Nerve Tracing in Juvenile Rats: A Feasible Model for the Study of Brachial Plexus Birth Palsy and Cocontractions?

• Abstract
• Background
• Materials and Methods
• Ethical Guidelines
• Materials
• Surgery
• Surgical Procedures
• Specimen Treatment
• Statistics
• Results
• Discussion
• References

Abstract

Brachial plexus birth injuries cause diminished motor function in the upper extremity. The most common sequel is internal rotation contracture. A number of these patients also suffer from cocontractions, preventing the use of an otherwise good passive range of motion in the shoulder. One theory behind the co-contracture problem is that injured nerve fibers grow into distal support tissue not corresponding to the proximal support tissue, resulting in reinnervation of the wrong muscle groups. To further elucidate this hypothesis, we used rat neonates to investigate a possible model for the study of cocontractions in brachial plexus birth injuries. Five-day-old rats were subjected to a crush injury to the C5–C6 roots. After a healing period of 4 weeks, the infraspinatus muscle was injected with Fluoro-Gold. A week later, the animals were perfused and spinal cords harvested and sectioned. Differences in the uptake of Fluoro-Gold and NeuN positive cells of between sides of the spinal cord were recorded. We found a larger amount of Fluoro-Gold positive cells on the uninjured side, while the injured side had positive cells dispersed over a longer area in the craniocaudal direction. Our findings indicate that the method can be used to trace Fluoro-Gold from muscle through a neuroma. Our results also indicate that a neuroma in continuity somewhat prevents the correct connection from being established between the motor neuron pool in the spinal cord and target muscle and that some neurons succumb to a crushing injury. We also present future research ideas.

Background

Brachial plexus birth palsy (BPBP) affects roughly 2.9/1,000 live births in developed countries.[1] The vast majority (over 70%) go on to recover full or near full function without any surgical intervention.[2] Children who do not recover or only recover partly most commonly suffer from an internal rotation contracture in the glenohumeral joint. The contracture keeps the forearm in a position close to the torso compromising the ability to place the hand in front of the body. Reaching the mouth, head, and neck can become difficult.[3] [4] Around 45% of children with external rotation contracture also develop some degree of incongruence in the glenohumeral joint.[5]

The internal rotation contracture was described in detail as early as 1905,[6] but despite many studies, clinical as well as experimental, the mechanism behind this dysfunction is not clear. Today it is well established that contracture develops in the subscapularis muscle and that a release of that musculotendinous unit is key to effective treatment.[7]

We have performed more than 400 subscapularis elongations on children with internal rotation contracture in our unit, with good clinical results in the passive and active shoulder motion in most patients.[4] [5]

In follow-up after surgery, we have observed a number of patients who cannot fully use their available range of rotation, due to simultaneous activation of the external rotators and their antagonists—a phenomenon known as “co-contraction.” This can affect both those with milder C5–C6 injuries and patients with more severe injuries including avulsions. Little is known about this phenomenon; it is unclear why some patients are affected more than others and to what extent it contributes to the development of contracture in the first place.[8] [9] Even less known is the exact neurological mechanism behind this phenomenon.

Cocontractions about the shoulder have been investigated earlier in research concerning subacromial shoulder pain in adults, where it has been shown that cocontractions in the shoulder adductors, for example, latissimus dorsi during abduction, have been associated with less subacromial pain.[10] The cause of cocontractions in BPBP, however, is so little investigated that it has been stated as unknown as recently as 2019.[11] The idea of “misguided” or misled nerve healing has been suggested to be the cause of this but without conclusive evidence.[8] [9] To the best of our knowledge, there has not been any experimental studies regarding the origins of the cocontractions seen in BPBP.

