User talk:I.R.Bhattacharjee

The article User:I.R.Bhattacharjee has been speedily deleted from Wikipedia. This has been done under the criteria for speedy deletion, because the article seems to be blatant advertising which only promotes a company, product, group or service and which is unlikely to be suitable for an article (or at best would need a fundamentally rewrite). Please read the general criteria for speedy deletion, particularly item 11, as well as the guidelines on spam. Feel free to leave a note on my talk page if you have any questions about this. JamesBWatson (talk) 20:42, 2 August 2010 (UTC)

Welcome!

Hello, I.R.Bhattacharjee, and welcome to Wikipedia! Thank you for your contributions. I hope you like the place and decide to stay. Here are some pages that you might find helpful: I hope you enjoy editing here and being a Wikipedian! Please sign your messages on discussion pages using four tildes ( ~ ); this will automatically insert your username and the date. If you need help, check out Questions, ask me on my talk page, or ask your question on this page and then place  before the question. Again, welcome! JohnCD (talk) 08:49, 3 August 2010 (UTC)
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JohnCD (talk) 08:46, 3 August 2010 (UTC)

Two accounts
I notice that you seem to have two accounts - this one and. Please use only one of these accounts, to avoid any suspicion of WP:Sockpuppetry. JohnCD (talk) 08:49, 3 August 2010 (UTC)

Deletion of article
Hi, welcome to wikipedia. The article in question was originally deleted in a deletion discussion (Articles for deletion/Biomechanics of intrinsic gravity). Subsequent verbatim recreations of the article may be deleted by administrators summarily through a process known as speedy deletion. The near unanimous opinion of the editors participating in that deletion debate was that the article represented a novel theory and Wikipedia was being treated as a publisher of first instance. I tend to agree with that conclusion. Wikipedia will have a place for this research if it becomes widely accepted within its field and is the subject of multiple independent reliable sources. Until then it would be inappropriate for us to have an article on the subject. Protonk (talk) 18:59, 10 August 2010 (UTC)

Hi, Protonk, I appreciate your concern that Wikipedia is not a publisher of first instance. Gravity Dictates Life Death/ Biomechanics of Intrinsic Gravity/ Self Gravitation bio, Wikipedia is not the publisher of first instance.From 1988 onward, there is lot of progress. For instance, http://www.amazon.com/gp/offer-listing/8170193206/ref=dp_olp_0?ie=UTF8&redirect=true&qid=1281614017&sr=1-1&condition=all; http://icbp2007.congresoselis.info/resumenAmpliado.php?idTL=455;http://www.cell.com/biophysj/archive/issue?pii=S0006-3495(08)X7185-1; http://www.abstractsonline.com/plan/ViewAbstract.aspx?mID=2294&sKey=ffbcc7a6-e87c-4238-ad30-edbd4b98b188&cKey=9cd3dd26-1f59-495a-8b50-7d603bb78a44&mKey=699dea71-10c2-4fff-a9e0-62aa4824fb1e;Eur Biophys J (2009)38(suppl 1):s35-s212 springer DOI 10-1007/s00249-009-0478-1 etc. are some of the documents I could locate in the net today. From all these instances, it is clear that, as regard 'Biomechanics of Intrinsic Gravity', Wikipedia is not the publisher of first instance. Rather all information are from secondary sources, with appropriately linked and reference. Considering its importance, Biophysical Society, USA which has about 8000 membership globally has included, christening it as "Self Gravitation Bio". European Biophysical Society has also agreed, apart from Indian Science Congress Association. So when a common widely accepted consensus has been built up, the decision of deletion "biomechanics of Intrinsic Gravity" is not understood. So I appeal to you to reconsider your decision in favour of progress in science. Nature itself is tough to understand. So compiled from primary sources with all links are attached below for a fresh decision from your end. Your suggestion in any manner is welcome.

Biomechanics of intrinsic gravity
Biomechanics and extrinsic gravity

Biomechanics is the science concerned with the action of forces, internal or external, on the living body [1]. Biological masses are under influence of both intrinsic and extrinsic forces of gravity. Interaction effect of extrinsic (earth’s) gravity on growth and development of living organisms is being established through comparative study under microgravity in space [2].

Biological particle pyramid
On presence of intrinsic force of gravity in biological mass, a conceptual model of domain of various basic forces in the particle pyramid had been outlined 3. In ten-storied particle-pyramid of biological organisms {viz. (i) electron, proton, neutron (ii) atoms (iii) molecules (iv) compounds (colloids, crystal, mixture) (v) organelles (vi) cells (vii) tissues (viii) organs (ix) organ systems and (x) organism /individual}, organelles and its above are regarded as living.

Domain of various basic forces
As regard operational domain of various basic forces around multi-storied 'particle pyramid' of biological mass (exception being any local perturbing or limiting effect), the short range nuclear forces are stronger below atomic level; medium range electrostatic forces are stronger at compound levels. The electrostatic potential is of diatomic origin and cannot be stored in biological system as internal metabolic energy. At higher levels of particle pyramid within structural enclosure, intrinsic force of self-gravity attracts in constant manner, as if entire mass is concentrated at the centre. Magnitude of such binding force is dependent on density of the bio-mass and buoyant force of the co-moving fluid surrounding it. Internal metabolic energy counteracts intrinsic and extrinsic gravitational energy. At higher levels of particle pyramid, 'gravitational force' would therefore be stronger after increase in mass through passing of age and fall in non-storable metabolic energy in time-bound biological system [3] [4].

