Although manganese (Mn) can enhance brain tissues for improving magnetic resonance imaging (MRI) assessments, the underlying neural mechanisms of Mn detection remain unclear. In this study, we used Mn-enhanced MRI to test the hypothesis that different Mn entry routes and spatiotemporal Mn distributions can reflect different mechanisms of neural circuitry and neurodegeneration in normal and injured brains. Upon systemic administration, exogenous Mn exhibited varying transport rates and continuous redistribution across healthy rodent brain nuclei over a 2-week timeframe, whereas in rodents following photothrombotic cortical injury, transient middle cerebral artery occlusion, or neonatal hypoxic-ischemic brain injury, Mn preferentially accumulated in perilesional tissues expressing gliosis or oxidative stress within days. Intravitreal Mn administration to healthy rodents not only allowed tracing of primary visual pathways, but also enhanced the hippocampus and medial amygdala within a day, whereas partial transection of the optic nerve led to MRI detection of degrading anterograde Mn transport at the primary injury site and the perilesional tissues secondarily over 6 weeks. Taken together, our results indicate the different Mn transport dynamics across widespread projections in normal and diseased brains. Particularly, perilesional brain tissues may attract abnormal Mn accumulation and gradually reduce anterograde Mn transport via specific Mn entry routes.
Manganese (Mn) has been increasingly used as a positive T1-weighted contrast agent in magnetic resonance imaging (MRI) to study the structures and functions of the central nervous system in vivo. Due to the paramagnetic nature of Mn ions and the similar biochemical properties as calcium, Mn has been introduced for neuronal tract tracing, enhancement of neuroarchitecture and functional brain mapping1,2,3,4. Mn is also an essential constituent of two important metalloproteins involved in the pathophysiology of the brain. Mn binds to the mitochondrial Mn superoxide dismutase enzyme, which acts against cellular oxidative stress. It can also bind to glutamine synthetase, which is a glial specific enzyme for regulating extracellular glutamate and reducing glutamate excitotoxicity5,6,7,8,9.
Because of the complex properties of Mn, it remains unclear how Mn is transported dynamically in normal and injured brains, and how Mn accumulates and enhances different brain tissues for MRI detection. A better understanding of the sensitivity and specificity of Mn detection under different experimental conditions can help design optimal tests targeting the normal physiology and pathophysiology of the brain. In this study, we hypothesize that Mn-enhanced MRI can indicate different mechanisms of brain circuitry and neurodegeneration by examining different Mn entry routes and the spatiotemporal Mn distributions across widespread projections in normal and injured brain tissues. We used Mn-enhanced MRI to detect Mn distribution in the normal brains of different rodent species upon systemic or intravitreal Mn injection. In addition, we evaluated the spatiotemporal profiles of Mn enhancement in 3 different types of cerebral ischemic injuries induced by photothrombotic cortical injury (PCI), transient middle cerebral artery occlusion (tMCAO), and neonatal hypoxic-ischemic (HI) injury, and confirmed the alterations in biochemical processes that occurred in the enhanced perilesional tissues using immunohistochemical markers. Lastly, we inspected how partial optic nerve lesions affect primarily and secondarily the anterograde transport of Mn in the injured and uninjured, perilesional visual pathways over time. Our results indicate that Mn-enhanced MRI can be an important in vivo technique for dynamically assessing the neural circuitry and degenerative events in localized regions across the brain. In particular, it may help characterize the pathophysiological properties of perilesional brain tissues via different routes of Mn entry.
Exogenous Mn enhanced individual brain nuclei at varying rates and peak times after systemic administration to healthy rodents
Upon systemic Mn administration to healthy adult rats (experiment 1), longitudinal T1-weighted MRI showed increased signal intensities to varying extents in both cortical and subcortical brain nuclei at Day 1 and Day 5 compared to pre-injection and Day 12 (Fig. 1). Mn enhancement was the most intense at Day 1 in the anterior pituitary gland, periventricular nuclei, hippocampus, frontal cortex, hypothalamus, superior colliculus and occipital cortex. In the central amygdaloid nucleus, globus pallidus, ventral pallidum, caudate putamen and thalamus, Mn enhancement was apparently more intense at Day 5 than the other 3 time points measured.
Mn preferentially accumulated in perilesional tissues expressing gliosis or oxidative stress after photothrombotic cortical injury, transient middle cerebral artery occlusion, and neonatal hypoxic-ischemic brain injury
Upon systemic Mn administration at 2 days after PCI to the right motor cortex (experiment 2a), T1-weighted hyperintensity was observed in the perilesional rim surrounding the hypointense ischemic core in all animals at Day 3 and Day 7 (Fig. 2a and d). T1-weighted hyperintensity was also observed in the ipsilesional cortex remote to the ischemic core, and occasionally in the subcortical regions after systemic Mn administration to the PCI model (Fig. 2b). When no exogenous Mn was applied to the PCI model, T1-weighted signal enhancement was not apparent in the perilesional rim at 3 days after PCI. However, mild T1-weighted signal enhancement was observed in the perilesional rim at 7 days after PCI without systemic Mn administration (Fig. 2a and d). The T1-weighted signal enhancement at 7 days after PCI colocalized with glial fibrillary acid protein, Mn superoxide dismutase or glutamine synthetase immunoreactivities in the perilesional rim both with and without systemic Mn administration (Fig. 3).
Upon systemic Mn administration at 2 days after unilateral tMCAO (experiment 2b), a significant increase in T1-weighted signal intensity was observed in the perilesional rim compared to the ischemic core at Day 3 (paired t-test, p < 0.05) similar to the PCI model, while the Mn enhancement at 10 days after tMCAO was in good colocalization with glial fibrillary acid protein, Mn superoxide dismutase and glutamine synthetase immunostainings (Fig. 4).
