Jason R. Potas

Early Loss of Pericytes and Perivascular Stromal Cell-Induced Scar Formation after Stroke

Despite its limited regenerative capacity, the central nervous system (CNS) shares more repair mechanisms with peripheral tissues than previously recognized. Scar formation is a ubiquitous healing mechanism aimed at patching tissue defects via the generation of fibrous extracellular matrix (ECM). This process, orchestrated by stromal cells, can unfavorably affect the capacity of tissues to restore function. Vascular mural cells have been found to contribute to scarring after spinal cord injury. In the case of stroke, little is known about the responses of pericytes (PCs) and stromal cells. Here, we show that capillary PCs are rapidly lost after cerebral ischemia in both experimental and human stroke. Coincident with this loss is a massive proliferation of resident platelet-derived growth factor receptor beta (PDGFRβ)+ and CD105+ stromal cells, which originate from the neurovascular unit and deposit ECM in the ischemic mouse brain. The presence of PDGFRβ+ stromal cells demarcates a fibrotic, contracted, and macrophage-laden lesion core from the rim of hypertrophic astroglia in both experimental and human stroke. We suggest that a previously unrecognized population of CNS-resident stromal cells drives a dynamic process of scarring after cerebral ischemia, which appears distinct from the glial scar and represents a novel target for regenerative stroke therapies.

Interleukin-10 conjugated electrospun polycaprolactone (PCL) nanofibre scaffolds for promoting alternatively activated (M2) macrophages around the peripheral nerve in vivo.

Macrophages play a key role in tissue regeneration following peripheral nerve injury by preparing the surrounding parenchyma for regeneration, however, they can be damaging if the response is excessive. Interleukin 10 (IL-10) is a cytokine that promotes macrophages toward an anti-inflammatory/wound healing state (M2 phenotype). The bioactive half-life of IL-10 is dependent on the cellular microenvironment and ranges from minutes to hours in vivo. Our objective was to extend the in vivo bioavailability and bioactivity of IL-10 by attaching the protein onto nanofibrous scaffolds and demonstrating increased expression levels of M2 macrophages when placed around healthy intact peripheral nerves. IL-10 was adsorbed and covalently bound to electrospun poly(ε-caprolactone) (PCL) nanofibrous scaffolds. In vivo bioavailability and bioactivity of IL-10 was confirmed by wrapping IL-10 conjugated nanofibres around the sciatic nerves of Wistar rats and quantifying M2 macrophages immunohistochemically double labelled with ED1 and either arginase 1 or CD206. IL-10 remained immobilised to PCL scaffolds for more than 120 days when stored in phosphate buffered saline at room temperature and for up to 14d ays when implanted around the sciatic nerve. IL-10 conjugated nanofibres successfully induced macrophage polarisation towards the M2 activated state within the scaffold material as well as the adjacent tissue surrounding the nerve. PCL biofunctionalised nanofibres are useful for manipulating the cellular microenvironment. Materials such as these could potentially lead to new therapeutic strategies for nervous tissue injuries as well as provide novel investigative tools for biological research.

Angiotensin II evokes hypotension and renal sympathoinhibition from a highly restricted region in the nucleus tractus solitarii

Microinjections of low doses (in the femtomolar or low picomolar range) of angiotensin II (Ang II) into the nucleus tractus solitarii (NTS) evoke depressor responses. In this study we have mapped in the rat the precise location of the subregion within the NTS at which Ang II evokes significant sympathoinhibitory and depressor responses. Microinjections of 1 pmol of Ang II evoked large decreases (>or=20% of baseline) in renal sympathetic nerve activity (RSNA), from a highly restricted region in the medial NTS, at or very close to the level 0.2 mm caudal to the obex. Microinjections of the same dose of Ang II into the commissural or lateral NTS at the same rostrocaudal level, or into the medial and lateral NTS at the level of the obex evoked significantly smaller sympathoinhibitory responses, while microinjections into more rostral or caudal levels of the NTS evoked significant sympathoinhibitory responses even less frequently. In most cases (71%), the sympathoinhibitory responses were accompanied by depressor responses, the magnitudes of which were also greater within the medial NTS at the level 0.2 mm caudal to obex, as compared to the surrounding subregions. The results demonstrate that the cardiovascular effects of Ang II in the NTS are highly site-specific. Taken together with previous studies, the results also indicate that the neurons in the NTS that mediate the Ang II-evoked sympathoinhibition are a discrete subgroup of the population of sympathoinhibitory neurons within the nucleus.

Renal sympathetic and cardiac changes associated with anaphylactic hypotension.

Severe anaphylactic reactions can result in life-threatening hypotension, but little is known about the autonomic changes that accompany the hypotensive response. The aim of this study was to determine the renal sympathetic and cardiac responses to anaphylactic hypotension, and to evaluate the contribution of sinoaortic and vagal afferent inputs in producing these responses. Rats were sensitized with bovine serum albumin (BSA) and, after 10-14 days, were anaesthesized with sodium pentobarbitone and arterial pressure, heart rate (HR), and renal sympathetic nerve activity (RSNA) were recorded. In about two thirds of the rats, injection of BSA evoked a severe and sustained hypotension, while in the remainder, there was either a more transient hypotension or else no significant change in arterial pressure. In control unsensitized rats, BSA injection had no significant effect on arterial pressure, heart rate, or RSNA. The BSA-induced hypotension in sensitized rats was associated with increases in HR and RSNA, the magnitudes of which were correlated with the magnitude of the hypotension. There were two components to the cardiac and renal sympathoexcitatory response: (1) an initial increase in HR and RSNA, which immediately followed the onset of hypotension and which was abolished by sinoaortic denervation and vagotomy, and (2) a delayed and gradual increase in HR and RSNA, which continued even while the arterial pressure was recovering and was reduced but not abolished by sinoaortic denervation and vagotomy. Thus, BSA-induced anaphylactic hypotension causes prolonged tachycardia and renal sympathoexcitation, which is only partly due to reflex effects arising from sinoaortic baroreceptors and cardiopulmonary receptors.