Rats and mice have a brachial plexus anatomy that is similar to that of humans and are therefore potentially useful as models for research on BPBP. When subjugated to a nerve injury on C5–C6 early in life, they have been shown to develop both external rotation contracture and the typical bony deformities of BPBP.[12] [13] [14]

Fluoro-Gold (FG) is a well-known neural tracer. It can be injected directly into muscles, where it is taken up by the motor endplates and retrogradely transported into the central nervous system and the nerve cell body.[15]

In this experimental study, our aim is to investigate a possible model for the study of cocontractions in BPBP and to elucidate if mechanisms such as cross-innervation[9] may have a role in causing cocontractions in BPBP by changing the motor neuron topography in the cervical cord. The null hypothesis was that there are no significant differences in FG uptake and distribution between injured and uninjured side.

Materials and Methods

Ethical Guidelines

The study was carried out according to ethical approval for animal experiments from the Stockholm board for ethics in animal experiments under number 9876-2018.

Materials

Fourteen 5-day-old Sprague-Dawley rat pups from two different mothers were used for this study. They were operated in groups of five and nine. The rat pups all underwent the same procedure on the same side utilizing the uninjured side as control. Rats were kept together with their mother according to animal welfare institution guidelines. Water and food were provided ad libitum. All animals from each of the two litters were included. In the first operated group, two animals were lost during surgery due to blood loss and two more were euthanized due to signs of infection and ill being.

Surgery

To determine the areas of interest for sectioning a prestudy using the protocol of surgery, injection and perfusion as described below were performed. The animals in the prestudy were thus treated the same as the animals in the two groups, but they were cut in the coronal plane to match the FG uptake more clearly to the cervical root level ([Fig. 1]).

Surgical Procedures

The 5-day-old pups were anesthetized using isoflurane, kept on a heat pad linked to a rodent rectal thermometer and thermostat, and the O₂ saturation was monitored (all apparatus from Agnthos, Lidingö, Sweden). A surgical microscope 6-10x magnification (Leica, Germany) was used for dissection. In field sterility, a straight incision was made 1 mm below the clavicle, and the cephalic vein was heat coagulated and displaced cranially. The pectoralis and the sternomastoideus were split between fibers and held using micro-retractors. The suprascapular nerve was identified to find the upper trunk, and the upper trunk was then verified using a nerve stimulator (Bovie Neuro-pulse, Bovie Medical Corporation, United States) to elicit activity in abduction and elbow flection. To create a neuroma in continuity or axonotmesis, a constant pressure was held against the upper trunk proximal to the suprascapular nerve branching for 10 seconds using micro-forceps.[16] [17] The fat pad was replaced, and the incision closed using interrupted Prolene 7–0 sutures. The rat pups were monitored in a separate clean and heated cage until showing signs of anesthesia wearing off, then returned to the mother. Perioperative fluid and peri- and postoperative analgesia were administered according to bodyweight via intraperitoneal injections of saline, Buprenorphine 0.05 mg/kg (Temgesic, Reckitt Benckiser Healthcare, UK), and Carprofen 5 mg/kg (Rimadyl Bovis vet, Zoetis, Finland).

Reduced forelimb function with pronation and elbow flexion was recorded in all subjects immediately postoperatively.

Four weeks postsurgery the rat pups were anesthetized again. In field sterility, the hair over the scapulae was shaved and the surgical loupes 3.5x magnification (Designs for vision, USA) were used for dissection. An incision was made over each scapula, exposing the underlying muscle but preserving the fascia to act as a seal around the injection needle. Into the angle between the body and the spina scapulae, that is, into the infraspinatus muscle, a Hamilton syringe was introduced. Ten microliters of FG 4% (Fluorochrome LLC, United States) was injected. The injection time was 1 minute per muscle to allow uniform distribution and prevent leakage. At the retraction of the needle, a cotton swab was used to prevent leakage of FG into the surrounding tissue. The wounds were closed using interrupted Prolene 7–0 sutures.

One week after the injections, the rats were deeply anesthetized. A perfusion needle was inserted into the left ventricle, the right atrium was opened, and the animals were perfused with 100-mL cold saline followed by 200-mL 4% [w/v] formaldehyde solution (Histolab, Sweden). The spine was dissected free from the paravertebral muscles and laminectomy was performed using micro-scissors. A micro-suture was attached cranial and posterior directly into the spinal cord for orientation. One group (n = 9) was marked with a surgical marker at the C5–C6 level before dissecting it free from the spinal canal. The spinal cord was lifted during meticulous dissection from the spinal canal and post fixed in 4% [w/v] formaldehyde solution.