Upon systemic Mn administration at 5 months after unilateral neonatal HI brain injury (experiment 2c), T1-weighted hyperintensity was observed in the perilesional regions of the ipsilesional hemisphere, especially in the remaining thalamus and cingulate cortex (Fig. 5a). Neither the contralesional hemisphere nor the age-matched normal control brain exhibited the same extent of Mn contrast enhancement in the homologous areas. The Mn-induced signal changes in the perilesional areas were quantified and validated statistically between the HI-injured group and age-matched normal control group (Fig. 5b). Furthermore, the Mn enhancement in the perilesional tissues colocalized with immunohistochemical expression of glial fibrillary acid protein staining (Fig. 5c).
Intravitreal Mn administration to healthy rodents enhanced both visual and non-visual pathways across species
At 1 day after intravitreal Mn injection to the right eyes of healthy adult rats, gerbils and mice (experiment 3), Mn enhancement was observed along the primary visual pathway in the right retina, right lens and right optic nerve, and in the left optic tract, left lateral geniculate nucleus and the superficial layers of the left superior colliculus in all species (closed solid arrows in Fig. 6a). Mild Mn enhancement could also be found in the ipsilateral right superior colliculus (dashed open arrows in Fig. 6a) in gerbils but not rats or mice. In addition, Mn enhancement was observed in the non-visual brain nuclei of the left hemisphere including the posterior medial amygdala (dashed arrows in Fig. 6a) and hippocampus (open solid arrows in Fig. 6a) across species. Quantitative analyses in Fig. 6b verified the significant T1-weighted signal increases in both visual and non-visual brain nuclei of the contralateral hemisphere after monocular intravitreal Mn injection across species.
Partial optic nerve transection led to gradual loss of anterograde Mn transport along perilesional visual pathway
In rats that had received partial transection of the right intraorbital optic nerve for 6 weeks and intravitreal Mn injection into both eyes for 1 day (experiment 4), the right vitreous and retina showed significantly higher T1-weighted signal intensities than the left eye. Distal to the transection site, the right optic nerve and the left lateral geniculate nucleus showed significantly lower T1-weighted signal intensities than the contralateral hemispheres (Fig. 7a and d). In the midbrain, localized T1-weighted hypointensity was found in the lateral half of the left superior colliculus (open arrows in Fig. 7b) at 1 week and 6 weeks after partial transection to the superior region of the right optic nerve. The lateral half of the left superior colliculus had 28 ± 5% and 27 ± 3% lower T1-weighted signal intensities than the right superior colliculus at Week 1 and Week 6 respectively. The medial half of the left superior colliculus also had lower T1-weighted signal intensities than the right superior colliculus but to a smaller extent by 11 ± 6% and 16 ± 5% at Week 1 and Week 6 respectively (Fig. 7e). The T1-weighted signal intensity of the left medial superior colliculus was significantly higher at Week 1 than Week 6, and was significantly higher than that of the left lateral superior colliculus at both time points. No statistical significance was found when comparing between the lateral and medial halves of the right superior colliculus at the same time points, or between Week 1 and Week 6 in the left lateral superior colliculus or the right superior colliculus (Fig. 7e).
Although previous Mn-enhanced MRI studies in healthy rodents showed that systemic Mn administration can enhance most brain tissues within a day10,11, the specific cellular fate of Mn across the brain following overexposure remain incompletely understood11,12,13. In experiment 1, the varying rates and peak times of Mn enhancement in individual brain nuclei may be explained partly by the differences in baseline metalloprotein levels, brain connectivity and brain activities. After systemic administration, Mn can transport from the plasma into the brain parenchyma across the cerebrospinal fluid and cerebral capillaries14. Mn can also diffuse into the brain and enter excitable cells via voltage-gated calcium channels10,11. The brain structures in Fig. 1b with maximal Mn enhancement at Day 1 are known to possess high contents of unsaturated glutamine synthetase14,15 as well as high baseline glutaminergic activities16, both of which may take up the diffused Mn leading to T1-weighted hyperintensity. In contrast, in brain regions with low glutamine synthetase contents such as the striatum, T1-weighted signal enhancement appeared less pronounced at Day 1. At Day 5, Mn enhancement persisted in the brain structures in Fig. 1b, indicative of the slow efflux of Mn within the first week of systemic Mn administration17. On the other hand, exogenous Mn appeared to accumulate further at Day 5 in the central amygdaloid nucleus, globus pallidus, ventral pallidum, caudate putamen and thalamus. While there are many parts of the neocortex innervating the caudate putamen, the caudate putamen provides efferent fibers to ventral pallidum and globus pallidus, which may allow continual Mn transport between subcortical structures. The amygdaloid complex and thalamus are also reciprocally connected with multiple cortical sensory systems14. Our results in Fig. 1c suggest that Mn is redistributed through axonal transport in the late phase of systemic Mn administration. Taken together, the Mn-enhanced MRI observations here extend beyond previous findings focusing on the early phase of systemic Mn administration, and demonstrated the intrinsic properties of systemic Mn uptake and continuous redistribution across normal neuronal pathways before global clearance from the brain within a 2-week timeframe. This may provide a basis for biophysical modeling and prediction of Mn transport dynamics across the brain. It has been shown that Mn accumulation in mitochondria may inhibit calcium efflux in the brain18,19. However, it remains unclear whether there is any distribution correlation between Mn and calcium, and how their distributions are influenced by each other20,21,22,23. Future directions are envisioned that examine the overall distributions of both intracellular and extracellular metal ions upon administration of other metal ions.
