My Girlfriend Claims She Grew 1 cm

I had said in a few posts back that I would not be doing too much posting on this website for the next 4-5 months as I am building up another project of mine. However, something interesting did happen today which made me start to rethink some theories I have had ever since last year.

I was on Skype with my girlfriend, and she told me that she found out from a recent Medical Exam that she was measured at 1.62 meters in height. Before that, she had always claimed that she was just 1.61 meters in height. Now, 1 cm is only about 0.394 inches, but since the rest of the world bases the measure of length on the meter, and thus the centimeter, that 1 extra centimeter in height is noticeable.

How was I supposed to take that type of news, since I am probably one of the only researchers in the world who has been actively looking for this type of phenomena??.

She is 26 now, with a birthday in January. It makes no sense for a girl of her age to ever increase in height.

However, females increasing in height in their late 20s is NOT completely unheard of.

She almost completely validates a theory I had about a year ago.

It seems that females who have been abnormally thin and with low bone density seem to have height increasing capabilities later than most other women.

In addition, she has been suffering from cold knees and knee pain for the longest time.

Recently she went to get 3 of her wisdom teeth removed, almost a dozen cavities filled, and had to see multiple medical specialists over medical problems.

In addition, she has been complaining for more than a year that she feels a strange feeling of pressure on her eyelid. A trip to the eye doctor suggested that she might very likely develop glaucoma. When the likelihood of glaucoma was ruled out, she went to see a Neuro-Specialist, who suggested that she might have a tumor developing in her brain, causing the optic nerve behind her eyeball to become pinched, causing that feeling of pressure on the eyelid. She did go get a CT Scan. Was it possible that she has some type of tumor in her pituitary causing pituitary adenoma?

So let me list the types of medical conditions she has been suffering from

  • Childhood history of being abnormally thin
  • She has the most common symptoms of a person with low bone density
  • She suffers from having knees which are always “cold”
  • Her knees have been developing pain, which has started to affect also her lower back.
  • Her blood test shows that her iron level is low, suggesting maybe anemia.
  • Has a long history of extremely heavy bleeding during menstration.

In response to all this, she has being taking the following supplements

  • Iron
  • Multivitamin
  • Magnesium
  • Vitamin D3
  • Glucosamine HCL (not the Sulphate type)
  • Lexapro

I don’t really know what to think right now since someone very close to me has gone through the small big of transformation which we have been searching for the last two years.

Could her claim to be a fluke, maybe a measurement error, or she just hasn’t measured herself in the last 10 years, ever since she noticed that she leveled off in height at the end of puberty?

If I was to be a sceptic, I would say that she has been at 1.62 meters in height for a long time, but she just never realized it. I remember more than a year ago, at a Zoo in Everland (South Korea), there was a height scale on the side of an exhibit to compare ourselves to the giraffe. You walk by it to get an idea of just how much taller a giraffe is to you. She walked under that height scale and stated that she was just 1.61 meters in height. Where I was standing, it looked like she was closer to the 1.62-1.63 meters range, and she was wearing TOMS shoes, the ones which only have less than 1 cm of heel height. If I was to guess, she was already 1.62 meters in height already.

However, let’s say that she did miraculously grow by 1 cm in the last few months. How would I even be able to validate that idea?

The only thing that I can think of is to maybe wait another 6 months or 1 year to see if she has pushed up in height again, to say 1.63 meters. If that happens, then I know that what I have been searching for the longest time may be already right next to me.

If she is growing, then it is time to ask myself, as probably the worlds most extensive amateur height increase researcher, how is it that my own girlfriend has grown at this late stage of her life?

Very promising evidence that LSJL induced longitudinal bone growth in my finger

The coloration of regions of an area in an xray reflect their density.  If a region of bone is grayer than normal that bone is less dense.  If a bone is less dense that could mean that it is a region of new growth or that the bone is naturally less dense.  But even though some regions of less density are natural, if these regions of decreased density are expanded it is very possible that this could be indicative of increased growth.  If this expansion occurs in the longitudinal direction then it is indicative of longitudinal bone growth.  If you compare my right and left lateral finger xrays below you can see that my right bone has much greater expansion of these gray regions than the left and the regions extend into the longitudinal direction thus being indicative of longitudinal bone growth.

I need your help to confirm or deny this theory.

I statement I found on white versus black regions in x=rays: “On x-ray, bone and dense materials such as barium are white. Black would be air (lungs or air in the GI tract). Other tissues are in shades of gray. You can see the outline or shadow of the kidneys or certain muscles, for example. But you cannot see these things in detail. X-ray does not show the difference between normal vs. “dead” tissue. A CT scan, or even better, a MRI would be better suited for that type of diagnosis. ”

The darker regions of the bones are more likely to be less dense or possibly new grown bone.  Some bones are naturally less dense than others.  So we have to compare the bones also to standard bones.  If there are more gray areas than normal then it’s likely that there was new bone growth.

