Spinal Interneuron Axons Spontaneously Regenerate after Spinal Cord Injury in the Adult Feline

Fenrich, Keith K.; Rose, P. K.

doi:10.1523/jneurosci.0897-09.2009

Cited by 80 publications

(78 citation statements)

References 46 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…]; supplemental dosages, 5 mg/kg i.v.). The surgical procedures, peripheral nerve stimulation protocols, and postoperative care procedures have previously been described (Fenrich et al, 2007;Fenrich and Rose, 2009). Briefly, the animal's head was placed in a stereotaxic head-holder, the C2 and C3 vertebra were exposed and the dorsal bone covering the C3 segment was removed.…”

Section: Materials and Methods Surgeriesmentioning

confidence: 99%

“…These blades were mounted on a microdrive attached to the stereotaxic frame. The lesion protocol has previously been described in detail (Fenrich et al, 2007;Fenrich and Rose, 2009). Briefly, the blade was aligned with the spinal midline on the dorsal surface of the spinal cord at the caudal edge of the planned lesion site.…”

Section: Spinal Midline Transectionsmentioning

confidence: 99%

“…For instance, Dray et al (2009) found that mouse spinal DRG axons can regenerate through pinprick SCIs. In addition, we recently showed that axons of some axotomized propriospinal commissural interneurons (PCI) can regenerate through SCI sites in the adult cat (Fenrich and Rose, 2009). However, whether there are certain morphological characteristics that distinguish between axons that cross a lesion site and those that fail to cross a lesion site remains unknown.…”

mentioning

confidence: 99%

See 2 more Smart Citations

Axons with highly branched terminal regions successfully regenerate across spinal midline transections in the adult cat

Fenrich

Rose

2011

J of Comparative Neurology

View full text Add to dashboard Cite

We recently reported that some, but not all, axotomized propriospinal commissural interneurons (PCI) of the adult mammal can regenerate through spinal midsagittal transection injury sites (Fenrich and Rose [2009] J Neurosci 29:12145-12158). In this model, regenerating axons grow through a lesion site surrounded by a dense deposition of chondroitin sulfate proteoglycans (CSPG), which are typically inhibitory to regenerating axons. However, the mechanisms that lead some regenerating axons to grow through spinal cord injury (SCI) sites while others remain trapped in the CSPG zones or retract to their soma remain unknown. As a first step toward elucidating these mechanisms, here we show that the ability of PCI axons to regenerate across a SCI site depends on the branching patterns of their distal terminals. Using 3D reconstruction techniques through multiple serial sections and immunohistochemical analyses, we found that at 7 days postinjury a majority of PCI axons terminated in CSPG zones ipsilateral of the spinal midline. Conversely, at 9 days postinjury some PCI axons had regenerated across the midline, but others terminated outside the CSPG zones near their soma. Furthermore, we show that the most successful regenerators were those with the most extensive branching patterns, whereas those that terminated outside the CSPG zones had terminal regions indistinguishable from dystrophic terminals. Our results demonstrate that the morphological characteristics of regenerating axons play an important role in their ability to regenerate across SCI sites, and that the branching patterns of some regenerating axons are more extensive and have a far greater complexity than previously reported.

show abstract

Section: Materials and Methods Surgeriesmentioning

confidence: 99%

Section: Spinal Midline Transectionsmentioning

confidence: 99%

mentioning

confidence: 99%

See 1 more Smart Citation

Axons with highly branched terminal regions successfully regenerate across spinal midline transections in the adult cat

Fenrich

Rose

2011

J of Comparative Neurology

View full text Add to dashboard Cite

show abstract

“…During the last decade, increasing evidence obtained from different spinal cord injury (SCI) models has shown that spinal networks can reorganize spontaneously to contribute to functional recovery [1][2][3][4][5][6][7][8][9] . Adaptive plasticity has as a consequence become an important topic in SCI research.…”