After acute stroke, the rescued penumbra may be affected by selective neuronal loss and glial activation, which may hinder functional recovery24. To date, limited in vivo techniques are available to delineate the penumbra regions accurately for better monitoring and targeted intervention of post-stroke events. In experiment 2, when Mn superoxide dismutase activity transiently peaked in the peri-infarct areas at about 7 days after PCI25, mild T1-weighted signal enhancement was also observed at the perilesional rim even without systemic Mn administration, suggestive of delayed upregulation of endogenous Mn26,27. In contrast, after exogenous Mn injection to PCI, tMCAO and HI-injured models, we demonstrated a stronger and earlier detection of Mn enhancement in the perilesional tissues than endogenous Mn upregulation. While the origins of Mn enhancement in neurodegeneration have been debatable in the past years28,29,30,31, our experiments indicated the good colocalization of Mn enhancement patterns with glial fibrillary acid protein, Mn superoxide dismutase or glutamine synthetase stains consistently across different brain ischemia models. In the perilesional tissues, astroglial cells that are highly immunostained for glial fibrillary acid protein would secrete reactive oxygen species, resulting in an upregulation of Mn superoxide dismutase and glutamine synthetase which are Mn dependent enzymes32. In addition, glutamate could be released in the peri-infarct areas by increasing the activation of neuronal glutamate receptors, which in turn increased membrane permeability to calcium in astrocytes7,33,34. As a calcium analog35, it is possible that exogenous Mn may enhance MRI detection of gliosis and oxidative stress. In summary, our experimental findings support the hypothesis that Mn is continuously redistributed differently between normal and injured brains after systemic administration to healthy rodents and brain ischemia rodent models. Our Mn-enhanced MRI observations may help better understand the mechanisms related to the uptake, distribution and action of Mn under different types of brain ischemia. Given that Mn superoxide dismutase and glutamine synthetase activities may increase upon Mn administration to normal and ischemic animals36,37,38, whereby Mn may trigger the scavenging of superoxide and hydroxyl radicals36, it is also possible that systemic Mn administration at low doses could exert antioxidative effects to some extents and preserve brain tissues at remote sites from delayed secondary damage (see Supplementary Figs S1 and S2). Such combined Mn administration and MRI detection approaches may be useful for investigation of post-injury cellular events and functional reorganization.
Apart from systemic Mn administration, local Mn administration may provide an excellent imaging model system for understanding the mechanisms of fiber formation, degeneration and plasticity in specific systems of the brain35,39,40,41,42,43,44. Within the visual system, there is increasing evidence that suggest the role of the retinal ganglion cells for both visual and non-visual functions45. However, the sensitivity of Mn-enhanced MRI for tracing retinal projections to different brain nuclei has not yet been fully explored. It is either incompletely understood how Mn enters, transports and accumulates within the brain circuitry after local administration35,46,47. Upon monocular intravitreal Mn injection to rats, gerbils, and mice, we demonstrated in experiment 3 the feasibility of submillimeter resolution Mn-enhanced MRI for in vivo examination of the retinal projections to both visual and non-visual brain nuclei. Apart from Mn enhancement of the primary visual centers along the retinocollicular and retinogeniculate pathways, a consistent unilateral enhancement in the posterior medial amygdala and hippocampus was observed in the contralateral hemisphere across rodent species. This may be partly ascribed to the direct communication between melanopsin-expressing retinal ganglion cells and the medial amygdala45,48,49,50, the existence of the retinolimbic pathway between the retina and the hippocampus51, or other non-specific enhancements52. Understanding the retinal inputs to both visual and non-visual brain nuclei simultaneously may help depict the underlying neural circuit in normal physiology and in diseases that involve widespread brain impairments such as glaucoma53,54,55. Future Mn-enhanced MRI studies are envisioned that measure the widespread retinal projections in normal development, disease, plasticity and therapy in longitudinal studies.
In addition to local Mn tracing of normal neural pathways, we extended beyond our previous cross-sectional 3D Mn-enhanced MRI study40, and evaluated longitudinally the primary and secondary degeneration along the retinocollicular projections after partial optic nerve injury in experiment 4. Previous histological work showed that partial transection of the intraorbital optic nerve is accompanied by the spreading damage of secondary degeneration, which results in further loss of neurons and function away from the initial injury56,57. After partial transection of the right superior optic nerve, the consistent T1-weighted hypointensity in the left lateral superior colliculus than the right superior colliculus at Week 1 and Week 6 reflected the primary loss of topological connections and Mn transport in consistency with our previous study assessed at Week 1 only40. The slightly weaker T1-weighted enhancement in the left medial superior colliculus at Week 1 may be partly due to reduced Mn transport upon spreading of oxidative stress through the inferior retina early after partial optic nerve injury58, whereas the further reduction in T1-weighted signal enhancement in left medial superior colliculus at Week 6 may indicate secondary loss of retinal ganglion cells and axons projecting through the uninjured, inferior optic nerve56,58. This further reduction in Mn enhancement at Week 6 was accompanied by more Mn deposition proximal to the transection site in the vitreous and the retina. The current Mn-enhanced MRI results may offer a sensitive tool for longitudinal assessments of secondary changes along initially uninjured neural connections in different neurodegenerative diseases and injuries. Together with Mn-enhanced MRI of perilesional tissues in brain ischemia, careful selection of Mn entry routes may allow examination of specific neurodegenerative events, as well as longitudinal monitoring of the integrity of topological connections in future studies of pharmacologic interventions against secondary degeneration57,59,60.
