Am J Ther. 2004 Sep-Oct;11(5):344-53. Related Articles,
Links
Urinary tract diseases revealed after DTP vaccination in infants and young
children: cytokine irregularities and down-regulation of cytochrome P-450
enzymes induced by the vaccine may uncover latent diseases in genetically
predisposed subjects.
Prandota J.
Faculty of Medicine and Dentistry, University Medical School, Wroclaw,
Poland. Jzef.854735@pharmanet.com.pl
Prophylactic vaccinations may sometimes shorten the incubation period of some
illnesses and/or convert a latent infection/inflammation into a clinically
apparent disease. Cytokines play a major role in mediating the inflammatory
process in various clinical entities and represent a potential source of
tissue damage if their production is not sufficiently well controlled. It
seems that irregularities in production of proinflammatory cytokines may be
responsible for the abnormalities associated with full-blown clinical
symptoms of various urinary tract diseases observed after DTP vaccination in
13 infants and young children hospitalized over the past 24 years. On
admission, upper respiratory tract diseases, atopic dermatitis, and/or latent
urinary tract infection/inflammation were found in these children. It is
suggested that the whole-cell pertussis present in DTP vaccine, acting as an
excessive stimulus in these patients, produced symptoms reminiscent of
biologic responses to circulating proinflammatory monokines such as IL-1beta,
TNF-alpha, and IL-6 because earlier it was reported that in vitro the
whole-cell vaccine induced significantly more such cytokine production than
did the acellular pertussis or diphtheria-tetanus-only vaccine. Analysis of
the cellular immune disturbances previously reported in urinary tract
infection/inflammation (increased serum and/or urinary IL-1alpha, IL-1
receptor antagonist, IL-6 and IL-8), steroid-sensitive nephrotic syndrome
(increased IL-2, IFN-gamma, TNF-alpha, and decreased or increased IL-4,
depending on the cells studied), and atopic dermatitis (decreased IFN-gamma
and increased IL-4 production), may suggest that similar subclinical chronic
cytokine-mediated abnormalities produced in the course of latent diseases
revealed in our patients, combined with those caused by DTP vaccination
stimulus, were responsible for the pathomechanism of these clinical entities.
This speculation is in agreement with the reports on the long-lasting
induction of cytokine release and down-regulation of hepatic cytochrome P-450
isoenzyme activities after administration of DTP vaccine to mice and may be
supported by the fact that TH1 phenotype is associated with the up-regulation
of intercellular adhesion molecule-1 and RANTES, whereas TH2 phenotype is
associated with the up-regulation of the vascular cell adhesion molecule and
P-selectin, which are key players in the migration into inflamed tissues and
localization of lymphocytes and other allergic effector and inflammatory
cells. Because several inflammatory cytokines down-regulate gene expression
of major cytochrome P-450 and/or other enzymes with the specific effects on
mRNA levels, protein expression, and enzyme activity, thus affecting the
metabolism of several endogenous lipophilic substances such as steroids,
lipid-soluble vitamins, prostaglandins, leukotrienes, thromboxanes, and
exogenous substances, their irregularities in the body may eventually lead to
the flare of latent diseases in some predisposed subjects. Also, interleukin
genetic polymorphisms, especially the constellation of TNF-alpha and IL-6
genetic variants, might predispose some infants with infection to a more than
usually intense inflammatory response in the kidneys after vaccination. It
seems that the aforementioned pathomechanism may also be responsible for some
cases of sudden infant death syndrome, which is often preceded by
infection/inflammation.
PMID: 15356430 [PubMed - indexed for MEDLINE]
VACCINATION AND THE
DYNAMICS OF CRITICAL DAYS
Nexus Magazine (Vol 12, No 6, Oct-Nov 2005)
PO Box 30, Mapleton Qld 4560 Australia. editor@nexusmagazine.com
Telephone: +61 (0)7 5442 9280; Fax: +61 (0)7 5442 9381
by Viera Scheibner, PhD ©2004
Principal Research Scientist (Retired) 178 Govetts Leap Road Blackheath, NSW
2785, Australia
Telephone: +61 (0)2 4787 8203 Fax: +61 (0)2 4787 8203
Dynamics of critical days as part of the dynamics of non-specific stress
syndrome discovered with Cotwatch breathing monitor
Underlying mechanisms of the cycle
Vaccination and cot deaths
Deaths after vaccinations
Vaccination and shaken baby syndrome
New diseases for old
Scientific evidence shows that babies can have severe adverse reactions to
vaccinations at critical intervals following their shots, and that vaccination
is the more likely cause of cot death and shaken baby syndrome.
