Medical/biological study (experimental study)

Iron oxide nanoparticles and magnetic field exposure promote functional recovery by attenuating free radical-induced damage in rats with spinal cord transection med./bio.

By: Pal A, Singh A, Nag TC, Chattopadhyay P, Mathur R, Jain S

Published in: Int J Nanomedicine 2013; 8: 2259-2272

Aim of study (acc. to author)

The effects of co-exposure of rats with spinal cord transection to a 50 Hz magnetic field and iron oxide nanoparticles on the functional recovery of spinal cord transection should be investigated.

Background/further details

For the in vivo tests, rats were divided into 4 groups: 1) spinal cord transection only (n=10), 2) spinal cord transection and implantation of iron oxide nanoparticles at the site of injury (n=7), 3) spinal cord transection and exposure to the magnetic field (n=8) and 4) spinal cord transection and nanoparticles implantation and magnetic field exposure (n=14). Exposure to the magnetic field started 24 hours after spinal cord transection. After 5 weeks, animals were killed and histological examinations were conducted.

Endpoint

effects on the neurological system: functional recovery and structure of spinal cord transection in rats

Exposure

- 50 Hz
- 50/60 Hz
- magnetic field
- co-exposure

Exposure	Parameters
Exposure 1: 50 Hz Exposure duration: continuous for 2 hours/day for 5 weeks	magnetic flux density: 17.96 µT

Exposure 1

Main characteristics

Frequency	50 Hz
Type	magnetic field
Exposure duration	continuous for 2 hours/day for 5 weeks

Exposure setup

Exposure source	coil(s)
Setup	rats were kept in a Plexiglas enclosure placed on a wooden platform in the middle of the exposure chamber; two pairs of circular coils of equal diameter (1 m, turn ratio of 9/4/4/9) wound on the same cylindrical surface created a uniform magnetic field in the chamber

Parameters

Measurand	Value	Type	Method	Mass	Remarks
magnetic flux density	17.96 µT	-	-	-	-

Additional parameter details

current ratio between the outer and inner pairs of coils was 2.2604 (A?)

Reference articles

Kirschvink JL (1992): Uniform magnetic fields and double-wrapped coil systems: improved techniques for the design of bioelectromagnetic experiments

Exposed system:

animal
rat/Wistar albino
whole body

Methods Endpoint/measurement parameters/methodology

morphol./histopathol. changes: total area damaged (cresyl violet staining), localization of iron oxide nanoparticles in tissue (Prussian blue staining), identification of collagenous connective tissue (Masson's trichrome staining) (microscopy); localization of iron oxide nanoparticles in cells (uranyl acetate and lead citrate staining, transmission electron microscopy) in tissue slices
effects on the neurological system: hind limb function (once a week; open field test, locomotor rating scale), balance and coordinate stepping (3 times/week; time until fall from moving wheel), sensitivity to noxious thermal stimuli (once every 2 weeks; latency of hind paw withdrawal from hot plate), urinary bladder function (once a day; ability to evacuate bladder autonomously)
food intake, water intake, body mass

Investigated system:

intact cell/cell culture
tissue slices
spinal cord
investigation on living organism

Investigated organ system:

brain/CNS

Time of investigation:

before exposure
during exposure
after exposure

Main outcome of study (acc. to author)

Locomotor, sensory and autonomic functions were significantly enhanced in group 4 (iron oxide nanoparticles and magnetic field exposure) compared to groups 1-3.
Histology demonstrated significant recovery of tissue and a reduction in lesion volume in group 4 compared to the other groups. No collagenous scar was observed in this group and nanoparticles were localized intracellularly in the immediate vicinity of the lesion.
The authors conclude that co-exposure of rats with spinal cord transection to a 50 Hz magnetic field and iron oxide nanoparticles might improve the functional recovery of spinal cord transection, what indicates a possible therapeutic use.

Study character:

medical/biological study
experimental study
full/main study
blind study

Study funded by

All India Institute of Medical Science Institute (AIIMS), India

Bhattacharyya S et al. (2020): Effect of Low Intensity Magnetic Field Stimulation on Calcium-Mediated Cytotoxicity After Mild Spinal Cord Contusion Injury in Rats
Grant DN et al. (2015): In vitro electromagnetic stimulation to enhance cell proliferation in extracellular matrix constructs with and without metallic nanoparticles
Choi YK et al. (2014): Stimulation of neural differentiation in human bone marrow mesenchymal stem cells by extremely low-frequency electromagnetic fields incorporated with MNPs
Kumar S et al. (2013): Exposure to extremely low-frequency magnetic field restores spinal cord injury-induced tonic pain and its related neurotransmitter concentration in the brain
Das S et al. (2012): Exposure to ELF- magnetic field promotes restoration of sensori-motor functions in adult rats with hemisection of thoracic spinal cord
Kumar S et al. (2010): Effect of magnetic field on food and water intake and body weight of spinal cord injured rats