Our results indicate the different Mn transport dynamics in the normal and diseased brains that are detectable by Mn-enhanced MRI globally and quantitatively across time. Specifically, Mn may continuously redistribute in normal individual brain nuclei to different extents over a 2-week timeframe after systemic administration, whereas intravitreal Mn administration to healthy rodents may not only allow track-tracing of primary visual pathways, but also enhance non-visual brain nuclei in the hippocampus and medial amygdala consistently across 3 species. Depending on specific Mn entry routes, perilesional brain tissues may attract abnormal Mn accumulation and reduce anterograde Mn transport over time, leading to enhanced MRI detection of neurodegenerative events such as gliosis, oxidative stress and transport deficits after brain ischemia and partial optic nerve injury. Our results on detecting spatiotemporal changes of Mn level in the normal brain tissues may help determine the capacity of Mn uptake in individual brain nuclei, as well as the widespread projections of the brain circuitry. The characterization of Mn enhancement in perilesional tissues may help monitor the pathophysiological properties and evolutionary changes of salvageable tissues, which in turn may guide potential targets for improving functional consequences during primary and secondary neurodegeneration.
Four major sets of Mn-enhanced MRI experiments were performed in order to examine the spatiotemporal patterns of Mn enhancement in normal and perilesional tissues of healthy rodents and rodents after focal brain ischemia or partial optic nerve injury. Animals were maintained in an AAALAC-accredited animal facility with a 12 hr light/dark cycle with standard rodent chow and water available ad libitum. All experiments were performed in accordance with the Association of Research for Vision and Ophthalmology Statement for the Use of Animals in Ophthalmic and Vision Research. The protocol was approved by the animal care and use committee of The University of Hong Kong.
Experiment 1: Mn-enhanced MRI of Mn transport dynamics in normal brain nuclei upon systemic Mn administration
Adult Sprague-Dawley rats (250–300 g, n = 6) were prepared and injected intraperitoneally with MnCl2 solution at 45 mg/kg and 100 mM. Mn-enhanced MRI was performed before, and at 1, 5 and 12 days after injection.
Experiment 2: Mn-enhanced MRI of perilesional rims in brain ischemia upon systemic Mn administration
Photothrombotic cortical injury (PCI)
Adult Sprague-Dawley rats (200–250 g, n = 8) were subjected to PCI in the center of the right motor cortex using the Rose Bengal technique25, and were divided into 2 groups (n = 4 each). Two days after surgery, one group was administered with an intraperitoneal injection of MnCl2 solution (45 mg/kg, 100 mM), while the other group received no Mn injection. T1-weighted MRI was performed to both groups at 3 and 7 days after surgery, whereby two rats from each group were sacrificed for histology after MRI examinations at Day 7.
Transient middle cerebral artery occlusion (tMCAO)
Adult C57BL/6 N mice (18–22 g, n = 8) were subjected to intraluminal occlusion of the right middle cerebral artery for 30 min followed by reperfusion under gas anesthesia (induction: 2% halothane in 70% N2O/30% O2; maintenance: 1% halothane in 70% N2O/30% O2) at a stabilized body temperature of 37 °C61. Two days after surgery, the mice were divided into 2 groups of 4 animals each. One group was administered with an intraperitoneal injection of MnCl2 solution (45 mg/kg, 100 mM), while the other group received no Mn injection. T1-weighted MRI was performed at 3, 7, 10, 14 and 21 days after surgery, whereby 2 mice from each group were sacrificed for histology after MRI examinations at Day 10.
Neonatal hypoxic-ischemic (HI) brain injury
Apart from PCI and tMCAO, we examined with Mn-enhanced MRI the long-term effects of neonatal HI brain injury on the perilesional tissues. Sprague-Dawley rats (12–16 g, n = 6) underwent unilateral ligation of the left common carotid artery at postnatal day 7 under isoflurane anesthesia, followed by hypoxia in 8% oxygen and 92% nitrogen at 36–37 °C for 2 hours62. Another 6 rats were untreated and acted as age-matched healthy control. Five months later, MnCl2 solution (60 mg/kg, 100 mM) was slowly infused intraperitoneally at a rate of 15 μl/min for 1 hr. Mn-enhanced MRI was performed before, and at 1 day and 7 days after Mn infusion followed by histology.
Experiment 3: Mn-enhanced MRI of visual and non-visual pathways in normal brains upon intravitreal Mn administration
Adult Sprague-Dawley rats (226 ± 27 g, n = 6), Mongolian gerbils (66 ± 2 g, n = 4) and C57BL/6 J mice (20 ± 1 g, n = 6) received intravitreal MnCl2 injection (100 mM) into the right eye at a volume of 2 μL for rats and gerbils, and 0.5 μL for mice under isoflurane anesthesia. After full recovery, animals returned to their cages, and Mn-enhanced MRI was performed at 1 day after Mn injection. As more than 90% of the rodent retinal ganglion cell axons decussate to the contralateral posterior visual components at the optic chiasm63, the Mn enhancement patterns were compared to the brain nuclei of the opposite hemisphere as an internal control.
Experiment 4: Mn-enhanced MRI of perilesional visual pathway upon partial optic nerve injury
The superior region of the right intraorbital optic nerve of adult Sprague-Dawley rats (200–250 g, n = 10) was partially transected at about 2 mm from the eye using a custom-made thin blade40. One week and 6 weeks after surgery, MnCl2 solution (3 μL, 50 mM) was injected intravitreally into both eyes of the same animals under isoflurane anesthesia. Animals then recovered and returned to their cages, and Mn-enhanced MRI was performed a day later. Throughout the experiment, the left optic nerve was not transected and the visual pathway projected from the left eye to the right posterior visual brain served as an internal control.
