Infra-red (IR) laser therapy has a good reputation for healing and regeneration of damaged tissue. Many clinics in the US and Canada utilize this modality for treating arthritis (painful joints). This method has nearly no side effects if properly used. Indeed, it is very effective if the affected lesion is superficial or very near to the skin. Unfortunately, this method has a critical drawback. Its penetration capacity is limited to about 3.5 cm. Therefore, any lesion deeper than that, the treatment becomes useless. Granted US patents had been issued to solve that problem. These patents include (US 9795802, US 9579520, US9433798). They invented a long-beveled needle that could bypass the skin, subcutaneous tissues, muscle layer (s) if is present, and any other intervening tissues. The laser beam goes directly to the exact site of the lesion. Thus, they solved the problem of the prior art of infrared laser therapy. This also means the full amount of IR laser energy is saved from being lost in the skin and/or any other intervening tissue between the skin and the lesion. This new modality can cure the deep-seated and damaged tissues of the orthopedic system without any side effects if properly used. Therefore. the medication and surgery which are the main lines of treatment of orthopedic diseases could be avoided or at least reduced to the minimum. Lastly, this novel method is essential for the group of patients who are inoperable or are in their end-stage. Examples of these patients include end-stage renal failure, hepatic failure, heart failure, or stage IV of metastatic cancer. These patients may be in a severely painful condition because of arthritis but surgery and/or medication may not be allowed.
| Published in | Frontiers (Volume 2, Issue 1) |
| DOI | 10.11648/j.frontiers.20220201.16 |
| Page(s) | 57-67 |
| Creative Commons |
This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited. |
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Copyright © The Author(s), 2024. Published by Science Publishing Group |
Infrared Laser, Visceral Fat, Osteoarthritis, Osteomyelitis, Lumbar Disc, AVN
| [1] | Jan Mbjordal, 2003. A systematic review of low level laser therapy with location-specific doses for pain from chronic joint disorders. Australian Journal of Physiotherapy. Volume 49, Issue 2, Pages 107-116. |
| [2] | Caerwyn Ash. 2017. Effect of wavelength and beam width on penetration in light-tissue interaction using computational methods. Lasers Med Sci. Volume 32 (8): 1909–1918. |
| [3] | Ayan Barbora. 2021. Higher pulse frequency of near-infrared laser irradiation increases penetration depth for novel biomedical applications. PLoS One. Volume 16 (1): e0245350 pages (1-11). |
| [4] | Danhong Han. 2018. Penetrating effect of high-intensity infrared laser pulses through body tissue†. RSC Advances. Volume 8. Pages (32344-32357). |
| [5] | Ju Hee Lee. 2006. Effects of Infrared Radiation on Skin Photo-Aging and Pigmentation. Yonsei Med J. volume 47 (4): 485–490. |
| [6] | Hossam Mohamed, 2017. Method of orthopedic treatment by radiation. US9579520. |
| [7] | Hossam Mohamed, 2017. Method of orthopedic treatment by radiation. US9795802. |
| [8] | Hossam Mohamed, 2017. Method of treating fat of a patient by Radiation. US9433798. |
| [9] | Julie A. Reisz. 2014. Effects of Ionizing Radiation on Biological Molecules—Mechanisms of Damage and Emerging Methods of Detection. Antioxidants & Redox SignalingVol. 21, No. 2. Pages 260-292. |
| [10] | Igor Koturbash, 2017. LINE-1 in response to exposure to ionizing radiation. Mob Genet Elements. volume 7 (6): e1393491. Pages (1-5). |
| [11] | Aleksandra Cios. 2021. Effect of Different Wavelengths of Laser Irradiation on the Skin Cells. Int J Mol Sci.; 22 (5): 2437. Pages (1-18). |
