Sustained cell body reactivity and loss of NeuN in a subset of axotomized bulbospinal neurons after a chronic high cervical spinal cord injury.

Following central nervous system lesion, the ability of injured axons to regrowth may depend on the level and duration of the injured cell body response (CBR). Therefore, to investigate whether axotomized brainstem neurons maintain a durable growth-competent state after spinal cord injury, we studied the effect of a chronic C2 hemisection in rats on the expression of various CBR markers involved in axon regeneration, such as c-Jun, ATF-3, HSP27, NO synthase (NOS), and also of the neural mature phenotype marker NeuN, in the bulbospinal respiratory neurons as compared to the gigantocellularis nucleus. Both at 7 and 30 days post-lesion (DPL), c-Jun and HSP27 were present in, respectively, ~60 and ~20% of the axotomized respiratory neurons, whereas the apoptotic factor caspase 3 was not detected in these cells. NOS appeared belatedly, and it was detected in ~20% of the axotomized respiratory neurons at 30DPL. At 30DPL, these different CBR markers were strongly colocalized in a sub-population of axotomized respiratory neurons and also in a sub-population of injured neurons within the gigantocellularis nucleus. Such CBR was also accompanied by a sustained alteration of the neural mature phenotype, as indicated by a loss of NeuN immunoreactivity selectively in HSP27+ bulbospinal neurons at 7DPL and 30DPL. Altogether, this study shows that a subset of axotomized medullary respiratory neurons remains in a growth-competent state after a chronic injury, suggesting that they may play a preferential role in long-lasting respiratory neuroplasticity processes.

Near-infrared light is neuroprotective in a monkey model of Parkinson disease.

OBJECTIVE: To examine whether near-infrared light (NIr) treatment reduces clinical signs and/or offers neuroprotection in a subacute 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) monkey model of Parkinson disease. METHODS: We implanted an optical fiber device that delivered NIr (670 nm) to the midbrain of macaque monkeys, close to the substantia nigra of both sides. MPTP injections (1.5-2.1mg/kg) were made over a 5- to 7-day period, during which time the NIr device was turned on. This was then followed by a 3-week survival period. Monkeys were evaluated clinically (eg, posture, bradykinesia) and behaviorally (open field test), and their brains were processed for immunohistochemistry and stereology. RESULTS: All monkeys in the MPTP group developed severe clinical and behavioral impairment (mean clinical scores = 21-34; n = 11). By contrast, the MPTP-NIr group developed much less clinical and behavioral impairment (n = 9); some monkeys developed moderate clinical signs (mean scores = 11-15; n = 3), whereas the majority--quite remarkably--developed few clinical signs (mean scores = 1-6; n = 6). The monkeys that developed moderate clinical signs had hematic fluid in their optical fibers at postmortem, presumably limiting NIr exposure and overall clinical improvement. NIr was not toxic to brain tissue and offered neuroprotection to dopaminergic cells and their terminations against MPTP insult, particularly in animals that developed few clinical signs. INTERPRETATION: Our findings indicate NIr to be an effective therapeutic agent in a primate model of the disease and create the template for translation into clinical trials.

No evidence for toxicity after long-term photobiomodulation in normal non-human primates.

In this study, we explored the effects of a longer term application, up to 12 weeks, of photobiomodulation in normal, naïve macaque monkeys. Monkeys (n = 5) were implanted intracranially with an optical fibre device delivering photobiomodulation (red light, 670 nm) to a midline midbrain region. Animals were then aldehyde-fixed and their brains were processed for immunohistochemistry. In general, our results showed that longer term intracranial application of photobiomodulation had no adverse effects on the surrounding brain parenchyma or on the nearby dopaminergic cell system. We found no evidence for photobiomodulation generating an inflammatory glial response or neuronal degeneration near the implant site; further, photobiomodulation did not induce an abnormal activation or mitochondrial stress in nearby cells, nor did it cause an abnormal arrangement of the surrounding vasculature (endothelial basement membrane). Finally, because of our interest in Parkinson's disease, we noted that photobiomodulation had no impact on the number of midbrain dopaminergic cells and the density of their terminations in the striatum. In summary, we found no histological basis for any major biosafety concerns associated with photobiomodulation delivered by our intracranial approach and our findings set a key template for progress onto clinical trial on patients with Parkinson's disease.