All MRI measurements were acquired utilizing a 7 Tesla Bruker scanner with a maximum gradient of 360 mT/m (70/16 PharmaScan, Bruker Biospin GmbH, Germany). Under anesthesia by inhaled isoflurane (3% induction and 1.5% maintenance), the animals were kept warm under circulating water at 37 °C with respiratory monitoring. Scout T2-weighted images were first acquired in the coronal, transverse and sagittal planes with a rapid-acquisition-with-relaxation-enhancement (RARE) pulse sequence to position the subsequent MR images along standard anatomical orientations in a reproducible manner.
For experiment 1, 2D T1-weighted RARE pulse sequence was employed using a receive-only surface coil with the following parameters: field-of-view (FOV) = 3.2 × 3.2 cm2, matrix size = 256 × 256, slice thickness = 1 mm, number of slices = 10, repetition time/echo time (TR/TE) = 400/7.5 ms, RARE factor = 4, number of averages = 16.
For experiment 2, rats with PCI or HI injury were imaged using a receive-only surface coil, whereas mice with tMCAO were imaged using a transmit-receive volume coil. 2D T1-weighted RARE sequences were acquired with TR/TE = 400/7.5 ms, RARE factor = 4, and matrix size = 256 × 256. For the PCI and HI injury models, FOV = 3.2 × 3.2 cm2, slice thickness = 1 mm, and number of averages = 16. For the tMCAO model, FOV = 2.0 × 2.0 cm2, slice thickness = 0.7 mm, and number of averages = 20.
For experiment 3, a receive-only surface coil was used for imaging rats and gerbils, and a transmit-receive volume coil was used for imaging mice. 2D T1-weighted MRI was acquired in the coronal plane using RARE sequences, with TR/TE = 420/7.5 ms, FOV = 32 × 32 mm2 for rats and gerbils, and 20 × 20 mm2 for mice, in-plane acquisition resolution = 125 × 125 μm2, slice thickness = 0.8 mm, number of slices = 10, RARE factor = 4 and number of averages = 16. In addition, 3D T1-weighted MRI was acquired covering the entire primary visual pathway using the modified driven equilibrium Fourier transform (MDEFT) imaging sequence with inversion time (TI)/TR/TE = 1200/9/3 ms, FOV = 32 × 32 × 11 mm3 for rats and gerbils, and 25.6 × 25.6 × 9.6 mm3 for mice, acquisition resolution = 200 × 200 × 200 μm3, one segment and number of averages = 9.
For experiment 4, all animals were imaged using a receive-only surface coil. 3D T1-weighted MRI was acquired covering the entire primary visual pathway using a RARE sequence, with TR/TE = 250/6.7 ms, FOV = 32 × 32 × 16 mm3, acquisition resolution = 200 × 200 × 200 μm3, RARE factor = 4 and number of averages = 4.
For experiment 2, after MRI examinations at the end time point, a subset of 2 animals from each of the PCI, tMCAO and HI injury groups were transcardially perfused with 4% paraformaldehyde. The brains were then removed, cut into 10 μm sections, and immunostained for GFAP, MnSOD or GS, which are markers for gliosis, oxidative stress and glutamate excitotoxicity, respectively28,38,64. Slices were counterstained with hematoxylin and eosin (H&E) to detect general morphological abnormalities.
For experiment 4, at 6 weeks after partial optic nerve transection, 2 animals were randomly selected after Mn-enhanced MRI for histological verification of the location and severity of optic nerve injury at about 1.5 mm posterior to the eye using toluidine blue staining.
For experiment 1, regions of interest (ROI) were manually defined in different brain nuclei of T1-weighted MRI with reference to the rat brain atlas65. T1-weighted signal intensities were measured across time using ImageJ v1.44 (Wayne Rasband, NIH, USA), and were normalized to the surrounding saline phantom followed by the pre-injection time point to evaluate the rates of Mn enhancement and clearance in the brain nuclei after systemic Mn administration. The temporal changes of the same brain nuclei were compared using analyses of variance (ANOVA) followed by post-hoc multiple comparisons correction tests via GraphPad Prism v5.00 (GraphPad Software Inc., La Jolla, CA, USA).
For experiment 2, the T1-weighted signal intensities at the ischemic core and the perilesional areas were measured in both PCI and tMCAO models using ImageJ, and were compared with the contralateral hemisphere or across time using ANOVA followed by post-hoc multiple comparisons correction tests. For HI-injured animals, the T1-weighted signal intensities in the remaining tissues of the ipsilesional thalamus and cingulate cortex, and in the contralateral brain tissues were compared with the corresponding locations of age-matched normal controls using two-tailed Student’s t-tests.
For experiment 3, the T1-weighted signal intensities in the superior colliculus, lateral geniculate nucleus, the CA3 region of hippocampus and the posterior medial amygdala of each species were measured in the 2D T1-weighted images using ImageJ with reference to the rodent brain atlases65,66, and were normalized to the surrounding muscles. The normalized values of the brain nuclei were compared between contralateral hemispheres of the same species using two-tailed Student’s t-tests. In addition, maximum intensity projection was performed onto the 3D T1-weighted images after segmenting the primary visual pathway from the retina to the subcortex in both hemispheres for qualitative evaluation.
For experiment 4, the T1-weighted signal intensities in the vitreous, retina, distal optic nerve, lateral geniculate nucleus, and the medial and lateral regions of the superior colliculus were measured in both hemispheres using ImageJ. These values were normalized to the right medial superior colliculus of each animal, and were compared intra- and inter-hemispherically or between 1 week and 6 weeks after partial optic nerve transection using ANOVA followed by post-hoc multiple comparisons correction tests. Maximum intensity projection was also performed onto the 3D T1-weighted images for qualitative evaluation.