| [12] | Pinar Avci, 2013. Low-level laser (light) therapy (LLLT) in skin: stimulating, healing, restoring. Semin Cutan Med Surg. volume 32 (1): 41–52. |
| [13] | Stefano Benedicenti, 2008. Intracellular ATP level increases in lymphocytes irradiated with infrared laser light of wavelength 904 nm. Photomed Laser Surg. Volume; 26 (5): 451-453. |
| [14] | Cleber Ferrares, 2015. Low-level laser (light) therapy increases mitochondrial membrane potential and ATP synthesis in C2C12 myotubes with a peak response at 3-6 hours. Photochem Photobiol. Volume 91 (2): 411–416. |
| [15] | Tetsuya Kawane. 2018. Runx2 is required for the proliferation of osteoblast progenitors and induces proliferation by regulating Fgfr2 and Fgfr3. Scientific Reports volume 8, Article number: 13551. Pages (1-17). |
| [16] | Michael Jackson. 2015. Characterizing Far-infrared Laser Emissions and the Measurement of Their Frequencies. J Vis Exp. 2015; (106): 53399. Pages (1-15). |
| [17] | Guy C Brown. 2007. Nitric oxide and mitochondria. Frontiers in Bioscience-Landmark. Volume 12. Issue 3. Page 1024-1033. |
| [18] | Jorge D. 2007. Nitric Oxide and Mitochondrial Signaling. Arteriosclerosis, Thrombosis, and Vascular Biology. volume 27 (12). Pages 2524–2531. |
| [19] | J R de Berrazueta. 1999. The nobel prize for nitric oxide. the unjust exclusion of Dr. Salvador Moncada. Revista Española de Cardiología. Volume 52, Issue 4, 1999, Pages 221-226. |
| [20] | Agnes Keszler. 2017. Red/Near Infrared Light Stimulates Release of an Endothelium Dependent Vasodilator and Rescues Vascular Dysfunction in a Diabetes Model Free Radic Biol Med.; volume 113: Pages 157–164. |
| [21] | Lauren K Meyer. 2013. Adipose tissue depot and cell size dependency of adiponectin synthesis and secretion in human obesity. Adipocyte; 2 (4): 217–226. |
| [22] | YuchangFu. 2005. Adiponectin promotes adipocyte differentiation, insulin sensitivity, and lipid accumulation. Journal of Lipid Research. Volume 46, Issue 7, Pages 1369-1379. |
| [23] | S W Coppack. 2001. Pro-inflammatory cytokines and adipose tissue. Proc Nutr Soc. Volume 60 (3): 349-56. |
| [24] | Natalya V. Andreeva. 2019. Effects of infrared laser irradiation on aging of mesenchymal stem cells in culture. Optical Engineering, 59 (6), e061607. |
| [25] | Khatereh Khorsandi. 2020. Biological Responses of Stem Cells to Photobiomodulation Therapy. Curr Stem Cell Research Therapy.; 15 (5): 400-413. |
| [26] | Xuanfang Zhou. 2020. Near-Infrared Light-Responsive Nitric Oxide Delivery Platform for Enhanced Radioimmunotherapy. Nano Micro Letters. Volume 12. e100. Pages (1-14). |
| [27] | Seonhee Kim. 2019. Far-Infrared-Emitting Sericite Board Upregulates Endothelial Nitric Oxide Synthase Activity through Increasing Biosynthesis of Tetrahydrobiopterin in Endothelial Cells. Hindawi. Evidence-Based Complementary and Alternative Medicine. Volume 2019. e1813282, Pages (1-9). |
| [28] | Béla Hegedűs, 2009. The Effect of Low-Level Laser in Knee Osteoarthritis: A Double-Blind, Randomized, Placebo-Controlled Trial. Photomed Laser Surg. volume 27 (4): 577–584. |
| [29] | Zaid Jibri. 2019. Patellar maltracking: an update on the diagnosis and treatment strategies. Insights Imaging. Volume 10: (65). Pages (1-11). |
| [30] | Shengjuan Wei. 2014. Emerging roles of zinc finger proteins in regulating adipogenesis. Cellular and Molecular Life Sciences volume 70, pages 4569–4584. |
| [31] | Ali Akbar Jafarian. 2018. Clinical and Radiographic Alterations in Bilateral Avascular Necrosis of the Femoral Head Following Laser Acupuncture: A Case Report. J Lasers Med Sci.; volume 9 (2): 149–153. |
| [32] | Göksel Şimşek Kaya. 2011. The use of 808-nm light therapy to treat experimental chronic osteomyelitis induced in rats by methicillin-resistant Staphylococcus aureus. Photomed Laser Surg; Volume 29 (6): 405-412. |