Dynamics of critical days as part of the dynamics of non-specific stress
syndrome discovered during monitoring with Cotwatch breathing monitor
Recent editorials in the British Medical Journal (BMJ) by a number of authors
have motivated me to publish the results of research into babies' breathing.
This was research that the late Leif Karlsson (a Swedish biomedical electronics
engineer living in Australia) and I conducted with the Cotwatch breathing
monitor, developed by Leif in 1985-86 at my suggestion. Leif died in 1994 and
the Cotwatch breathing monitor died with him: I had it delisted with the
Therapeutic Goods Administration (TGA), and since 1994 it has not been
distributed.
Cotwatch was a true breathing monitor, meaning its electronics separated
heartbeat and breathing and only breathing delayed the alarm. The feedback on
breathing from the standard home monitor was from alarms (figure 1), while the
microprocessor-based unit provided computer printouts of the record of breathing
in the form of histograms stacked up at an angle (figure 2) or vertical bars
(figures 3,4), the length of which directly reflected the stress level as
integrals of the weighted apnoea/hypopnoea density (WAHD).
The record of alarms in a baby over a period of five-and-a-half months, from
October 1987 to March 1988 (figure 1), reveals that the stress-induced breathing
pattern did not subside after 21 days following vaccine administration: it was
still continuing on and off (following the critical days) two-and-a-half to
three months later; and before really recovering from the first lot, the child
was given the second injection of DPT and oral polio vaccines. Cotwatch recorded
events in breathing: apnoeas (pauses in breathing) and hypopnoeas (low-volume
breathing, i.e., below 5% of the volume of normal unstressed breathing). The
events were logarithmically weighted (the figures on the vertical axis of the
computer printouts are integrals of the WAHD).
The first two charts in figure 3 are computer printouts of the record of events
in breathing in two babies: baby one, who was given the third DPT
(diphtheria-pertussis-tetanus) vaccine and OPV (oral polio vaccine); and baby
two, who was given the first DPT and OPV. The higher the vertical bar, the
higher the stress level in breathing; figure 3 shows flare-ups of stress-induced
breathing day by day from day 0 when the vaccines were administered and up to
the 17th day.
It is obvious that even though baby one reacted much more than baby two, the
flare-ups of stressed breathing followed the same pattern of critical days, the
most important of these being day 2, after which day the stress level went down
and started rising again between days 5 and 7, when the stress level subsided
and started increasing again between days 14-16, subsided again and rose again
between days 19-24, after which it subsided and rose again towards the 28th day
and so on, following closely the pattern of alarms as recorded by a mother of
one baby (figure 1). Days 10 or 11 also emerged as critical days in babies who
reacted strongly, such as baby one. Needless to say, the increased intensity of
reactions after the third DPT injection and OPV reflects the phenomenon of
sensitisation (sensitisation in this context means increased deranged
immunological response or anaphylaxis; and in the case of vaccines it also means
increased susceptibility to the diseases that the vaccines are supposed to
prevent and to a host of unrelated bacterial and viral infections (Parfentjev,
1955; Craighead, 1975; Daum et al., 1989).
The third chart in figure 3 is of 41 actual, randomly listed deaths after DPT
and OPV; it can be seen that the distribution of deaths closely follows the
dynamics of the flare-ups of stressed breathing of babies one and two after the
administration of the DPT vaccine (Bernier et al., 1982, Walker et al., 1987,
Coulter and Fisher, 1991).
Figure 4 illustrates that in our research every baby was its own control (the
data measures the stress level in every baby before and after vaccination). For
a number of days there was no stress level in breathing, then conies day 0 when
the vaccine was administered and one can see how the babies reacted day by day.