The morphology and intensity of the brain tissues in immunohistochemistry were assessed qualitatively across animal groups in experiments 2 and 4. For experiments 1–4, all quantitative data were presented as mean ± standard deviation. Results were considered statistically significant when p < 0.05.
How to cite this article: Chan, K. C. et al. Longitudinal Assessments of Normal and Perilesional Tissues in Focal Brain Ischemia and Partial Optic Nerve Injury with Manganese-enhanced MRI. Sci. Rep. 7, 43124; doi: 10.1038/srep43124 (2017).
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Silva, A. C. & Bock, N. A. Manganese-enhanced MRI: an exceptional tool in translational neuroimaging. Schizophr Bull 34, 595–604, doi: 10.1093/schbul/sbn056 (2008).
Massaad, C. A. & Pautler, R. G. Manganese-enhanced magnetic resonance imaging (MEMRI). Methods Mol Biol 711, 145–174, doi: 10.1007/978-1-61737-992-5_7 (2011).
Pautler, R. G., Silva, A. C. & Koretsky, A. P. In vivo neuronal tract tracing using manganese-enhanced magnetic resonance imaging. Magn Reson Med 40, 740–748 (1998).
Chan, K. C. et al. In vivo visuotopic brain mapping with manganese-enhanced MRI and resting-state functional connectivity MRI. Neuroimage 90, 235–245, doi: 10.1016/j.neuroimage.2013.12.056 (2014).
Eads, C. D. & Villafranca, J. J. Interaction among substrates, inhibitors and Mn2+ bound to glutamine synthetase as studied by NMR relaxation rate measurements. Arch Biochem Biophys 252, 382–387 (1987).
Lindenau, J., Noack, H., Possel, H., Asayama, K. & Wolf, G. Cellular distribution of superoxide dismutases in the rat CNS. Glia 29, 25–34 (2000).
Suarez, I., Bodega, G. & Fernandez, B. Glutamine synthetase in brain: effect of ammonia. Neurochem Int 41, 123–142 (2002).
Villafranca, J. J., Yost, F. J. Jr. & Fridovich, I. Magnetic resonance studies of manganese(3) and iron(3) superoxide dismutases. Temperature and frequency dependence of proton relaxation rates of water. J Biol Chem 249, 3532–3536 (1974).
Wedler, F. C. & Denman, R. B. Glutamine synthetase: the major Mn(II) enzyme in mammalian brain. Curr Top Cell Regul 24, 153–169 (1984).
Lee, J. H., Silva, A. C., Merkle, H. & Koretsky, A. P. Manganese-enhanced magnetic resonance imaging of mouse brain after systemic administration of MnCl2: dose-dependent and temporal evolution of T1 contrast. Magn Reson Med 53, 640–648, doi: 10.1002/mrm.20368 (2005).
Aoki, I., Wu, Y. J., Silva, A. C., Lynch, R. M. & Koretsky, A. P. In vivo detection of neuroarchitecture in the rodent brain using manganese-enhanced MRI. Neuroimage 22, 1046–1059 (2004).
Bock, N. A., Paiva, F. F., Nascimento, G. C., Newman, J. D. & Silva, A. C. Cerebrospinal fluid to brain transport of manganese in a non-human primate revealed by MRI. Brain Res 1198, 160–170 (2008).
Van der Linden, A., Van Camp, N., Ramos-Cabrer, P. & Hoehn, M. Current status of functional MRI on small animals: application to physiology, pathophysiology, and cognition. NMR Biomed 20, 522–545 (2007).
Aschner, M., Vrana, K. E. & Zheng, W. Manganese uptake and distribution in the central nervous system (CNS). Neurotoxicology 20, 173–180 (1999).
Patel, A. J., Weir, M. D., Hunt, A., Tahourdin, C. S. & Thomas, D. G. Distribution of glutamine synthetase and glial fibrillary acidic protein and correlation of glutamine synthetase with glutamate decarboxylase in different regions of the rat central nervous system. Brain Res 331, 1–9 (1985).
Norenberg, M. D. Distribution of glutamine synthetase in the rat central nervous system. J Histochem Cytochem 27, 756–762 (1979).
Gavin, C. E., Gunter, K. K. & Gunter, T. E. Manganese and calcium transport in mitochondria: implications for manganese toxicity. Neurotoxicology 20, 445–453 (1999).
Gavin, C. E., Gunter, K. K. & Gunter, T. E. Manganese and calcium efflux kinetics in brain mitochondria. Relevance to manganese toxicity. Biochem J 266, 329–334 (1990).
Tjalkens, R. B., Zoran, M. J., Mohl, B. & Barhoumi, R. Manganese suppresses ATP-dependent intercellular calcium waves in astrocyte networks through alteration of mitochondrial and endoplasmic reticulum calcium dynamics. Brain Res 1113, 210–219, doi: 10.1016/j.brainres.2006.07.053 (2006).
Faragalla, F. F. The distribution and exchange of brain calcium in vivo in the rat. Exp Brain Res 17, 206–215 (1973).
Nelson, M. T. Interactions of divalent cations with single calcium channels from rat brain synaptosomes. J Gen Physiol 87, 201–222 (1986).
Wedler, F. C., Ley, B. W. & Grippo, A. A. Manganese(II) dynamics and distribution in glial cells cultured from chick cerebral cortex. Neurochem Res 14, 1129–1135 (1989).