Specimen Treatment

After 24 hours in 4% [w/v] formaldehyde, the specimens were cryoprotected in 20% sucrose solution. The specimens were frozen on dry ice, mounted, and transversally cut into 14-µm sections on a cryostat (Leica, Germany).

One group of specimens (Group I) (n = 5) was cut from C1 and as caudal as the tissue was intact (21.5 mm), for investigations of the craniocaudal extension of FG uptake. The second group of specimens (Group II) (n = 9) was sectioned through the injured C5–C6 level to provide information on differences between the sides. All sections were mounted on gelatin-coated slides and air dried.

From Group I, every fifth section was thawed for inspection of FG uptake. For Group II, every section was thawed and inspected for FG uptake.

Sixty sections from Group II (20 sections from three different animals) were stained with NeuN antibody 1:1,000 (Millipore Corporation, United States) by marking the edges of the slides with PAP PEN, re-moisturizing the specimens and applying NeuN antibody 1:1,000, phosphate buffer, and normal serum. The specimens were incubated in refrigerator for 18 hours, rinsed in phosphate buffer solution, and treated with donkey antimouse 1:400 before final rinse and covering.

The sections were examined under fluorescent microscope (Nikon Eclipse Ni-E, Nikon, Japan) and photographed using the attached camera (Andor Zyla sCMOS, Oxford Instruments, UK). For FG detection, the built-in Nikon-made DAPI filter (excitation 340–380 nm, emission 435–485 nm) was used. For NeuN detection, the bult-in Nikon-made FITC filter (excitation 465–495 nm, emission 515–555 nm) was used. The pictures were captured using NIS Elements 5.02 (Nikon). One animal specimen from group I was photographed in its entirety. These photographs were processed in Photoshop (CS5 Adobe, United States) and stitched together to a 3D model using Neurolucida (Neurolucida 360, MBF Bioscience, United States).

Statistics

All data were recorded in SPSS version 28 (IBM, United States). The normality assumption of data was tested using the Shapiro–Wilk test. The Wilcoxon signed-rank test was then used to evaluate the differences between the injured and uninjured sides. A p ≤ 0.05 was considered significant.

Results

For Group I, where a long section of the spinal cord was harvested, we saw small differences between sides in total numbers but found a wider dispersion of the FG positive cells on the injured side ([Figs. 2] and [3]).

On the injured side, we saw an average of 0.4594 (SD = 0.54617) positive cells for FG per section. For the uninjured side, there was on average 0.5230 (SD = 0.66407) positive cells for FG per section. The difference in FG positive cells per section of 0.0635 (SD = 0.44192) was not statistically significant (Z = –1.578, p = 0.115).

When comparing the sides from the Group II where C5–C6 was selected and cut, we saw significant and more concentrated differences between sides.

On the injured side, we saw an average of 0.7073 (SD = 0.71961) positive cells for FG per section. For the uninjured side, there was an average of 1.0663 (SD = 1.0663) positive cells for FG per section. The difference in FG positive cells per section of 0.3590 (SD = 0.77790) was statistically significant (Z = –3.912, p < 0.001; [Fig. 4]).

The average NeuN positive cells per section was 6.3123 (SD = 1.48605) and 7.0276 (SD = 2.16876) for the uninjured and injured sides, respectively. The difference in NeuN positive cells per section was not statistically significant (Z = –1.069, p = 0.285; [Fig. 4]).