Figure 4 represents two babies (baby one and baby three) and one can see the
individual differences in response, since baby three reacted within the first 24
hours, and also that the highest stress level occurred for baby one on days 5-6,
while for baby three it occurred on day 7, but this is to be expected since
babies are individuals in their own right. One must also take into consideration
that in statistics you always have a slight spread of a day or two before or
after the critical days. One can also rephrase it that nature does not
necessarily operate in a sudden, cut-off fashion but in a building-up and
tapering-off way.
Figure 4 also illustrates the individuality of stress response after the 16th
day: baby three had a significant delayed reaction towards the 24th day, while
baby one had only a slightly increased stress level towards the 24th day.
Underlying mechanisms of the cycle
Immunological research unwittingly provided another explanation for the observed
and recorded slight differences in the daily dynamics of maximum stress
response. Takacs et al. (1997) studied the possible underlying mechanisms of the
cyclic pattern of relapsing/remitting experimental allergic encephalomyelitis (EAE).
Their approach was to conduct a longitudinal study correlating epitope
recognition and cytokine production by draining lymph node cells, splenocytes
and central nervous system (CNS) infiltrating cells with disease during
relapsing and remitting EAE. Responses of lymph node cells and splenocytes were
uni-formative with respect to epitope spread. However, there were interesting
day-by-day dynamics as far as the time-course of T cell responses in lymph nodes
was concerned.
EAE was induced with 200 micrograms of PLP (proeolipid protein) 139-151, PLP
178-191 or MBP (myelin basic protein) 87-106, emulsified in IF A supplemented
with 200 micrograms of Mycobacterium tuberculosis and M. butyricum 8:1 and given
subcutaneously (s.c.) on days 0 and 7. Immediately after this "immunisation" and
48 hours later, mice received 200 nanograms of Bordetella pertussis toxin (intraperitoneally)
in PBS (protein baseline serum). Relapse was defined as a weight loss and
clinical worsening was characterised by at
Figure 1: This record of alarms in a baby over a period of five-and-a-half
months, from October 1987 to March 1988, reveals that the stress-induced
breathing pattern did not subside after 21 days following vaccine
administration.
Figure 2: Record of breathing in the form of histograms stacked up at an angle.
Figure 3: Record of breathing in the form of vertical bars.
least one full-grade clinical score after stable recovery, indicated by weight
gain and at least one full clinical score.
Without going into great detail, strong proliferation to the PLP 178-191 peptide
used to induce disease was detected as early as day 4 after "immunisation",
reaching a peak by days 9-11. At the time of remission, days 15-16, a
considerable decrease in proliferative capacity of lymph node cells was
detected. IFN-gamma (interferon gamma) production followed the same pattern;
some variability was observed between individual mice, but a relatively high
concentration was measured during the first 11 days, decreasing thereafter. The
highest concentration of IFN-gamma was measured at the time of disease onset, on
day 11. The response to PLP 178-191 gradually waned and was lowest at day 17,
which in almost all mice is a silent period of the disease. Days 22-25 were
characterised by an increase in IFN-gamma production again: this is the time
point which, in most mice, precedes detectable relapse.
Equally interesting are Takacs et al.'s immunological time dynamics from days 42
to 48, as established by our monitoring of stress response to vaccination in
babies. These are the days with increased stress level in breathing and
increased numbers of deaths after vaccination. The weight loss/weight gain
dynamics accompanying the above immunological challenge is equally relevant to
babies after vaccination. Leif's and my studies confirmed the validity of Hans
Selye's concept of nonspecific (or general adaptation) stress syndrome as a
characteristic but nonspecific response in mammals to any noxious substance or
insult or injury of any kind (Selye, 1978). However, since our recording of
breathing was done with a non-touch medical technology (Cotwatch had a sensor
pad positioned under the mattress and nothing was attached to the body of the
monitored person or an animal), we could record longitudinally for long periods
of time (hour-by-hour or day-by-day recording of stress dynamics in breathing),
while Selye studied the dynamics of adreno-cortical activity and had to perform
invasive blood tests which limited the density of his record. His research only
demonstrated the dynamics of stress response in very general terms as an alarm
reaction (48 hours after the insult), a stage of resistance (an undetermined
number of days after the first 48 hours) and a stage of exhaustion (another
alarm-like reaction) following the stage of resistance (of undetermined
duration) approximately corresponding to the 16th day. Our much more detailed
recording of stress response established that the alarm reaction is biphasic and
includes two flare-ups of stressed breathing, one on day 2 and another between
days 5 and 7, then followed by about seven days corresponding to the stage of
resistance, and the increased stress level around day 16 representing the stage
of exhaustion.