Allshire, A., Bernardi, P. & Saris, N. E. Manganese stimulates calcium flux through the mitochondrial uniporter. Biochim Biophys Acta 807, 202–209 (1985).
Hughes, J. L. et al. Mapping selective neuronal loss and microglial activation in the salvaged neocortical penumbra in the rat. Neuroimage 49, 19–31, doi: 10.1016/j.neuroimage.2009.08.047 (2010).
Bidmon, H. J., Kato, K., Schleicher, A., Witte, O. W. & Zilles, K. Transient increase of manganese-superoxide dismutase in remote brain areas after focal photothrombotic cortical lesion. Stroke 29, 203–210; discussion 211 (1998).
Wang, X. et al. Delayed changes in T1-weighted signal intensity in a rat model of 15-minute transient focal ischemia studied by magnetic resonance imaging/spectroscopy and synchrotron radiation X-ray fluorescence. Magn Reson Med 56, 474–480, doi: 10.1002/mrm.20985 (2006).
Fujioka, M. et al. Magnetic resonance imaging shows delayed ischemic striatal neurodegeneration. Ann Neurol 54, 732–747, doi: 10.1002/ana.10751 (2003).
Yang, J. et al. Manganese-enhanced MRI detection of neurodegeneration in neonatal hypoxic-ischemic cerebral injury. Magn Reson Med 59, 1329–1339, doi: 10.1002/mrm.21484 (2008).
Wideroe, M. et al. Manganese-enhanced magnetic resonance imaging of hypoxic-ischemic brain injury in the neonatal rat. Neuroimage 45, 880–890, doi: 10.1016/j.neuroimage.2008.12.007 (2009).
Kawai, Y. et al. In vivo visualization of reactive gliosis using manganese-enhanced magnetic resonance imaging. Neuroimage 49, 3122–3131, doi: 10.1016/j.neuroimage.2009.11.005 (2010).
Wideroe, M. et al. Longitudinal manganese-enhanced magnetic resonance imaging of delayed brain damage after hypoxic-ischemic injury in the neonatal rat. Neonatology 100, 363–372, doi: 10.1159/000328705 (2011).
Pinteaux, E., Perraut, M. & Tholey, G. Distribution of mitochondrial manganese superoxide dismutase among rat glial cells in culture. Glia 22, 408–414 (1998).
Siesjo, B. K. Pathophysiology and treatment of focal cerebral ischemia. Part I: Pathophysiology. (1992). J Neurosurg 108, 616–631, doi: 10.3171/JNS/2008/108/3/0616 (2008).
Di Filippo, M. et al. Plasticity and repair in the post-ischemic brain. Neuropharmacology 55, 353–362, doi: 10.1016/j.neuropharm.2008.01.012 (2008).
Pautler, R. G. Biological applications of manganese-enhanced magnetic resonance imaging. Methods Mol Med 124, 365–386 (2006).
Hussain, S. & Ali, S. F. Manganese scavenges superoxide and hydroxyl radicals: an in vitro study in rats. Neurosci Lett 261, 21–24 (1999).
Singh, R. K. et al. Potential use of simple manganese salts as antioxidant drugs in horses. Am J Vet Res 53, 1822–1829 (1992).
Yang, J. & Wu, E. X. Detection of cortical gray matter lesion in the late phase of mild hypoxic-ischemic injury by manganese-enhanced MRI. Neuroimage 39, 669–679, doi: 10.1016/j.neuroimage.2007.09.009 (2008).
Watanabe, T., Frahm, J. & Michaelis, T. Functional mapping of neural pathways in rodent brain in vivo using manganese-enhanced three-dimensional magnetic resonance imaging. NMR Biomed 17, 554–568 (2004).
Chan, K. C. et al. In vivo retinotopic mapping of superior colliculus using manganese-enhanced magnetic resonance imaging. Neuroimage 54, 389–395, doi: 10.1016/j.neuroimage.2010.07.015 (2011).
Chan, K. C. et al. In vivo evaluation of retinal and callosal projections in early postnatal development and plasticity using manganese-enhanced MRI and diffusion tensor imaging. Neuroimage 59, 2274–2283, doi: 10.1016/j.neuroimage.2011.09.055 (2012).
Chan, K. C., Fu, Q. L., Hui, E. S., So, K. F. & Wu, E. X. Evaluation of the retina and optic nerve in a rat model of chronic glaucoma using in vivo manganese-enhanced magnetic resonance imaging. Neuroimage 40, 1166–1174, doi: 10.1016/j.neuroimage.2008.01.002 (2008).
Ho, L. C. et al. In Vivo Evaluation of White Matter Integrity and Anterograde Transport in Visual System After Excitotoxic Retinal Injury With Multimodal MRI and OCT. Invest Ophthalmol Vis Sci 56, 3788–3800, doi: 10.1167/iovs.14-15552 (2015).
Kancherla, S., Kohler, W. J., van der Merwe, Y. & Chan, K. C. In Vivo Evaluation of the Visual Pathway in Streptozotocin-Induced Diabetes by Diffusion Tensor MRI and Contrast Enhanced MRI. PLoS One 11, e0165169, doi: 10.1371/journal.pone.0165169 (2016).
Hattar, S. et al. Central projections of melanopsin-expressing retinal ganglion cells in the mouse. J Comp Neurol 497, 326–349, doi: 10.1002/cne.20970 (2006).
Bearer, E. L. et al. Role of neuronal activity and kinesin on tract tracing by manganese-enhanced MRI (MEMRI). Neuroimage 37 Suppl 1, S37–46, doi: S1053-8119(07)00380-1 [pii]10.1016/j.neuroimage.2007.04.053 (2007).