Research on domain of intrinsic gravity in biomass

To systematize understanding on biomechanics of intrinsic gravity, theoretical calculation shows that exertion of gravitational forces which follows inverse square law gets increased from 0.0007 to 6.6726 dynes when quantity in two masses increase from 10-4 to 10-2 grams under same separation distance of 10-6 centimeter. Similarly when separation distance is decreased from 10-6 centimeter to 10-10 centimeter for the same two masses of 10-4 grams each, the gravitational force is increased from 0.0007 to 66,726 dyne [5].

Suggested methodology

Methodology that responds only to differences in standard from nano to micron or higher level in gravitational attractions, canceling out much stronger constant extrinsic gravitational pull and various localized forces could provide valuable insight. Biological mass is not uniformly dense spherical shell. It would be possible to ingeniously locate internal mass point in self-gravitating system of live cells, as if masses are concentrated at the centre. There may be an acceleration of various peripheral particles towards mid-plane out of movement between azimuthally and radial components due to inward drag force. Also there would be an outward internal pressure of bioenergetics like metabolically inert infrastructure (MII) and [|basal metabolic rate] (BMR). With appropriate deductions and adopting suitable marker, the net force in terms of differential strength of self gravity in a system of cells at nano to micron level could be measured with adequate statistical mechanics 6.

Metabolically inert infrastructure as structural support
Metabolically inert infrastructure (MII) consists of total body mass (body water, dissolved substances, mineral and organic deposits) and serves as storage of nutrients, transport and distribution of these materials [7]. To act independently as living body, MII was suggested also to provide structural support to the organism with density-gradient buoyant force against intrinsic and extrinsic gravitational attraction for the biological mass [8] [9]. It was shown that `amniotic fluid', `isotonic saline to ailing patient', `cultural medium' and other `medium matrices' act as counter-gravity mechanism for living organisms [18] [19].

Metabolic energy related to Mass
Relationship between mass and [|metabolic] energy of the living organism remains controversial. Max Rubner reported that mammalian basal metabolic rate (BMR) was proportional to mass (M 2/3) [10]. Max Kleiber [11], supported by Brody  [12] modified proportionality to mass (M 3/4) in organisms ranging from simple unicells to plants and endothermic vertebrates. Warm blooded, cold blooded and unicellular animals fit on different curves. Kleiber’s famous mouse-to-elephant curve and quarter-power scaling is often regarded as ubiquitous in biology. Harris-Benedict equation [13] calculates total heat production at complete rest based on weight, stature (height), and age, and with the difference in basal metabolic rate (BMR) for men and women being mainly due to differences in body weight. MD Mifflin and ST St Jeor[14] created new equation with +5 for males and −161 for female or Katch-McArdle formula[15] based on lean body mass in kilogram with woman whom, for example, has a body fat percentage of 30%, BMR would be 1262 kcal per day. To calculate daily calorie needs, this BMR value is multiplied by a factor with a value between 1.2 and 1.9, depending on the person's physical activity level (PAL) [16]. Basal metabolic rate (molecule of oxygen consumption per hour) at rest [16] is expected to be approximately proportional to intrinsic gravitational energy, whereas energy expenditure due to physical activity level (PAL) would be approximately equals to energy needed to work against extrinsic gravitational energy [8] [9]. To remain as living, metabolic energy of the biological mass works against intrinsic and extrinsic gravitational energy. It also has to do work or remain functional against extrinsic gravitational pull of the planet [8] [9].

Mimics in gravitational phenomena of biomass
Without mass, living organism does not exist. Gravity is the basic force that acts on mass. Magnitude wise small effect of intrinsic gravity [17] in biological mass seems mimic gravitational phenomena of larger mass (say stellar bodies). Living species are therefore contemplated to live and grow out of balance between individual’s inward force of self-gravity and outward metabolic energy, mass being buoyed by metabolically inert infrastructure, so also on interaction with extrinsic gravitational pressure and pull of the earth or planet [8] [9] [19]. Phenomena (mimic) of rhythmic growth and development of living bodies through phases of contraction followed by expansion alternately, isostatic balance i.e. balances between lighter and heavier mass in relation to centre of self-gravity, convectional flow pattern leading to bilateral symmetry and other pertinent features including sigmoid shape evolutionary process, on being subjected by changing external gravitational force have some similarity with other self-gravitating bodies of the universe and these were outlined on the principles of equivalence [3][18][19][20].

Self gravitation bio
To carry out more focus research on biomechanics of intrinsic gravity, a new field of study named as ‘self gravitation bio’ had been initiated during 2008[21].

Deletion review
I have posted a deletion review here. Protonk (talk) 22:30, 30 August 2010 (UTC)

Please do not recreate the Biomechanics of intrinsic gravity article. It will simply be redeleted and you will sooner or later be blocked from editing. Angus McLellan (Talk) 21:11, 7 September 2010 (UTC)

Article has not been recreated with the same content (prior to deletion). It is placed after ample revision/ modification, and in the talk page for interaction, and not in the main page. Is it not permissible? Please suggest alternatives, if any –I.R.Bhattacharjee 14:02, 8 September 2010 (UTC) My request has not yet been addressed to.I.R.Bhattacharjee 18:48, 23 October 2010 (UTC)