Discussion

In this investigation, we have found differences in FG uptake between sides; however, statistical significance was only achieved for one group. For the other and the compiled material, no significant differences were found in the number of FG positive neurons. The null hypothesis cannot be rejected, albeit the method can be used to trace topographical reorganization in the spinal cord after nerve injury in continuity in rat neonates. This study is limited by the small number of animals, that the groups are not identical and that co contractions were not recorded. We note however that the standard deviation in FG uptake differs between sides, indicating a more dispersed innervation on the injured side. This is confirmed by ocular inspection of the specimens where the FG positive neurons on the injured side seem to be less densely packed together and dispersed over a longer area of the spinal cord ([Fig. 2]). This indicates that the total amount of FG positive cells (here representing the number of neurons in contact with the muscle) is similar on both sides, but the neurons on the uninjured side are more concentrated or closely packed together, while those on the injured side are almost as numerous but spread thinly over a larger section of the spinal cord. There are some overlaps in the craniocaudal limits of motor neuron pools of different muscles in the common rat.[18] It is, however, reasonable to expect that the wide spread of the injured sides motor neuron pool would overlap with the anatomical motor pool location of other muscles in the anterior horn. The lower amount of NeuN positive cells on the injured side shows that some neurons succumb to the injury and the deprivation of input and neurotrophic factors during the healing process.[19] [20] This was anticipated as a proportion of injured motor neurons as well as interneurons go through upregulation of apoptotic activity in rats injured at this age,[19] [21] when deprived of afferent input, neurotrophic factors from contact with the periphery, or a combination thereof. The apoptotic upregulation can be partly inhibited by providing the neurons with neurotrophic factors.[20]

The differences in absolute numbers between sides, although statistically significant, are small, and the number of specimens is limited. The groups of animals are not size-matched, and we interpret our results with great caution. We have, however, shown a trend toward a different anatomical dispersion after injury and that this is a viable method to study the regeneration of nerve paths in neurologically developing rat neonates, giving opportunity to further study not only BPBP but also other afflictions of the locomotor system in young individuals.

Similar investigations on nerve injuries in continuity on very young individuals have, to our knowledge, not been performed earlier. When looking for a model to investigate cocontractions in very young individuals sustaining nerve injury in continuity, we had no prior knowledge of the origin of the cocontraction.

Two main theories behind cocontractions can be postulated. It may be a central mechanism originating in the motor cortex that is disorganized. This would then presumably be due to lack of continuous contact with the periphery. Something similar to that seen in adult rats with nerve stem injuries, the normal architecture of the motor cortex is disrupted.[22] It may also be a peripheral mechanism originating from crisscross reinnervation inside a neuroma in continuity, for example, axons growing from neurons in the motor pool supplying the infraspinatus muscle ending up exerting motor control to the supraspinatus or the subscapularis muscle and therefore upon activation produce contractions in two or several antagonistic muscles at the same time.

The adult brain has enough plasticity to achieve some control over the sensation from a limb or a part of a limb with a severed nerve stem,[23] and children usually have better results after traumatic nerve injuries.[24] So why does this not apply to BPBP? In these injuries, results depend on the plasticity of the brain, that is, the ability to relearn a new pattern of activation. BPBP occurs at birth, causing a lack of input to a brain that is maturing very fast. We know that visual input is crucial during some development stages for visual cortex development.[25] Similarly a maturing motor cortex on the affected side in BPBP may not get the chance to develop the correct organization for activation.

Motor neurons depend for their survival on signals from their vast network of synapses and support tissue. In newborn animals, especially, an injury to the axon may compromise the survival of the neuron, while the mature neuron is more resilient to injury.[19] [26] An injured motor neuron sets off a cascade of signaling and protein fabrication to change from the normal state to a producer of a new axon. Cell preservation proteins such as BDNF and axonal growth proteins like GAP-43 are produced in increasing quantities.[26] Cell adhesion proteins are upregulated by the proximal stumps' contact with the periphery; adhesion proteins, like the survivability after nerve injury, change depending on age at injury.[27]

We interpret the wider dispersion on the injured side as FG being transported retrogradely through the axons, which at the point of the neuroma take a different path toward the spinal cord, much like a train going through a switch ending up at a different track. This might cause a cocontraction if several muscles were involved, and this was what Roth suggested following electrophysiological investigations.[9] However, we see the same phenomenon of faulty reinnervation in all nerve stem injuries.[23] These patients may experience transient cocontractions during rehabilitation, but, to the best of our knowledge, they do not persist in nerve stem injuries in children or adults.[24]