Near-infrared light treatment reduces astrogliosis in MPTP-treated monkeys.

We have reported previously that intracranial application of near-infrared light (NIr) reduces clinical signs and offers neuroprotection in a subacute MPTP (1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine) monkey model of Parkinson's disease. In this study, we explored whether NIr reduces the gliosis in this animal model. Sections of midbrain (containing the substantia nigra pars compacta; SNc) and striatum were processed for glial fibrillary acidic protein (to label astrocytes; GFAP) and ionised calcium-binding adaptor molecule 1 (to label microglia; IBA1) immunohistochemistry. Cell counts were undertaken using stereology, and cell body sizes were measured using ImageJ. Our results showed that NIr treatment reduced dramatically (~75 %) MPTP-induced astrogliosis in both the SNc and striatum. Among microglia, however, NIr had a more limited impact in both nuclei; although there was a reduction in overall cell size, there were no changes in the number of microglia in the MPTP-treated monkeys after NIr treatment. In summary, we showed that NIr treatment influenced the glial response, particularly that of the astrocytes, in our monkey MPTP model of Parkinson's disease. Our findings raise the possibility of glial cells as a future therapeutic target using NIr.

Long-term reorganization of respiratory pathways after partial cervical spinal cord injury.

High cervical spinal cord injury (SCI) interrupts bulbospinal respiratory pathways innervating phrenic motoneurons, and induces an inactivation of phrenic nerves (PN) and diaphragm. We have previously shown that the ipsilateral (ipsi) PN was inactivated following a lateral C2 SCI, but was spontaneously partially reactivated 7 days post-SCI. This phrenic reactivation depended on contralateral (contra) descending pathways, located laterally, that cross the spinal midline. We analysed here whether long-term post-lesional changes may occur in the respiratory network. We showed that ipsi PN reactivation was greater at 3 months compared with 7 days post-SCI, and that it was enhanced after acute contra phrenicotomy (Phx), which also induced a substantial reactivation of the ipsi diaphragm (not detected at 7 days post-SCI). At 3 months post-SCI (compared with 7 days post-SCI), ipsi PN activity was only moderately affected by ipsi Phx or by gallamine treatment, a nicotinic neuromuscular blocking agent, indicating that it was less dependent on ipsi sensory phrenic afferents. After an additional acute contra SCI (C1) performed laterally, ipsi PN activity was abolished in rats 7 days post-SCI, but persisted in rats 3 months post-SCI. This activity thus depended on new functional descending pathways located medially rather than laterally. These may not involve newly recruited neurons as retrograde labelling showed that ipsi phrenic motoneurons were innervated by a similar number of medullary respiratory neurons after a short and long post-lesional time. These results show that after a long post-lesional time, phrenic reactivation is reinforced by an anatomo-functional reorganization of spinal respiratory pathways.

Effects of a higher dose of near-infrared light on clinical signs and neuroprotection in a monkey model of Parkinson's disease.

We have reported previously that intracranial application of near-infrared light (NIr) - when delivered at the lower doses of 25J and 35J - reduces clinical signs and offers neuroprotection in a subacute MPTP (1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine) monkey model of Parkinson's disease. In this study, we explored whether a higher NIr dose (125J) generated beneficial effects in the same MPTP monkey model (n=15). We implanted an NIr (670nm) optical fibre device within a midline region of the midbrain in macaque monkeys, close to the substantia nigra of both sides. MPTP injections (1.8-2.1mg/kg) were made over a five day period, during which time the NIr device was turned on and left on continuously throughout the ensuing three week survival period. Monkeys were evaluated clinically and their brains processed for immunohistochemistry and stereology. Our results showed that the higher NIr dose did not have any toxic impact on cells at the midbrain implant site. Further, this NIr dose resulted in a higher number of nigral tyrosine hydroxylase immunoreactive cells when compared to the MPTP group. However, the higher NIr dose monkeys showed little evidence for an increase in mean clinical score, number of nigral Nissl-stained cells and density of striatal tyrosine hydroxylase terminations. In summary, the higher NIr dose of 125J was not as beneficial to MPTP-treated monkeys as compared to the lower doses of 25J and 35J, boding well for strategies of NIr dose delivery and device energy consumption in a future clinical trial.

