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Bala, Jyoti

Empowering Parents of Children with Thalassemia

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Authors

Jyoti Bala ¹, Jyoti Sarin ²

Affiliations
1 College of Nursing, Saifai, Etawah (U.P.), IN
2 M.M. College of Nursing, Mullana, Ambala, IN

Source

International Journal of Nursing Care, Vol 2, No 1 (2014), Pagination: 22-25

Abstract

Thalassemia is a common disorder worldwide with a predominant incidence in Mediterranean countries, North Africa, Middle East, India, Central Asia, and Southeast Asia. Approximately, 240 million people are estimated as carriers for β-thalessemia worldwide while 100,000 thalassemic major are born annually2. It is not only affect the children but also their parents due to the cost of treatment involving regular blood transfusions, iron chelation, frequent hospitalization and general medical follow up. Diagnosis of the disease and adjusting with it for parents is considered as a crisis and they react differently. Most of the parents can successfully adopt themselves with chronic disease of their children. In contrast, some of them also may not be successful in coping with it due to lack of access to accurate information about the disease, lack of appropriate support resources, high treatment costs, mental status and social damages. Nurses have a key role in empowerment of parents of children with thalassemia for the child's development needs such as health, social identity, education, self care skills, family and social relationships, emotional and behavioural development; the parents' own capacity to parent, including issues related to guidance and boundaries; and to deal with the family and environmental factors like family history and functioning, employment, income, family's social integration and community resources.

Keywords

Thalassemia , Blood Transfusion, Iron Chelation, Empowerment

Full Text

Comparative Physiological Cost of Chapati Making in Different Postures

Ultrasonic Attenuation in Intermetallics HfX(X=Os, Ir and Pt)

Abstract Views :213 | PDF Views:1

Authors

Jyoti Bala ¹, Devraj Singh ², Arvind Kumar Tiwari ³, Shikha Wadhwa ⁴, Ashish Mathur ⁴

Affiliations
1 University School of Information, Communication and Technology, Guru Gobind Singh Indraprastha University, Dwarka Sector 16C, New Delhi-110078, IN
2 Department of Physics, Professor Rajendra Singh (Rajju Bhaiya) Institute of Physical Sciences for Study & Research, Veer Bahadur Singh Purvanchal University, Jaunpur-222003, U.P., IN
3 Department of Physics, Bappa Sri Narain Vocational P.G. College (KKV), Charbagh, Lucknow-226001, U.P., IN
4 Amity Institute of Nanotechnology, Amity University Uttar Pradesh, Noida-201313, U.P., IN

Source

Journal of Pure and Applied Ultrasonics, Vol 42, No 2 (2020), Pagination: 46-51

Abstract

Ultrasonic study of B₂ -structured hafnium based compounds HfX(X=Os, Ir and Pt) along direction were evaluated at room temperature. Initially, the Coulomb and Born-Mayer potential model was used to find out the higher order elastic constants of HfX at room temperature. We have used the second order elastic constants (SOECs) to compute the mechanical properties such as bulk modulus, Young's modulus, shear modulus, Pugh's ratio, Poisson's ratio, Zener anisotropic factor, Vicker's hardness, Lame's modulus of chosen materials. Further, the SOECs and third order elastic constants (TOECs) were applied to compute ultrasonic velocities and Debye temperature. The thermal conductivity and thermal relaxation time of chosen monopnictides compounds have also been computed at room temperature. We have found that HfOs is strongest and most fit material for crystallographic study in B₂ phase. In addition to above evaluated parameters, energy density, specific heat per unit volume, thermal conductivity, acoustic coupling constants and ultrasonic attenuation for longitudinal and shear modes propagation along direction have been estimated. The ultrasonic attenuation was least in case of HfOs. Obtained results have been discussed and justified with available findings for their future prospects.

Keywords

Elastic Constants, Mechanical Properties, Thermal Conductivity, Ultrasonic Attenuation.

Full Text

References

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Bala J., Singh D., Pandey D.K.and Yadav C.P., Mechanical and thermophysical properties of ScM (M: Ru, Rh, Pd, Ag) intermetallics, Int. J. Thermophys. 41 (2020) 46 (13 pp.).

Singh D., Tripathy C., Paikaray R., Mathur A.and Wadhwa S.,Behaviour of ultrasonic properties on SnAs, InTe and PbSb. Eng. Appl. Sci. Res., 46(2019) 98-105.