The phenomenon of persisting cocontractions in BPBP and the reason for the difference in nerve stem injuries in older children merits further study, and we see multiple routes ahead. The presence and frequency of cocontractions in BPBP model rat neonates should be recorded using continuously surveilling electromyography. Any further animal model should also correlate the expression of cell regenerating proteins to the degree of function/contracture and the presence of cocontractions, and to the degree of dispersion outside the normal motor pool distribution. Further elucidation of the mechanisms behind cocontractions could help in developing specific treatments for this subgroup of patients, surgically and/or more targeted rehabilitation programs.

Conflict of Interest

None declared.

• References

• 1 Lagerkvist AL, Johansson U, Johansson A, Bager B, Uvebrant P. Obstetric brachial plexus palsy: a prospective, population-based study of incidence, recovery, and residual impairment at 18 months of age. Dev Med Child Neurol 2010; 52 (06) 529-534
  CrossrefPubMedGoogle Scholar
• 2 Buterbaugh KL, Shah AS. The natural history and management of brachial plexus birth palsy. Curr Rev Musculoskelet Med 2016; 9 (04) 418-426
  CrossrefPubMedGoogle Scholar
• 3 Hultgren T, Jönsson K, Pettersson H, Hammarberg H. Surgical correction of a rotational deformity of the shoulder in patients with obstetric brachial plexus palsy: short-term results in 270 patients. Bone Joint J 2013; 95-B (10) 1432-1438
  CrossrefPubMedGoogle Scholar
• 4 Hultgren T, Jönsson K, Roos F, Järnbert-Pettersson H, Hammarberg H. Surgical correction of shoulder rotation deformity in brachial plexus birth palsy: long-term results in 118 patients. Bone Joint J 2014; 96-B (10) 1411-1418
  CrossrefPubMedGoogle Scholar
• 5 Jönsson K, Werner M, Roos F, Hultgren T. Development of the glenohumeral joint after subscapular release and open relocation in children with brachial plexus birth palsy: long-term results in 61 patients. J Shoulder Elbow Surg 2019; 28 (10) 1983-1990
  CrossrefPubMedGoogle Scholar
• 6 Whitman R. VIII. The Treatment of Congenital and Acquired Luxations at the Shoulder in Childhood. Ann Surg 1905; 42 (01) 110-115
  CrossrefPubMedGoogle Scholar
• 7 Jönsson K, Roos F, Hultgren T. Structures contributing to the shoulder contracture in brachial plexus birth palsy. An intraoperative biomechanical study. J Hand Surg Eur Vol 2022; 47 (03) 237-242
  CrossrefPubMedGoogle Scholar
• 8 Rollnik JD, Hierner R, Schubert M. et al. Botulinum toxin treatment of cocontractions after birth-related brachial plexus lesions. Neurology 2000; 55 (01) 112-114
  CrossrefPubMedGoogle Scholar
• 9 Roth G. Reinnervation in obstetrical brachial plexus paralysis. J Neurol Sci 1983; 58 (01) 103-115
  CrossrefPubMedGoogle Scholar
• 10 Overbeek CL, Kolk A, Nagels J. et al. Increased co-contraction of arm adductors is associated with a favorable course in subacromial pain syndrome. J Shoulder Elbow Surg 2018; 27 (11) 1925-1931
  CrossrefPubMedGoogle Scholar
• 11 Buchanan PJ, Grossman JAI, Price AE, Reddy C, Chopan M, Chim H. The use of botulinum toxin injection for brachial plexus birth injuries: a systematic review of the literature. Hand (N Y) 2019; 14 (02) 150-154
  CrossrefPubMedGoogle Scholar
• 12 Bertelli JA, Mira JC, Gilbert A, Michot GA, Legagneux J. Anatomical basis of rat brachial plexus reconstruction. Surg Radiol Anat 1992; 14 (01) 85-86