| [33] | George D Gale. 2006. Infrared therapy for chronic low back pain: A randomized, controlled trial. Pain Res Manag. Volume 11 (3): 193–196. |
| [34] | Nitis Reeboonlap. 2012. Outcome of plantar fasciitis treatment using monochrome infrared irradiation. J Med Assoc Thai Volume; 95 Suppl 10: pages 147-150. |
| [35] | Chin-Li Wu. 2009. The application of infrared thermography in the assessment of patients with coccygodynia before and after manual therapy combined with diathermy. J Manipulative Physiol Ther Volume 32 (4): 287-293. |
| [36] | S England. 1989. Low power laser therapy of shoulder tendonitis. Scand J Rheumatol Volume18 (6): 427-431. |
| [37] | Yan Chen. 2016. Low-power laser therapy for carpal tunnel syndrome: effective optical power. Neural Regen Res.; 11 (7): 1180–1184. |
| [38] | Jean Pascal Reynaud. 2009. Lipolysis Using a 980-nm Diode Laser: A Retrospective Analysis of 534 Procedures. Aesthetic Plast Surg. Volume 33 (1): 28–36. |
| [39] | Yun-Mi Jeong. 2017. Preconditioning with far-infrared irradiation enhances proliferation, cell survival, and migration of rat bone marrow-derived stem cells via CXCR4-ERK pathways. Sci Rep. Volume; 7: e13718. Pages 1-9. |
| [40] | Y Maegawa. 2000. Effects of near-infrared low-level laser irradiation on microcirculation. Lasers Surg Med. Volume 27 (5): 427-437. |
| [41] | Rajiah AldrinDenny. 2013. Recent developments in targeting protein misfolding diseases. Bioorganic & Medicinal Chemistry Letters. Volume 23, Issue 7, Pages 1935-1944. |
| [42] | Hossam Mohamed, 2022. Hossam Retrograde Mitochondrial-Nuclear Axis is the Hidden Secret for Rejuvenation: Granted US Patents Review. Frontiers. Volume 2, Issue 1, Pages: 34-45. |
APA Style
Hossam Mohamed, Houda Almansour, Dalal Alsaadoun, Sawsan Samy, Mariam Almansour, et al. (2022). Hossam’s Far-Infra-Red (FIR) Laser Injection Therapy Repairs & Rejuvenates of the Deep-seated Lesions of the Orthopaedic Diseases: Granted US Patents Review. Frontiers, 2(1), 57-67. https://doi.org/10.11648/j.frontiers.20220201.16
ACS Style
Hossam Mohamed; Houda Almansour; Dalal Alsaadoun; Sawsan Samy; Mariam Almansour, et al. Hossam’s Far-Infra-Red (FIR) Laser Injection Therapy Repairs & Rejuvenates of the Deep-seated Lesions of the Orthopaedic Diseases: Granted US Patents Review. Frontiers. 2022, 2(1), 57-67. doi: 10.11648/j.frontiers.20220201.16
AMA Style
Hossam Mohamed, Houda Almansour, Dalal Alsaadoun, Sawsan Samy, Mariam Almansour, et al. Hossam’s Far-Infra-Red (FIR) Laser Injection Therapy Repairs & Rejuvenates of the Deep-seated Lesions of the Orthopaedic Diseases: Granted US Patents Review. Frontiers. 2022;2(1):57-67. doi: 10.11648/j.frontiers.20220201.16
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Download@article{10.11648/j.frontiers.20220201.16,
author = {Hossam Mohamed and Houda Almansour and Dalal Alsaadoun and Sawsan Samy and Mariam Almansour and Yasmin Almansour},
title = {Hossam’s Far-Infra-Red (FIR) Laser Injection Therapy Repairs & Rejuvenates of the Deep-seated Lesions of the Orthopaedic Diseases: Granted US Patents Review},
journal = {Frontiers},
volume = {2},
number = {1},
pages = {57-67},
doi = {10.11648/j.frontiers.20220201.16},
url = {https://doi.org/10.11648/j.frontiers.20220201.16},
eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.frontiers.20220201.16},