Vaccination and cot deaths
Figure 4: Record of breathing in the form of vertical bars, showing the stress
level in each baby before and after vaccination.
Figure 5: Tabulation of data on deaths after DPT and polio vaccination (Mitchell
et al.).
Figure 6: Tabulation of data from four groups of babies who died after DPT and
polio vaccinations (Griffin et al.).
Figure 5 represents tabulation of raw data on deaths after DPT and polio
vaccination published by Mitchell et al. (1995). These New Zealand authors
concluded that "there was a reduced chance of SIDS [sudden infant death
syndrome] in the four-day period after immunisation" and hence that immunisation
"may even lower the risk of SIDS" (though also saying that they cannot
confidently state it as a certainty).
However, far from showing protection against cot death by vaccination, Mitchell
et al.'s data show that all those babies they studied died as a direct
consequence of their DPT and OPV vaccination, showing perfect clustering along
the critical days. The "reduced" risk of SIDS in the "immunised" group is
misleading, because only those who received vaccines on schedule were
categorised as "immunised". Obviously this biases this group to be relatively
healthier children because a, or the, major reason for vaccines not being given
on time, and sometimes not ever again, is the child being unwell, at least when
the shots are due, if not constantly. So, ironically, a child who suffered
visible adverse effects from previous vaccines is likely to be in the "non-immunised"
category in this study, even if he or she received further vaccines.
Generally speaking, the most fundamental error of judgement displayed by cot
death researchers is that they do not look at what happened to the babies who
succumbed to SIDS, days before they died, and instead they try to identify the
elusive entity of "at risk" babies. The pneumographic studies are done without
any regard to what happens to babies in the first six months and/or one year or
18 months of life when the initial DPT, Hib and polio vaccines and the first MMR
and/or booster vaccines are given.
Vaccinations are mostly ignored in cot death studies. In our experience, the
timing of pneumographic studies is determined by the availability of a bed in
the overnight study unit rather than by looking at what happened to the baby
just before it developed symptoms of stress or started causing alarms on its
monitor.
The notion of false alarms, widely used by those who conduct monitoring of
babies' breathing, has also delayed the understanding of the situation. Alarms
which occurred when the monitored baby did not stop breathing but was breathing
very shallowly are considered false alarms. Leif and I called them "warning
alarms" because they sounded when the monitored babies started having longer and
longer episodes of low-volume breathing, which is the true stress-induced
breathing pattern. A baby who developed pneumonia experienced such "false
alarms" for two weeks before going down with typical symptoms of pneumonia. This
happened about six weeks after the six-month vaccination with DPT and polio
vaccines.
When reactions or deaths occur six weeks after vaccination, they would not be
considered as being caused by vaccination. Yet our records of alarms with
Cotwatch microprocessor computer printouts demonstrate increased stress level
in breathing more than six weeks after vaccination.
Deaths after vaccinations
Griffin et al.'s (1988) data on deaths after vaccination are of interest as
well. Even though the authors concluded that their data do not show the causal
link, a proper tabulation of their own raw data (figure 6), looking at four
groups of babies who died after DPT and polio vaccination, shows the following:
• Group 1 included babies aged 1.5-2.5 months (in the USA, vaccinations start at
6-8 weeks). The majority of these babies died within 8-14 days after the first
dose.
• Group 2 included babies aged 2.5-4 months, who died after the second dose of
DPT and OPV. The majority died between 15 and 30 days.
• Group 3 included babies aged 4-8 months, who died after the third dose. The
majority died more than 31 days after vaccination.
• Group 4 included babies who died aged 8-12 months. These are the residue of
delayed deaths after the third dose.