  CrossrefPubMedGoogle Scholar
• 13 Crouch DL, Hutchinson ID, Plate JF. et al. Biomechanical basis of shoulder osseous deformity and contracture in a rat model of brachial plexus birth palsy. J Bone Joint Surg Am 2015; 97 (15) 1264-1271
  CrossrefPubMedGoogle Scholar
• 14 Mascarenhas VV, Casaccia M, Fernandez-Martin A. et al. The role of subscapularis muscle denervation in the pathogenesis of shoulder internal rotation contracture after neonatal brachial plexus palsy: a study in a rat model. J Orthop Res 2014; 32 (12) 1675-1679
  CrossrefPubMedGoogle Scholar
• 15 Schmued LC, Fallon JH. Fluoro-Gold: a new fluorescent retrograde axonal tracer with numerous unique properties. Brain Res 1986; 377 (01) 147-154
  CrossrefPubMedGoogle Scholar
• 16 Mazzer PY, Barbieri CH, Mazzer N, Fazan VP. Morphologic and morphometric evaluation of experimental acute crush injuries of the sciatic nerve of rats. J Neurosci Methods 2008; 173 (02) 249-258
  CrossrefPubMedGoogle Scholar
• 17 Bridge PM, Ball DJ, Mackinnon SE. et al. Nerve crush injuries: a model for axonotmesis. Exp Neurol 1994; 127 (02) 284-290
  CrossrefPubMedGoogle Scholar
• 18 Tosolini AP, Morris R. Spatial characterization of the motor neuron columns supplying the rat forelimb. Neuroscience 2012; 200: 19-30
  CrossrefPubMedGoogle Scholar
• 19 Lowrie MB, Vrbová G. Repeated injury to the sciatic nerve in immature rats causes motoneuron death and impairs muscle recovery. Exp Neurol 2001; 171 (01) 170-175
  CrossrefPubMedGoogle Scholar
• 20 Oliveira AL, Risling M, Negro A, Langone F, Cullheim S. Apoptosis of spinal interneurons induced by sciatic nerve axotomy in the neonatal rat is counteracted by nerve growth factor and ciliary neurotrophic factor. J Comp Neurol 2002; 447 (04) 381-393
  CrossrefPubMedGoogle Scholar
• 21 Oliveira AL, Risling M, Deckner M, Lindholm T, Langone F, Cullheim S. Neonatal sciatic nerve transection induces TUNEL labeling of neurons in the rat spinal cord and DRG. Neuroreport 1997; 8 (13) 2837-2840
  CrossrefPubMedGoogle Scholar
• 22 Sanes JN, Suner S, Donoghue JP. Dynamic organization of primary motor cortex output to target muscles in adult rats. I. Long-term patterns of reorganization following motor or mixed peripheral nerve lesions. Exp Brain Res 1990; 79 (03) 479-491
  CrossrefPubMedGoogle Scholar
• 23 Dahlin LB, Wiberg M. Nerve injuries of the upper extremity and hand. EFORT Open Rev 2017; 2 (05) 158-170
  CrossrefPubMedGoogle Scholar
• 24 Chemnitz A, Björkman A, Dahlin LB, Rosén B. Functional outcome thirty years after median and ulnar nerve repair in childhood and adolescence. J Bone Joint Surg Am 2013; 95 (04) 329-337
  CrossrefPubMedGoogle Scholar
• 25 Blakemore C, Garey LJ, Vital-Durand F. The physiological effects of monocular deprivation and their reversal in the monkey's visual cortex. J Physiol 1978; 283: 223-262
  CrossrefPubMedGoogle Scholar
• 26 Carlstedt T, Cullheim S. Spinal cord motoneuron maintenance, injury and repair. Prog Brain Res 2000; 127: 501-514
  CrossrefPubMedGoogle Scholar
• 27 Hammarberg H, Wallquist W, Piehl F, Risling M, Cullheim S. Regulation of laminin-associated integrin subunit mRNAs in rat spinal motoneurons during postnatal development and after axonal injury. J Comp Neurol 2000; 428 (02) 294-304
  CrossrefPubMedGoogle Scholar