Section: Introductionmentioning

confidence: 99%

A Neonatal Mouse Spinal Cord Compression Injury Model

Züchner

Glover

Boulland

2016

JoVE

View full text Add to dashboard Cite

Spinal cord injury (SCI) typically causes devastating neurological deficits, particularly through damage to fibers descending from the brain to the spinal cord. A major current area of research is focused on the mechanisms of adaptive plasticity that underlie spontaneous or induced functional recovery following SCI. Spontaneous functional recovery is reported to be greater early in life, raising interesting questions about how adaptive plasticity changes as the spinal cord develops. To facilitate investigation of this dynamic, we have developed a SCI model in the neonatal mouse. The model has relevance for pediatric SCI, which is too little studied. Because neural plasticity in the adult involves some of the same mechanisms as neural plasticity in early life 1 , this model may potentially have some relevance also for adult SCI. Here we describe the entire procedure for generating a reproducible spinal cord compression (SCC) injury in the neonatal mouse as early as postnatal (P) day 1. SCC is achieved by performing a laminectomy at a given spinal level (here described at thoracic levels 9-11) and then using a modified Yasargil aneurysm mini-clip to rapidly compress and decompress the spinal cord. As previously described, the injured neonatal mice can be tested for behavioral deficits or sacrificed for ex vivo physiological analysis of synaptic connectivity using electrophysiological and high-throughput optical recording techniques 1 . Earlier and ongoing studies using behavioral and physiological assessment have demonstrated a dramatic, acute impairment of hindlimb motility followed by a complete functional recovery within 2 weeks, and the first evidence of changes in functional circuitry at the level of identified descending synaptic connections 1 .

show abstract

“…This may explain why human stepping-like movements are easier to induce aftercervical than thoracic SCI, 9 and also the chronic weakness detected in human arm muscles that receive innervation from spinal levels just caudal to the lesion site. 10 The loss and recovery of forelimb motor function has been studied in several models of cervical SCI in rats, 4,[11][12][13][14][15][16][17][18][19][20][21][22][23][24][25][26][27] cats, [28][29][30] and primates. [31][32][33][34][35] All those studies demonstrated some extent of spontaneous motor function recovery, albeit with persisting deficits as a consequence of interruption of descending axonal tracts or segmental neuronal death.…”

Section: Introductionmentioning

confidence: 99%

Dynamic Motor Compensations with Permanent, Focal Loss of Forelimb Force after Cervical Spinal Cord Injury

López-Dolado

Lucas‐Osma²,

Collazos‐Castro³

2013

Journal of Neurotrauma

View full text Add to dashboard Cite

Incomplete cervical lesion is the most common type of human spinal cord injury (SCI) and causes permanent paresis of arm muscles, a phenomenon still incompletely understood in physiopathological and neuroanatomical terms. We performed spinal cord hemisection in adult rats at the caudal part of the segment C6, just rostral to the bulk of triceps brachii motoneurons, and analyzed the forces and kinematics of locomotion up to 4 months postlesion to determine the nature of motor function loss and recovery. A dramatic (50%), immediate and permanent loss of extensor force occurred in the forelimb but not in the hind limb of the injured side, accompanied by elbow and wrist kinematic impairments and early adaptations of whole-body movements that initially compensated the balance but changed continuously over the follow-up period to allow effective locomotion. Overuse of both contralateral legs and ipsilateral hind leg was evidenced since 5 days postlesion. Ipsilateral foreleg deficits resulted mainly from interruption of axons that innervate the spinal cord segments caudal to the lesion, because chronic loss (about 35%) of synapses was detected at C7 while only 14% of triceps braquii motoneurons died, as assessed by synaptophysin immunohistochemistry and retrograde neural tracing, respectively. We also found a large pool of propriospinal neurons projecting from C2-C5 to C7 in normal rats, with topographical features similar to the propriospinal premotoneuronal system of cats and primates. Thus, concurrent axotomy at C6 of brain descending axons and cervical propriospinal axons likely hampered spontaneous recovery of the focal neurological impairments.

show abstract

Spinal Interneuron Axons Spontaneously Regenerate after Spinal Cord Injury in the Adult Feline

Cited by 80 publications

References 46 publications

Axons with highly branched terminal regions successfully regenerate across spinal midline transections in the adult cat

Axons with highly branched terminal regions successfully regenerate across spinal midline transections in the adult cat

A Neonatal Mouse Spinal Cord Compression Injury Model

Dynamic Motor Compensations with Permanent, Focal Loss of Forelimb Force after Cervical Spinal Cord Injury

Contact Info

Product

Resources

About