on PET-MRI, in addition to acute and chronic neuro-functional assessment. Voxel-based analyses between per-occlusion PET-MRI and day-7 MRI showed two different patterns of lesion evolution: “symptomatic salvaged tissue” (SST) and “asymptomatic infarcted tissue” (AIT). Extended SST was present in all cases. AIT, remote from the area at risk, represented 45% of the final lesion. This model also expresses both worsening of fine motor skills and dysexecutive behavior over the chronic post-stroke period, a result in agreement with cortical-subcortical lesions. We thus fully characterized an original translational model of ischemia–reperfusion damage after stroke, with consistent ischemia time, and thrombus retrieval for effective recanalization.

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Gut microbiome and metabolome in a non-human primate model of chronic excessive alcohol drinking

Translational Psychiatry ◽

10.1038/s41398-021-01728-6 ◽

2021 ◽

Vol 11 (1) ◽

Author(s):

Daria Piacentino ◽

Silvia Grant-Beurmann ◽

Carlotta Vizioli ◽

Xiaobai Li ◽

Catherine F. Moore ◽

...

Keyword(s):

Amino Acids ◽

Alcohol Use ◽

Alcohol Drinking ◽

Gut Microbiome ◽

Alcohol Exposure ◽

Primate Model ◽

Fecal Microbiome ◽

Excessive Alcohol ◽

Human Primate

AbstractA relationship between the gut microbiome and alcohol use disorder has been suggested. Excessive alcohol use produces changes in the fecal microbiome and metabolome in both rodents and humans. Yet, these changes can be observed only in a subgroup of the studied populations, and reversal does not always occur after abstinence. We aimed to analyze fecal microbial composition and function in a translationally relevant baboon model of chronic heavy drinking that also meets binge criteria (drinking too much, too fast, and too often), i.e., alcohol ~1 g/kg and blood alcohol levels (BALs) ≥ 0.08 g/dL in a 2-hour period, daily, for years. We compared three groups of male baboons (Papio anubis): L = Long-term alcohol drinking group (12.1 years); S = Short-term alcohol drinking group (2.7 years); and C = Control group, drinking a non-alcoholic reinforcer (Tang®) (8.2 years). Fecal collection took place during 3 days of Drinking (D), followed by a short period (3 days) of Abstinence (A). Fecal microbial alpha- and beta-diversity were significantly lower in L vs. S and C (p’s < 0.05). Members of the commensal families Lachnospiraceae and Prevotellaceae showed a relative decrease, whereas the opportunistic pathogen Streptococcus genus showed a relative increase in L vs. S and C (p’s < 0.05). Microbiota-related metabolites of aromatic amino acids, tricarboxylic acid cycle, and pentose increased in L vs. S and C (FDR-corrected p < 0.01), with the latter two suggesting high energy metabolism and enhanced glycolysis in the gut lumen in response to alcohol. Consistent with the long-term alcohol exposure, mucosal damage and oxidative stress markers (N-acetylated amino acids, 2-hydroxybutyrate, and metabolites of the methionine cycle) increased in L vs. S and C (FDR-corrected p < 0.01). Overall, S showed few differences vs. C, possibly due to the long-term, chronic alcohol exposure needed to alter the normal gut microbiota. In the three groups, the fecal microbiome barely differed between conditions D and A, whereas the metabolome shifted in the transition from condition D to A. In conclusion, changes in the fecal microbiome and metabolome occur after significant long-term excessive drinking and are only partially affected by acute forced abstinence from alcohol. These results provide novel information on the relationship between the fecal microbiome and metabolome in a controlled experimental setting and using a unique non-human primate model of chronic excessive alcohol drinking.

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