Address for correspondence

Publication History

Received: 21 June 2023

Accepted: 12 December 2023

Article published online:
22 January 2024

© 2024. The Author(s). This is an open access article published by Thieme under the terms of the Creative Commons Attribution License, permitting unrestricted use, distribution, and reproduction so long as the original work is properly cited. (https://creativecommons.org/licenses/by/4.0/)

Georg Thieme Verlag KG
Rüdigerstraße 14, 70469 Stuttgart, Germany

• References

• 1 Lagerkvist AL, Johansson U, Johansson A, Bager B, Uvebrant P. Obstetric brachial plexus palsy: a prospective, population-based study of incidence, recovery, and residual impairment at 18 months of age. Dev Med Child Neurol 2010; 52 (06) 529-534
  CrossrefPubMedGoogle Scholar
• 2 Buterbaugh KL, Shah AS. The natural history and management of brachial plexus birth palsy. Curr Rev Musculoskelet Med 2016; 9 (04) 418-426
  CrossrefPubMedGoogle Scholar
• 3 Hultgren T, Jönsson K, Pettersson H, Hammarberg H. Surgical correction of a rotational deformity of the shoulder in patients with obstetric brachial plexus palsy: short-term results in 270 patients. Bone Joint J 2013; 95-B (10) 1432-1438
  CrossrefPubMedGoogle Scholar
• 4 Hultgren T, Jönsson K, Roos F, Järnbert-Pettersson H, Hammarberg H. Surgical correction of shoulder rotation deformity in brachial plexus birth palsy: long-term results in 118 patients. Bone Joint J 2014; 96-B (10) 1411-1418
  CrossrefPubMedGoogle Scholar
• 5 Jönsson K, Werner M, Roos F, Hultgren T. Development of the glenohumeral joint after subscapular release and open relocation in children with brachial plexus birth palsy: long-term results in 61 patients. J Shoulder Elbow Surg 2019; 28 (10) 1983-1990
  CrossrefPubMedGoogle Scholar
• 6 Whitman R. VIII. The Treatment of Congenital and Acquired Luxations at the Shoulder in Childhood. Ann Surg 1905; 42 (01) 110-115
  CrossrefPubMedGoogle Scholar
• 7 Jönsson K, Roos F, Hultgren T. Structures contributing to the shoulder contracture in brachial plexus birth palsy. An intraoperative biomechanical study. J Hand Surg Eur Vol 2022; 47 (03) 237-242
  CrossrefPubMedGoogle Scholar
• 8 Rollnik JD, Hierner R, Schubert M. et al. Botulinum toxin treatment of cocontractions after birth-related brachial plexus lesions. Neurology 2000; 55 (01) 112-114
  CrossrefPubMedGoogle Scholar
• 9 Roth G. Reinnervation in obstetrical brachial plexus paralysis. J Neurol Sci 1983; 58 (01) 103-115
  CrossrefPubMedGoogle Scholar
• 10 Overbeek CL, Kolk A, Nagels J. et al. Increased co-contraction of arm adductors is associated with a favorable course in subacromial pain syndrome. J Shoulder Elbow Surg 2018; 27 (11) 1925-1931
  CrossrefPubMedGoogle Scholar
• 11 Buchanan PJ, Grossman JAI, Price AE, Reddy C, Chopan M, Chim H. The use of botulinum toxin injection for brachial plexus birth injuries: a systematic review of the literature. Hand (N Y) 2019; 14 (02) 150-154
  CrossrefPubMedGoogle Scholar
• 12 Bertelli JA, Mira JC, Gilbert A, Michot GA, Legagneux J. Anatomical basis of rat brachial plexus reconstruction. Surg Radiol Anat 1992; 14 (01) 85-86
  CrossrefPubMedGoogle Scholar