Here’s one lateral index finger view:
right lateral index finger

Which my finger looks more like.  Here’s one that my left finger looks more like(this is also a right index finger):
left proximal index finger

Have to compare color intensity of areas of right versus left bone.

Here’s a finger with some gray areas.  There is a large gray region on the tip of the proximal finger and some on the bottom part of the distal region of the medial index finger.  Note this is a fractured finger so we’d expect there to be some anabolic growth.

xray-mallet

So, it’s normal to have those regions of darker bone.

There are other potential reasons why one part of the bone can be much darker than the other but one strong possibility is that it is new LSJL induced bone growth.  Since LSJL involves lateral loading it makes sense that much of the growth can be better observed than a lateral angle(the differences in coloration can not be seen as well from an overhead view).  From the overhead view the right index finger looks to be whiter than the left index finger infact.  Click on the images below to enlarge them.

LSJL-right hand illustrated

LSJL left hand illustratedEach of the circled points A-D represents a region of bone that is much lighter than the other.  On the left side these regions are present but the are much lighter.  At point A it seems to blend better with the whiter region of the bone in contrast to the right side where it is more a bulbous head.  The bone at B looks totally different.  C and D are similar but the right(LSJL loaded side the darker region of the bone is much bigger).

Percentage growth based on darker area versus lighter area:

Proximal Head(Tip of dark region to tip of light): 23.4 pixels

(bottom of proximal index finger bone to top of light region): 170.4 pixels

13.7% growth.

However, I’d guess that my left bones are about 1% longer than my right.  If my right finger did grow longer than 10% my right proximal finger would measure longer than my left which is not the case.  You can see from the above images of other images that the normal finger has these darker regions, those regions are just expanded above normal.  So maybe the the proximal finger bone didn’t grow the entire gray region but the gray region just expanded in response to the stimulus.  In fact a study has shown that the finger bones naturally grow into adulthood.  So these darker regions of bone could be a sign of adult finger growth.  The same study stated that metacarpals tend to decrease in length so the fact that my right metacarpal grew longer is a good sign that this growth could extend to other bones.

What’s a bit unfortunate is that the growth plates are on the proximal(bottom) end of the finger bones and the gray regions are on the distal(top) ends of the finger bones.  However, the distal regions of my right finger bones do seem to be a bit more gray than the left bones so it is possible that the growth plate region was stimulated by LSJL.

Below is some more information about x-rays.

Here’s something I found describing xrays:

” The bone along the joint is usually whiter (called “sclerosis”) and may have little points of bone growing out (called “osteophytes”). There may be holes in the bone ( called “cysts”) and the bones may be starting to slide out of alignment (called “subluxation”).”<-None of these images quite explains the growth in LSJL.

Here’s a comment I found from Yahoo! Answers:

“Bones always appear as white images in regular xrays. However they arent really white because the film is clear, the plastic on the view box is white. But on xray film it is coated with a metalic layer. The xrays make the metalic layer stick to the film. So the black part of the film is where all the xrays reach the film. If the area on the xray is gray, then that means that some of the xrays are getting through implying that the structure is more dense than the black part. Soft tissue appears gray. The bone is a very dense structure allowing minimal to no xrays getting through. The film is then put through the processor and the film runs through chemicals that make the picture “stay” on the film. It is then rinsed and dried. Since the xrays make the metalic layer stick, none stick to the area of the bone because no radiation got through and the layer was washed off during processing. This is why bones appear white, they are the densest structure.”

Here’s another response from Yahoo! Answers regarding why one part of the bone is darker than the other:

“When a bone X-ray is taken, radiation is momentarily irradiated on the area being examined. X-rays pass through the body to produce an image on film. Structures like bone that are dense and have a high atomic number absorb a lot of X-rays, so less X-rays reach the film and the bone appears white on the film. Muscle, fat, tumour, and fluid absorb less X-ray than bone, and appear darker than bone on the film. Air distributed in various pockets within the body (usually due to an abnormality) has a low atomic number and density, and consequently appears black, because most X-rays pass through without being absorbed. You would be advised to consult the doctor or radiologist dealing with this matter and enquire as to the suspected cause of the description that you describe. You may find that further tests/examinations will result from the X-Ray result which will determine or assist the diagnosis.
The information provided here should not be used during any medical emergency or for the diagnosis or treatment of any medical condition. A licensed physician should be consulted for diagnosis and treatment of any and all medical conditions. “<-I don’t think air pockets could explain the larger gray area on the right side bone.