Intracranial application of near-infrared light in a hemi-parkinsonian rat model: the impact on behavior and cell survival.

OBJECT The authors of this study used a newly developed intracranial optical fiber device to deliver near-infrared light (NIr) to the midbrain of 6-hydroxydopamine (6-OHDA)-lesioned rats, a model of Parkinson's disease. The authors explored whether NIr had any impact on apomorphine-induced turning behavior and whether it was neuroprotective. METHODS Two NIr powers (333 nW and 0.16 mW), modes of delivery (pulse and continuous), and total doses (634 mJ and 304 J) were tested, together with the feasibility of a midbrain implant site, one considered for later use in primates. Following a striatal 6-OHDA injection, the NIr optical fiber device was implanted surgically into the midline midbrain area of Wistar rats. Animals were tested for apomorphine-induced rotations, and then, 23 days later, their brains were aldehyde fixed for routine immunohistochemical analysis. RESULTS The results showed that there was no evidence of tissue toxicity by NIr in the midbrain. After 6-OHDA lesion, regardless of mode of delivery or total dose, NIr reduced apomorphine-induced rotations at the stronger, but not at the weaker, power. The authors found that neuroprotection, as assessed by tyrosine hydroxylase expression in midbrain dopaminergic cells, could account for some, but not all, of the observed behavioral improvements; the groups that were associated with fewer rotations did not all necessarily have a greater number of surviving cells. There may have been other "symptomatic" elements contributing to behavioral improvements in these rats. CONCLUSIONS In summary, when delivered at the appropriate power, delivery mode, and dosage, NIr treatment provided both improved behavior and neuroprotection in 6-OHDA-lesioned rats.

810nm near-infrared light offers neuroprotection and improves locomotor activity in MPTP-treated mice.

We explored whether 810nm near-infrared light (NIr) offered neuroprotection and/or improvement in locomotor activity in an acute 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP)-treated mouse model of Parkinson's disease. Mice received MPTP and 810nm NIr treatments, or not, and were tested for locomotive activity in an open-field test. Thereafter, brains were aldehyde-fixed and processed for tyrosine hydroxylase immunohistochemistry. Our results showed that MPTP-treated mice that were irradiated with 810nm NIr had both greater locomotor activity (∼40%) and number of dopaminergic cells (∼20%) than those that were not. In summary, 810nm (as with 670nm) NIr offered neuroprotection and improved locomotor activity in MPTP-treated mice.

Extensive respiratory plasticity after cervical spinal cord injury in rats: axonal sprouting and rerouting of ventrolateral bulbospinal pathways.

Spinal cord injury (SCI) causes an interruption of descending motor and autonomic nervous tracts. However, a partial injury, and particularly a unilateral section, is generally followed by spontaneous locomotor and respiratory recovery. Although locomotor functional recovery has been correlated to spontaneous anatomical plasticity of the corticospinal tract, the remodeling of the bulbospinal tract that sustains respiratory improvement is unknown and has therefore been investigated here after chronic lateral cervical injury in rats (90 days post-lesion by comparison to 7 days post-lesion). We show that chronic lateral C2 SCI leads both to a decreased thickness of the ipsilateral ventrolateral funiculus at sus and sub-lesional levels and to an opposite effect on the contralateral side. At C1 level, the number of ventrolateral bulbospinal fibers, stained with anterograde tracer was reduced within the ipsilateral ventrolateral funiculi while collateral arborization toward the gray matter and growth associated protein-43 levels was increased. At C2 lesional level, fibers rerouting toward the gray matter were also identified for 5% of the axotomized axon terminals. Despite these chronic sprouting processes respiratory bulbospinal projections to ipsilateral phrenic nucleus remained poor (less than 10% compared to non-injured conditions). Retrograde labeling of projections onto the phrenic nucleus revealed, after chronic injury, an increased recruitment of C1 propriospinal interneurons which moreover received more contacts from bulbospinal collaterals. This chronic remodeling was correlated with chronic diaphragm recovery under conditions of respiratory stress. Thus, despite extensive axonal loss and absence of direct phrenic reinnervation by bulbospinal respiratory neurons, sprouting processes toward cervical propriospinal neurons may contribute to the observed partial respiratory recovery.