abstract = {Infra-red (IR) laser therapy has a good reputation for healing and regeneration of damaged tissue. Many clinics in the US and Canada utilize this modality for treating arthritis (painful joints). This method has nearly no side effects if properly used. Indeed, it is very effective if the affected lesion is superficial or very near to the skin. Unfortunately, this method has a critical drawback. Its penetration capacity is limited to about 3.5 cm. Therefore, any lesion deeper than that, the treatment becomes useless. Granted US patents had been issued to solve that problem. These patents include (US 9795802, US 9579520, US9433798). They invented a long-beveled needle that could bypass the skin, subcutaneous tissues, muscle layer (s) if is present, and any other intervening tissues. The laser beam goes directly to the exact site of the lesion. Thus, they solved the problem of the prior art of infrared laser therapy. This also means the full amount of IR laser energy is saved from being lost in the skin and/or any other intervening tissue between the skin and the lesion. This new modality can cure the deep-seated and damaged tissues of the orthopedic system without any side effects if properly used. Therefore. the medication and surgery which are the main lines of treatment of orthopedic diseases could be avoided or at least reduced to the minimum. Lastly, this novel method is essential for the group of patients who are inoperable or are in their end-stage. Examples of these patients include end-stage renal failure, hepatic failure, heart failure, or stage IV of metastatic cancer. These patients may be in a severely painful condition because of arthritis but surgery and/or medication may not be allowed.},
year = {2022}
}
TY - JOUR T1 - Hossam’s Far-Infra-Red (FIR) Laser Injection Therapy Repairs & Rejuvenates of the Deep-seated Lesions of the Orthopaedic Diseases: Granted US Patents Review AU - Hossam Mohamed AU - Houda Almansour AU - Dalal Alsaadoun AU - Sawsan Samy AU - Mariam Almansour AU - Yasmin Almansour Y1 - 2022/02/25 PY - 2022 N1 - https://doi.org/10.11648/j.frontiers.20220201.16 DO - 10.11648/j.frontiers.20220201.16 T2 - Frontiers JF - Frontiers JO - Frontiers SP - 57 EP - 67 PB - Science Publishing Group SN - 2994-7197 UR - https://doi.org/10.11648/j.frontiers.20220201.16 AB - Infra-red (IR) laser therapy has a good reputation for healing and regeneration of damaged tissue. Many clinics in the US and Canada utilize this modality for treating arthritis (painful joints). This method has nearly no side effects if properly used. Indeed, it is very effective if the affected lesion is superficial or very near to the skin. Unfortunately, this method has a critical drawback. Its penetration capacity is limited to about 3.5 cm. Therefore, any lesion deeper than that, the treatment becomes useless. Granted US patents had been issued to solve that problem. These patents include (US 9795802, US 9579520, US9433798). They invented a long-beveled needle that could bypass the skin, subcutaneous tissues, muscle layer (s) if is present, and any other intervening tissues. The laser beam goes directly to the exact site of the lesion. Thus, they solved the problem of the prior art of infrared laser therapy. This also means the full amount of IR laser energy is saved from being lost in the skin and/or any other intervening tissue between the skin and the lesion. This new modality can cure the deep-seated and damaged tissues of the orthopedic system without any side effects if properly used. Therefore. the medication and surgery which are the main lines of treatment of orthopedic diseases could be avoided or at least reduced to the minimum. Lastly, this novel method is essential for the group of patients who are inoperable or are in their end-stage. Examples of these patients include end-stage renal failure, hepatic failure, heart failure, or stage IV of metastatic cancer. These patients may be in a severely painful condition because of arthritis but surgery and/or medication may not be allowed. VL - 2 IS - 1 ER -
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