Somatic and visceral afferents to the 'vasodepressor region' of the caudal midline medulla in the rat

Previous research has found that the integrity of a restricted region of the caudal midline medulla (including caudal portions of nucleus raphé obscurus and nucleus raphé pallidus) was critical for vasodepression (hypotension, bradycardia, decreased cardiac contractility) evoked either by haemorrhage or deep pain. In this anatomical tracing study we found that the vasodepressor part of the caudal midline medulla (CMM) receives inputs arising from spinal cord, spinal trigeminal nucleus (SpV) and nucleus of the solitary tract (NTS). Specifically: (i) a spinal–CMM projection arises from neurons of the deep dorsal horn, medial ventral horn and lamina X at all spinal segmental levels, with approximately 60% of the projection originating from the upper cervical spinal cord (C1–C4); (ii) a SpV–CMM projection arises primarily from neurons at the transition between subnucleus caudalis and subnucleus interpolaris; (iii) a NTS–CMM projection arises primarily from neurons in ventrolateral and medial subnuclei. In combination, the specific spinal, SpV and NTS regions which project to the CMM receive the complete range of somatic and visceral afferents known to trigger vasodepression. The role(s) of each specific projection is discussed.

Evidence that venoconstriction reverses the phase II sympathoinhibitory and bradycardic response to haemorrhage

Severe hypotensive haemorrhage results in a biphasic response, characterized by an initial increase in heart rate and sympathetic vasomotor activity (phase I) followed by a life-threatening hypotension, accompanied by profound sympathoinhibition and bradycardia (phase II). The phase II response is believed to be dependent on inputs from cardiopulmonary receptors, and may be triggered by the reduction in venous return and cardiac filling associated with severe haemorrhage. In this study, we tested the hypothesis that the phase II response could be reversed by venoconstriction, which is known to enhance venous return and cardiac filling, by comparing the effects of phenylephrine (which constricts veins as well as arterioles) with that of vasopressin (which constricts arterioles but not veins). In sodium pentobarbitone-anaesthetised rats, haemorrhage evoked an initial increase in heart rate (HR) and renal sympathetic activity (RSNA) followed by a large decrease in both variables to levels below the pre-haemorrhage baseline levels (phase II response). During the phase II response, an intravenous injection of phenylephrine, sufficient to restore mean arterial pressure to the pre-haemorrhage level, resulted in a gradually developing increase (over 3-4 min) in HR and RSNA back to the baseline levels. In contrast, intravenous injection of an equipressor dose of vasopressin did not result in any increase in RSNA and only a transient increase in HR. Injection of phenylephrine, but not vasopressin, also increased the pulsatile component of central venous pressure, indicative of reduced venous capacitance. The findings indicate that venoconstriction reverses the phase II sympathoinhibition and bradycardia.

Waveform Similarity Analysis: A Simple Template Comparing Approach for Detecting and Quantifying Noisy Evoked Compound Action Potentials.

Experimental electrophysiological assessment of evoked responses from regenerating nerves is challenging due to the typical complex response of events dispersed over various latencies and poor signal-to-noise ratio. Our objective was to automate the detection of compound action potential events and derive their latencies and magnitudes using a simple cross-correlation template comparison approach. For this, we developed an algorithm called Waveform Similarity Analysis. To test the algorithm, challenging signals were generated in vivo by stimulating sural and sciatic nerves, whilst recording evoked potentials at the sciatic nerve and tibialis anterior muscle, respectively, in animals recovering from sciatic nerve transection. Our template for the algorithm was generated based on responses evoked from the intact side. We also simulated noisy signals and examined the output of the Waveform Similarity Analysis algorithm with imperfect templates. Signals were detected and quantified using Waveform Similarity Analysis, which was compared to event detection, latency and magnitude measurements of the same signals performed by a trained observer, a process we called Trained Eye Analysis. The Waveform Similarity Analysis algorithm could successfully detect and quantify simple or complex responses from nerve and muscle compound action potentials of intact or regenerated nerves. Incorrectly specifying the template outperformed Trained Eye Analysis for predicting signal amplitude, but produced consistent latency errors for the simulated signals examined. Compared to the trained eye, Waveform Similarity Analysis is automatic, objective, does not rely on the observer to identify and/or measure peaks, and can detect small clustered events even when signal-to-noise ratio is poor. Waveform Similarity Analysis provides a simple, reliable and convenient approach to quantify latencies and magnitudes of complex waveforms and therefore serves as a useful tool for studying evoked compound action potentials in neural regeneration studies.

Characterisation and functional mapping of surface potentials in the rat dorsal column nuclei

The brainstem dorsal column nuclei (DCN) process sensory information arising from the body before it reaches the brain and becomes conscious. Despite significant investigations into sensory coding in peripheral nerves and the somatosensory cortex, little is known about how sensory information arising from the periphery is represented in the DCN. Following stimulation of hind‐limb nerves, we mapped and characterised the evoked electrical signatures across the DCN surface. We show that evoked responses recorded from the DCN surface are highly reproducible and are unique to nerves carrying specific sensory information.