Spinal height gained by bedrest could be related to GAGs

This study shows that the increase in spinal height after bed rest and space flight may be due to an increase in GAG content in the intervertebral disc.

Assessment of Lumbar Intervertebral Disc Glycosaminoglycan Content by Gadolinium-Enhanced MRI before and after 21-Days of Head-Down-Tilt Bedrest.

“During spaceflight, it has been shown that intervertebral discs (IVDs) increase in height, causing elongation of the spine up to several centimeters. Astronauts frequently report dull lower back pain that is most likely of discogenic origin and may result from IVD expansion. It is unknown whether disc volume solely increases by water influx, or if the content of glycosaminoglycans also changes in microgravity. Aim of this pilot study was to investigate effects of the spaceflight analog of bedrest on the glycosaminoglycan content of human lumbar IVDs. Five healthy, non-smoking, male human subjects of European descent were immobilized in 6° head-down-tilt bedrest for 21 days. Subjects remained in bed 24 h a day with at least one shoulder on the mattress. Magnetic Resonance Imaging (MRI) scans were taken according to the delayed gadolinium-enhanced magnetic resonance imaging (dGEMRIC) protocol before and after bedrest. The outcome measures were T1 and ΔT1. Scans were performed before and after administration of the contrast agent Gd-DOTA, and differences between T1-values of both scans (ΔT1) were computed. ΔT1 is the longitudinal relaxation time in the tissue and inversely related to the glycosaminoglycan-content. For data analysis, IVDs L1/2 to L4/5 were semi-automatically segmented. Zones were defined and analyzed separately. Results show a highly significant decrease in ΔT1 (p<0.001) after bedrest in all IVDs, and in all areas of the IVDs. The ΔT1-decrease was most prominent in the nucleus pulposus and in L4/5, and was expressed slightly more in the posterior than anterior IVD. Unexpected negative ΔT1-values were found in Pfirrmann-grade 2-discs after bedrest. Significantly lower T1 before contrast agent application was found after bedrest compared to before bedrest. According to the dGEMRIC-literature, the decrease in ΔT1 may be interpreted as an increase in glycosaminoglycans in healthy IVDs during bedrest. This interpretation seems contradictory to previous findings in IVD unloading.”

“Average ΔT1 value of all intervertebral discs was 104.87 ms (sd 7.64 ms) pre-bedrest and -20.20 ms (sd 4.70 ms) post-bedrest.”

“It seems to be well established that increased GAG concentration within the IVD will result in a decrease in ΔT1. A high GAG-concentration causes a small ΔT1 during dGEMRIC-measurements because only small amounts of contrast agent shift into the IVD. A low GAG-concentration in turn leads to a high ΔT1. Increased ΔT1 after an intervention (as compared to before) has been interpreted as degeneration process”<So T1 has nothing to do with the height it has to do with the GAG content.  So a decrease in deltaT1 means that GAG content likely increased.

Creep Strain to grow taller?

I couldn’t find anything that showed that bone could grow taller in response to creep strain but it seems that other objects can get longer.  Creep Strain can cause a change in shape of bone at very low magnitudes of strain but at very high amounts of time which is important as the amount of load required to induce plastic deformation of bone is outside ordinary means.  The optimal load for creep strain may about half that of which is used to induce fracture.

I could only find studies that showed that creep strain compressed bone not that it could lengthen it.

However, if creep strain can lengthen other objects shouldn’t it be able to do the same to bone?

Here’s a high school science experiment that shows that creep strain can lengthen objects:

Do Materials Get Tired? Do Rubber Bands Get Longer During Use?

 

“Some materials will slowly deform when a constant force or displacement is applied to them. This time-dependent and permanent deformation is called creep.

If you have ever noticed that chewing gum gradually sags when it is stuck to something or watched a plastic grocery bag gradually tear apart when it is carrying too much weight, you have observed creep!”

The science experiment involves loading a rubber band with a weight for 24 hours to observe creep and then measuring the change in length.

Now rubber bands are much more elastic than bone which is a problem.

Another problem is that based on how the tensile creep strain is applied to the bone other soft tissues will be loaded which may fail first before the bone has undergone creep for an appropriate amount of time.  Another issue is that inducing creep failure in bone may cause loss of bone structural integrity may cause problems.

Methods of inducing creep strain in bone seem to lend itself to several common exercises:

Holding weights for extended periods of time to lengthen arms.  For creep strain it has to be for a significantly long amount of time and then there’s the issue of the soft tissues failing first.  Can anyone find any anecdotal evidence of people who do farmer’s walks(you don’t actually have to walk to induce creep strain just holding the weights is enough) having longer arms?