Distinct expression of c-Jun and HSP27 in axotomized and spared bulbospinal neurons after cervical spinal cord injury.

In several populations of adult central nervous system neurons, axon damage can lead to an up-regulation of some transcription factors among which is c-Jun, known to be a key regulator of neuron cell body response to injury and of its intrinsic potential for axon regeneration. Thus, cervical spinal hemisection leads to c-Jun up-regulation in bulbospinal and rubrospinal axotomized neurons. The aims of the present study were to specify, after a unilateral cervical spinal cord injury, the expression of another marker of the neuronal stress response, heat shock protein 27 (HSP27) in axotomized neurons of the medulla (labeled by fluorogold retrograde tracer), and to compare it to that of c-Jun. In the medulla of injured rats, HSP27 and phospho-HSP27 were expressed in sub-populations of axotomized neurons, principally in the rostral ventral respiratory group (rVRG) (20%), the dorsal part of the gigantocellularis (Gi) (50%), and vestibular nucleus, but seldom in the ventral Gi and raphe nucleus, indicating a heterogeneous post-lesion cell body response between these different neuron populations. By contrast, phospho-c-Jun was up-regulated in axotomized neurons in all nuclei containing bulbospinal neurons, including the rVRG and Gi. In these areas, phospho-c-Jun was also up-regulated in uninjured bulbospinal neurons which project caudal to the spinal cord injury (labeled by fluorogold retrograde tracer). In contrast to phospho-c-Jun, HSP27 immunoreactivity was generally not present in neurons with spared axons. Our results show that various bulbospinal neuron populations react differentially to the injury and that spinal cord injury affects also bulbospinal neurons that are spared by the injury. However, the molecular cell body response of spared neurons is distinct from that of axotomized neurons since they can up-regulate c-Jun but not HSP27.

Effect of cervical spinal cord hemisection on the expression of axon growth markers.

To evaluate the plasticity processes occurring in the spared and injured tissue after partial spinal cord injury, we have compared the level of axon growth markers after a C2 cervical hemisection in rats between the contralateral (spared) and ipsilateral (injured) cervical cord using western blotting and immunohistochemical techniques. In the ipsilateral spinal cord 7 days after injury, although GAP-43 levels were increased in the ventral horn caudal to the injury, they were globally decreased in the whole structure (C1-C6). By contrast, in the contralateral intact side 7 days and 1 month after injury, we have found an increase of GAP-43 and betaIII tubulin levels, suggesting that processes of axonal sprouting may occur in the spinal region contralateral to the injury. This increase of GAP-43 in the contralateral spinal cord after cervical hemisection may account, at least partially, to the spontaneous ipsilateral recovery observed after a cervical hemisection.

Topology of Schwann cells and sympathetic innervation along preglomerular vessels: a confocal microscopic study in protein S100B/EGFP transgenic mice.

Schwann cells (Sc), associated axons, and nearby vascular endothelium constitute a functional trilogy of major importance during the development and regrowth of peripheral vascular nerves. The goal of the present study is to provide a technique of triple fluorescence confocal imaging of these cell types along renal preglomerular vessels. We took advantage of a protein S100B/EGFP transgenic mouse to visualize Sc. The endothelium was labeled with an intravenous injection of fluorescently tagged lectin, and after tissue processing, adrenergic nerves were revealed with an antibody against the marker protein synaptophysin. As a validation step, we found that EGFP-positive perivascular cells with prominent cell bodies and extensive, multidirectional cell processes were protein S100B positive. They were identified as Sc and indirectly assumed to be unmyelinated Sc. By contrast, we found strong EGFP expression in proximal epithelial cells and in the epithelium lining thin limbs of Henle. This epithelial fluorescence was not associated with immunoreactive protein S100B and thus corresponded to ectopic EGFP expressions in this mouse strain. Sc were organized in bundles or as a meshwork surrounding the preglomerular vasculature from arcuate arteries to afferent arterioles. No Sc were detected in the medulla. Although most Sc were closely apposed to adrenergic varicosities, many varicosities were not associated with detectable Sc processes. The present technique, and the capacity of confocal microscopy to yield three-dimensional imaging, allow the study of the microtopology of Sc and related sympathetic axons in the renal perivascular interstitium.