Wang, L. et al. Manganese-Enhanced MRI Reflects Both Activity-Independent and Activity-Dependent Uptake within the Rat Habenulomesencephalic Pathway. PLoS One 10, e0127773, doi: 10.1371/journal.pone.0127773 (2015).
Elliott, A. S., Weiss, M. L. & Nunez, A. A. Direct retinal communication with the peri-amygdaloid area. Neuroreport 6, 806–808 (1995).
Cooper, H. M., Herbin, M. & Nevo, E. Visual system of a naturally microphthalmic mammal: the blind mole rat, Spalax ehrenbergi. J Comp Neurol 328, 313–350, doi: 10.1002/cne.903280302 (1993).
Johnson, R. F., Morin, L. P. & Moore, R. Y. Retinohypothalamic projections in the hamster and rat demonstrated using cholera toxin. Brain Res 462, 301–312 (1988).
Vereczki, V. et al. Distribution of hypothalamic, hippocampal and other limbic peptidergic neuronal cell bodies giving rise to retinopetal fibers: anterograde and retrograde tracing and neuropeptide immunohistochemical studies. Neuroscience 140, 1089–1100, doi: 10.1016/j.neuroscience.2006.02.081 (2006).
Chuang, K. H. & Koretsky, A. P. Accounting for nonspecific enhancement in neuronal tract tracing using manganese enhanced magnetic resonance imaging. Magn Reson Imaging 27, 594–600, doi: 10.1016/j.mri.2008.10.006 (2009).
Wang, J. et al. Structural brain alterations in primary open angle glaucoma: a 3T MRI study. Sci Rep 6, 18969, doi: 10.1038/srep18969 (2016).
Murphy, M. C. et al. Retinal Structures and Visual Cortex Activity are Impaired Prior to Clinical Vision Loss in Glaucoma. Sci Rep 6, 31464, doi: 10.1038/srep31464 (2016).
Frezzotti, P. et al. Structural and functional brain changes beyond visual system in patients with advanced glaucoma. PLoS One 9, e105931, doi: 10.1371/journal.pone.0105931 (2014).
Levkovitch-Verbin, H. et al. A model to study differences between primary and secondary degeneration of retinal ganglion cells in rats by partial optic nerve transection. Invest Ophthalmol Vis Sci 44, 3388–3393 (2003).
Fitzgerald, M. et al. Secondary retinal ganglion cell death and the neuroprotective effects of the calcium channel blocker lomerizine. Invest Ophthalmol Vis Sci 50, 5456–5462, doi: iovs.09-3717 [pii] 10.1167/iovs.09-3717 (2009).
Fitzgerald, M., Bartlett, C. A., Harvey, A. R. & Dunlop, S. A. Early events of secondary degeneration after partial optic nerve transection: an immunohistochemical study. J Neurotrauma 27, 439–452, doi: 10.1089/neu.2009.1112 (2010).
Chu, P. H., Li, H. Y., Chin, M. P., So, K. F. & Chan, H. H. Effect of lycium barbarum (wolfberry) polysaccharides on preserving retinal function after partial optic nerve transection. PLoS One 8, e81339, doi: 10.1371/journal.pone.0081339 (2013).
Fitzgerald, M. et al. Near infrared light reduces oxidative stress and preserves function in CNS tissue vulnerable to secondary degeneration following partial transection of the optic nerve. J Neurotrauma 27, 2107–2119, doi: 10.1089/neu.2010.1426 (2010).
Hung, V. K. et al. Selective astrocytic endothelin-1 overexpression contributes to dementia associated with ischemic stroke by exaggerating astrocyte-derived amyloid secretion. J Cereb Blood Flow Metab 35, 1687–1696, doi: 10.1038/jcbfm.2015.109 (2015).
Chan, K. C., Kancherla, S., Fan, S. J. & Wu, E. X. Long-term effects of neonatal hypoxia-ischemia on structural and physiological integrity of the eye and visual pathway by multimodal MRI. Invest Ophthalmol Vis Sci 56, 1–9, doi: 10.1167/iovs.14-14287 (2015).
Fleming, M. D., Benca, R. M. & Behan, M. Retinal projections to the subcortical visual system in congenic albino and pigmented rats. Neuroscience 143, 895–904, doi: 10.1016/j.neuroscience.2006.08.016 (2006).
Chan, K. C. et al. MRI of late microstructural and metabolic alterations in radiation-induced brain injuries. J Magn Reson Imaging 29, 1013–1020, doi: 10.1002/jmri.21736 (2009).
Paxinos, G. & Watson, C. The Rat Brain in Stereotaxic Coordinates: Hard Cover Edition. (Elsevier Science, 2006).
Paxinos, G. & Franklin, K. B. J. The Mouse Brain in Stereotaxic Coordinates. (Elsevier Academic Press, 2004).
This work was supported by the National Institutes of Health P30-EY008098 (Bethesda, Maryland); BrightFocus Foundation G2013077 (Clarksburg, Maryland); Alcon Research Institute Young Investigator Grant (Fort Worth, Texas); Eye and Ear Foundation (Pittsburgh, Pennsylvania); Research to Prevent Blindness (New York, New York); and Hong Kong Research Grant Council GRF HKU 7837/11 M (Hong Kong, China).
The authors declare no competing financial interests.
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Chan, K., Zhou, I., Liu, S. et al. Longitudinal Assessments of Normal and Perilesional Tissues in Focal Brain Ischemia and Partial Optic Nerve Injury with Manganese-enhanced MRI. Sci Rep 7, 43124 (2017). https://doi.org/10.1038/srep43124
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