Hanging to lengthen arms.  And again there’s no guarantee that creep strain will be induced in the arms before soft tissue failure.  And you’d have to do it for quite a sustained amount of time although you can take breaks as creep train is based on fatigue loading so you can rest for brief intervals as long as total bone fatigue gradually increases.

Inversion to lengthen legs although more load than body weight is likely needed and it would be very hard to maintain the kind of duration for creep to take place.

Does anyone have any anecdotal evidence of these exercises increasing arm or leg height?  While common I’m not sure these exercises are best for creep strain based lengthening due to the likelihood of your joints giving out before your bones.

Height Increase Techniques that are unlikely to work

1) Stretching(on the spine)

Read this summation of the theory of spinal stretching.

Although one study indicates that a twisting motion can increase height in some cases, other human studies have suggested that twisting can only reduce height in human models.  This is due to the nucleus pulposus not being mechanically stable in contrast to the annulus fibrosus which can grow.  In response to mechanically strain, there was degeneration in the nucleus pulposus and there is a medical term for this caused degenerative disc disease.

Now, other joints do not have nucleus pulposus like the joints of the ankle and knee so those can potentially grow in size.  Interesting though is that one study found that wingspan decreased more with age than overall height.  Which is contrary to what we would believe with discs being prone to degeneration.  There is an increase in the hand phalanxes continuously throughout lifeNow I received an increase of 0.8%(at least) in my right index finger metacarpal.  So the normal hand phalanx growth does not explain my growth.  That study suggests that articular cartilage can undergo endochondral ossification which can add appositional bone growth to the longitudinal ends of the bone resulting in longitudinal bone growth.

Now one thing is that nucleus pulposus is so prone to degeneration and can reduce height so much is that we can reduce degeneration.  For example by living in zero gravity, by strengthening the muscles surrounding the spine to reduce spinal load, or via spinal tractors/inversion to reduce load allowing water to return to the nucleus pulposus.

This height increase method listed here(Aquatic Vertical Suspension) resulted in an immediate height increase of about 4mm.

2) HGH

People have supplemented with HGH at levels at or greater than those who have “suffered” from gigantism reported no height gain.  Gigantism does not merely involve elevated HGH levels but also resistance to HGH suppression.  Gigantism also involves a tumor.  Two factors that are not involved in HGH supplementation.

There has been no evidence as of yet that HGH can induce exogenous growth plates to induce new longitudinal bone growth.  Although some anecdotal evidence of HGH induced growth has been reported.

3) Microcracks

There hasn’t been any evidence to suggest that microcracks can lengthen bone.  And mineralized bone seems to be incapable of interstitial growth(growth from within ala growth plates) due to high ECM stiffness.  Thus there needs to be an intermediary tissue involved like cartilage in order to lengthen bone in a roundabout way.  So to lengthen bone via microfractures you’d have to reduce ECM stiffness to allow for interstitial growth.  Here’s one possible method to reducing ECM stiffness using acid that has been suggested.

4)Bone Stretching

For example via the Rack.  The amount of load required to induce a bone fracture is  usually a colossal figure like 25000-lbs.  And the amount of load to induce plastic deformation(bone stretching or negatively compression) is usually very close to the fracture point.  This makes the generation of such loads problematic.  That’s why the design of LSJL is to try to induce mesenchymal condensation and neo-growth plate formation.

Creep Strain can induce plastic deformation at much lower loads.  However, a considerable continuous amount of load is required to induce 1-2 weeks.  I could not find any evidence of creep strain inducing plastic deformation in a positive way(stretching), only a negative way(compression).  I couldn’t find any other studies where length was even considered as only damage to the bone was measured.

Video Of Alexander Teplyashin’s Laboratory Lengthening Legs Of Sheep Using Stem Cell Implants

This is the 2nd video

There is some medical terms that can’t be translated like “stem cells” and “implant” so the video is quite accurate. Dr. Teplyashin is actually sort of a celebrity surgeon in the Moscow area. The rams/sheeps in the video are adult, so they are not going to get any taller. The implant goes into the bone after a small resection.

If you guys are interested in watching more videos about Teplyashin’s many video appearances on Russian Media TV , click here for the Youtube username Alexander Gaponov – https://www.youtube.com/user/elansky/videos

If any of you actually understands Russian, can you translate what they say in the short video?

Notice also in the video below how his lab follows general GLP (Good Laboratory Practices). This is not like what Gavrill Ilizarov did back in the 60s-80s with his version of leg lengthening.

I haven’t updated this website in a long time because I have recently started a new business venture. However, I promise that I will come back to this venture. There are other medical entrepreneurial ideas that I would like to pursue as well.