• 13 Crouch DL, Hutchinson ID, Plate JF. et al. Biomechanical basis of shoulder osseous deformity and contracture in a rat model of brachial plexus birth palsy. J Bone Joint Surg Am 2015; 97 (15) 1264-1271
  CrossrefPubMedGoogle Scholar
• 14 Mascarenhas VV, Casaccia M, Fernandez-Martin A. et al. The role of subscapularis muscle denervation in the pathogenesis of shoulder internal rotation contracture after neonatal brachial plexus palsy: a study in a rat model. J Orthop Res 2014; 32 (12) 1675-1679
  CrossrefPubMedGoogle Scholar
• 15 Schmued LC, Fallon JH. Fluoro-Gold: a new fluorescent retrograde axonal tracer with numerous unique properties. Brain Res 1986; 377 (01) 147-154
  CrossrefPubMedGoogle Scholar
• 16 Mazzer PY, Barbieri CH, Mazzer N, Fazan VP. Morphologic and morphometric evaluation of experimental acute crush injuries of the sciatic nerve of rats. J Neurosci Methods 2008; 173 (02) 249-258
  CrossrefPubMedGoogle Scholar
• 17 Bridge PM, Ball DJ, Mackinnon SE. et al. Nerve crush injuries: a model for axonotmesis. Exp Neurol 1994; 127 (02) 284-290
  CrossrefPubMedGoogle Scholar
• 18 Tosolini AP, Morris R. Spatial characterization of the motor neuron columns supplying the rat forelimb. Neuroscience 2012; 200: 19-30
  CrossrefPubMedGoogle Scholar
• 19 Lowrie MB, Vrbová G. Repeated injury to the sciatic nerve in immature rats causes motoneuron death and impairs muscle recovery. Exp Neurol 2001; 171 (01) 170-175
  CrossrefPubMedGoogle Scholar
• 20 Oliveira AL, Risling M, Negro A, Langone F, Cullheim S. Apoptosis of spinal interneurons induced by sciatic nerve axotomy in the neonatal rat is counteracted by nerve growth factor and ciliary neurotrophic factor. J Comp Neurol 2002; 447 (04) 381-393
  CrossrefPubMedGoogle Scholar
• 21 Oliveira AL, Risling M, Deckner M, Lindholm T, Langone F, Cullheim S. Neonatal sciatic nerve transection induces TUNEL labeling of neurons in the rat spinal cord and DRG. Neuroreport 1997; 8 (13) 2837-2840
  CrossrefPubMedGoogle Scholar
• 22 Sanes JN, Suner S, Donoghue JP. Dynamic organization of primary motor cortex output to target muscles in adult rats. I. Long-term patterns of reorganization following motor or mixed peripheral nerve lesions. Exp Brain Res 1990; 79 (03) 479-491
  CrossrefPubMedGoogle Scholar
• 23 Dahlin LB, Wiberg M. Nerve injuries of the upper extremity and hand. EFORT Open Rev 2017; 2 (05) 158-170
  CrossrefPubMedGoogle Scholar
• 24 Chemnitz A, Björkman A, Dahlin LB, Rosén B. Functional outcome thirty years after median and ulnar nerve repair in childhood and adolescence. J Bone Joint Surg Am 2013; 95 (04) 329-337
  CrossrefPubMedGoogle Scholar
• 25 Blakemore C, Garey LJ, Vital-Durand F. The physiological effects of monocular deprivation and their reversal in the monkey's visual cortex. J Physiol 1978; 283: 223-262
  CrossrefPubMedGoogle Scholar
• 26 Carlstedt T, Cullheim S. Spinal cord motoneuron maintenance, injury and repair. Prog Brain Res 2000; 127: 501-514
  CrossrefPubMedGoogle Scholar
• 27 Hammarberg H, Wallquist W, Piehl F, Risling M, Cullheim S. Regulation of laminin-associated integrin subunit mRNAs in rat spinal motoneurons during postnatal development and after axonal injury. J Comp Neurol 2000; 428 (02) 294-304
  CrossrefPubMedGoogle Scholar