Lidya Maltz

Promotion of bone repair in the cortical bone of the tibia in rats by low energy laser (He-Ne) irradiation.

Abstract. The effect of low energy laser (He-Ne) irradiation on bone repair in the cortical part of the tibia of the rat was investigated using biochemical and radioactive labeling methods. A fixed round hole was created in the lateral aspect of the tibia and the newly formed tissue was collected from the gap in the cortical bone. Alkaline phosphatase (ALP) and calcium progressively accumulated at the site of injury, peaking at 9 and 13 days postinjury, respectively. Direct irradiation of the hole injury with He-Ne laser on days 5 and 6 postinjury altered osteoblastic activity at the injured site as reflected by alkaline phosphatase activity. The laser irradiation also caused a significant increase (∼2-fold) in calcium accumulation at the site of injury for 9–18 days postinjury. The rate of calcium deposition, measured by radioactive calcium, was significantly higher (∼2-fold) in the laser-irradiated rats as compared with controls. It is concluded that the process of bone repair in a hole created in the rat tibia is markedly enhanced by direct He-Ne laser irradiation of the injured site at the optimal energy level and time postinjury.

Induction of autologous mesenchymal stem cells in the bone marrow by low-level laser therapy has profound beneficial effects on the infarcted rat heart

The adult mammalian heart is known to have a very limited regenerative capacity following acute ischemia. In this study we investigated the hypothesis that photobiostimulation of autologous bone‐marrow‐derived mesenchymal stem cells (MSCs) by low‐level laser therapy (LLLT) applied to the bone marrow (BM), may migrate to the infarcted area and thus attenuate the scarring processes following myocardial infarction (MI).

Promotion of Angiogenesis by Low Energy Laser Irradiation

The effect of low energy laser (He-Ne) irradiation (LELI) on the process of angiogenesis in the infarcted rat heart and in the chick chorioallantoic membrane (CAM), as well as the proliferation of endothelial cells in tissue culture, was investigated. Formation of new blood vessels in the infarcted rat heart was monitored by counting proliferating endothelial cells in blood vessels. In the CAM model, defined areas were laser-irradiated or nonirradiated and blood vessel density was recorded in each site in the CAM at various time intervals. Laser irradiation caused a 3.1-fold significant increase in newly formed blood vessels 6 days post infarction, as compared with nonirradiated rats. In the CAM model, a slight inhibition of angiogenesis up to 2 days post irradiation and a significant enhancement of angiogenesis in the laser-irradiated foci as compared with control nonirradiated spots were evident. The LELI caused a 1.8-fold significant increase in the rate of proliferation in endothelial cells in culture over nonirradiated cells. It is concluded that LELI can promote the proliferation of endothelial cells in culture, which may partially explain the augmentation of angiogenesis in the CAM model and in the infarcted heart. These results may have clinical significance by offering therapeutic options to ameliorate angiogenesis in ischemic conditions.

Long-Term Safety of Low-Level Laser Therapy at Different Power Densities and Single or Multiple Applications to the Bone Marrow in Mice

OBJECTIVE The purpose of this study was to determine the long-term safety effect of low-level laser therapy (LLLT) to the bone marrow (BM) in mice. BACKGROUND DATA LLLT has been shown to have a photobiostimulatory effect on various cellular processes and on stem cells. It was recently shown that applying LLLT to BM in rats post-myocardial infarction caused a marked reduction of scar tissue formation in the heart. METHODS Eighty-three mice were divided into five groups: control sham-treated and laser-treated at measured density of either 4, 10, 18, or 40 mW/cm(2) at the BM level. The laser was applied to the exposed flat medial part of the tibia 8 mm from the knee joint for 100 sec. Mice were monitored for 8 months and then killed, and histopathology was performed on various organs. RESULTS No histological differences were observed in the liver, kidneys, brain or BM of the laser-treated mice as compared with the sham-treated, control mice. Moreover, no neoplasmic response in the tissues was observed in the laser-treated groups as compared with the control, sham-treated mice. There were no significant histopathological differences among the same organs under different laser treatment regimes in response to the BM-derived mesenchymal stem cell proliferation following LLLT to the BM. CONCLUSIONS LLLT applied multiple times either at the optimal dose (which induces photobiostimulation of stem cells in the BM), or at a higher dose (such as five times the optimal dose), does not cause histopathological changes or neoplasmic response in various organs in mice, as examined over a period of 8 months.

Autologous Bone-Marrow Stem Cells Stimulation Reverses Post-Ischemic-Reperfusion Kidney Injury in Rats

Background/Aims: Low-level laser therapy (LLLT) has been found to modulate biological activity. The aim of the present study was to investigate the possible beneficial effects of LLLT application to stem cells in the bone marrow (BM), on the kidneys of rats that had undergone acute ischemia-reperfusion injury (IRI). Methods: Injury to the kidneys was induced by the excision of the left kidney and 60 min of IRI to the right kidney in each rat. Rats were then divided randomly into 2 groups: non-laser-treated and laser-treated. LLLT was applied to the BM 10 min and 24 h post-IRI and rats were sacrificed 4 days post-IRI. Blood was collected before the sacrifice and the kidney processed for histology. Results: Histological evaluation of kidney sections revealed the restored structural integrity of the renal tubules, and a significant reduction of 66% of pathological score in the laser-treated rats as compared to the non-laser-treated ones. C-kit positive cell density in kidneys post-IRI and laser-treatment was (p = 0.05) 2.4-fold higher compared to that of the non-laser treated group. Creatinine, blood urea nitrogen, and cystatin-C levels were significantly 55, 48, and 25% lower respectively in the laser-treated rats as compared to non-treated ones. Conclusion: LLLT application to the BM causes induction of stem cells, which subsequently migrate and home in on the injured kidney. Consequently, a significant reduction in pathological features and improved kidney function post-IRI are evident. The results demonstrate a novel approach in cell-based therapy for acute ischemic injured kidneys. i 2014 S. Karger AG, Basel

Histology and Enzymatic Activity in the Postnatal Development of Limb Muscles in Rodents

The present work examines how increases in spontaneous motor capabilities during postnatal development are reflected in enzymatic activity and the histology of hindlimb muscles of the dormouse (Eliomys melanurus), the jird (Meriones tristrami), the vole (Microtus socialis), and the spiny mouse (Acomys cahirinus). The precocial neonate of the spiny mouse had the most advanced developmental state of young myofibers with striations as early as 1 week after delivery. At the same age, the altricial neonate vole had less developed muscles compared to the spiny mouse, but was more mature compared to other altricial species. The dormouse was the least developed, with numerous myoblasts and few myotubes at 1 week after delivery. These differences in myogenic development were conspicuous throughout postnatal development. Similar differences between the species were also evident at the biochemical level, as measured in the kinetics of activity of the enzyme creatine-phosphokinase immediately after delivery. On postnatal day 7, the creatine-phosphokinase level in the spiny mouse was fourfold higher than in the dormouse or vole. The enzymatic activity of acid phosphatase decreased during the first week postdelivery in the spiny mouse while peaking in the first, second, and third week in the jird, vole, and dormouse, respectively. These results support the notion that precocial species undergo certain developmental stages in utero, whereas, the same stages commence in altricials only postnatally. For the tested altricial species, the results illustrate that limb muscles in the vole, which displays more basic gaits, mature before limb muscles of the jird and dormouse, which display more specialized gaits.