Pandey D.K.and Yadav C.P.,Thermophysical and ultrasonic properties of GdCu under the effect of temperature and pressure, Phase Trans., 93(2020) 338-349.

Yadav C.P., Pandey D.K.and Singh D.,Elastic and ultrasonic studies on RM (R = Tb, Dy, Ho, Er, Tm; M = Zn, Cu) compounds, Z. Naturforsch. A 74(2019) 1123-1130.

Internet of Diagnostic Things: Emerging Horizon towards Precision and Digital Health Care

Abstract Views :503 | PDF Views:107

Authors

Vijay Verma ¹, Abhisek Mishra ², Vaishali Bisht ², Jyoti Bala ²

Affiliations
1 Aristocrat Technologies, Noida Sector 16, Uttar Pradesh, IN
2 Rapture Biotech International (P) Ltd., Sector 10, Noida − 201301, Uttar Pradesh, IN

Source

Journal of Health Science Research, Vol 5, No 2 (2020), Pagination: 51-61

Abstract

Digital revolution and advancement of information technologies, smart phone industry, multi-omic technologies, availability with 5G networks and emergence of big data era has greatly impacted on diagnostic, biomedical and e-healthcare sectors. Intelligent sensors, wearable, digital imaging, smart phone based diagnostic and connected networking provides smart approach and platform towards precision diagnostics. Recently, Internet of Things (IoT) have shown remarkable impact on diverge sectors such as digital imaging, smart sensing, digital diagnostic, digital biotech, telemedicine, precision farming, lab-on phone, smart home, smart city planning, smart retails and Research and Development (R&D) automation etc. Application of IoT technology in diagnostic and healthcare opens a way for personalization in the medical care depending on individual needs, additionally giving option for well-organized way for remote healthcare and management. This review focuses on theoretical, technological, advanced aspects of digital diagnostic utilizing IoT technology. Furthermore, we have also highlighted the opportunities and challenges for IoT in exploring the futuristic scope and innovation in diagnostic application. IoT based diagnostic, sensing and imaging devices provides unprecedented precision, automation in the diagnostic and thereby could significantly improve the biomedical and e-healthcare area.

Keywords

Digital Biomarkers, Digital Diagnostic, e-Health, Integrated Networking, Internet of Things.

Full Text

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Elastic and Ultrasonic Properties of Cadmium Oxide

Abstract Views :242 | PDF Views:1

Authors

Jyoti Bala ¹, Vyoma Bhalla ², Devraj Singh ³, C. P. Yadav ⁴, D. K. Pandey ⁴

Affiliations
1 University School of Information & Communication Technology, Guru Gobind Singh Indraprastha University, New Delhi-110 078, IN
2 Amity School of Engineering & Technology Delhi, A.U.U.P. Premises, Noida-201 313, IN
3 Department of Physics, Prof. Rajendra Singh (Rajju Bhaiya) Institute of Physical Sciences for Study and Research, Veer Bahadur Singh Purvanchal University, Jaunpur-222 003, IN
4 Department of Physics, P.P.N. (P.G.) College, Kanpur-208 001, IN

Source

Journal of Pure and Applied Ultrasonics, Vol 42, No 3 (2020), Pagination: 78-80

Abstract

The attenuation of ultrasonic waves has been estimated in rocksalt type (B1) and CsCl type (B2) structures of CdO at room temperature along , and directions. First of all, the higher order elastic constants have been computed using Born model with Mori and Hiki approach. Then, the second order elastic constants (SOECs) were applied to compute the mechanical constants such as shear modulus, Young's modulus, bulk modulus, tetragonal modulus, Poisson's ratio, Pugh's indicator for finding performance of CdO. Numerous physical quantities, such as ultrasonic velocity, Debye temperature, thermal conductivity, ultrasonic Gruneisen parameter and acoustic coupling constants have been determined for the chosen material. Finally, the attenuation of ultrasonic waves has been compared in B1 and B2 phases of CdO and discussed in correlation with available findings.

Keywords

Cadmium Oxide, Elastic Constants, Thermal Properties, Ultrasonic Properties.

Full Text

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Bala, Jyoti

Empowering Parents of Children with Thalassemia

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Comparative Physiological Cost of Chapati Making in Different Postures

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Ultrasonic Attenuation in Intermetallics HfX(X=Os, Ir and Pt)

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Internet of Diagnostic Things: Emerging Horizon towards Precision and Digital Health Care

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Elastic and Ultrasonic Properties of Cadmium Oxide

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