Far from showing no evidence of the causal link with the administration of DPT
and OPV vaccines, the tabulated raw data by Griffin et al. show three important
observed phenomena:
1. Younger babies died earlier than older, bigger babies who took longer to die.
2. Sensitisation: there was increased immunological reaction (anaphylaxis) after
subsequent doses of vaccines.
3. Increased numbers of deaths with the increasing interval from vaccination:
delayed reactions, which are a rule rather than an exception.
Interestingly, Torch (1982, 1986) independently also made the same observation
as Leif Karlson and I: an increasing number of deaths with the increasing
interval from the vaccine administration, increasing number of injections and
increasing age. Torch (1982) wrote: "Preliminary data on the first 70 cases
studied shows that 2/3 had been immunized within 21 days prior to death... In
the DPT SIDS group 6.5% died within 12 hours of inoculation, 13% within 24
hours, 26% within 3 days, and 37%, 61% and 70% within 1,2 and 3 weeks
respectively. Significant SIDS clustering occurred within the first 2 to 3
weeks of DTP #1,2,3 or 4. The age range in the DTP group was 59 days to 3
years..."
One of many points I am making here is that the recipients of a vaccine such as
DPT or OPV may react for more than 21 days after the vaccines are administered,
this being additional information to that published by Innis (2004). Innis puts
emphasis on the period of under 21 days from vaccination as a risk period for
the onset of symptoms that can lead to allegations of child abuse, based on the
22 cases that he has analysed to date.
Vaccines, such as that for pertussis, are actually used to induce so-called
experimental allergic encephalomyelitis (Levine et al., 1966; Levine and
Sowinski, 1979; Steinman et al., 1982; and many others). Steinman et al.
described an animal model for pertussis vaccination encephalopathy. They
vaccinated mice with the heat-killed Bordetella pertussis-vaccine combined with
bovine serum albumin (BSA). They concluded that neuropathology in their mouse
model resembled that of human cases in which death occurred after DPT
vaccination: diffuse vascular congestion and parenchymal haemorrhage in both the
cortex and white matter. Cortical neurons showed ischaemic changes, and areas of
hypercellularity were evident in the meninges.
B. pertussis has a wide range of physiological effects including increased IgE
production, increased sensitivity to anaphylactic shock, lymphocytosis and
hyperinsulinaemia. Its ability to induce increased vascular permeability may
account for the tendency to produce haemorrhages. The relevance of the murine
[i.e., mouse-related] model of pertussis vaccine encephalopathy is demonstrated
by most babies being exposed to cow's milk (even in breast-fed babies) due to a
pre-existing anti-BSA antibody. This sensitisation to BSA may lead to a similar
chain of events following pertussis vaccination in genetically susceptible human
babies.
When babies were only given four vaccines at one session (DPT and OPV), they
developed the so-called minimal pathology: petechial (spot-like) bleeding into
the thymus, pericardium, lungs and other organs and their deaths were classified
as SIDS (which should stand for "sudden immunisation death syndrome"). Such
pathology was considered insufficient to cause death, even though it was
obviously sufficient, considering that tens of thousands of babies have died
this way. According to Hess (1920) and many others, one of the symptoms of acute
scurvy is petechial haemorrhage. Why consider scurvy in post-vaccinal death?
Vaccines are a cocktail of toxic substances such as formaldehyde (interestingly,
when Selye discovered nonspecific stress syndrome, the first "noxious
substance" he injected into his laboratory rats was formaldehyde), aluminium
phosphate and aluminium hydroxide, mercury compounds (thimerosal, merthiolate,
containing up to 49% mercury), phenol, coolant (propylene glycol), peanut oil,
and of course foreign proteins (antigens), viruses and bacteria or their protein
envelopes (such as pertussigen, an active toxic ingredient in all pertussis
vaccines, whether whole cell or acellular), to mention just a few of the most
common, standard ingredients in a variety of vaccines.
Vaccination and shaken baby syndrome
As Dr Innis repeatedly stated in his comments to a variety of BMJ articles on
shaken baby syndrome (SBS), all of the SBS cases he studied were vaccinated
within 21 days of the appearance of symptoms of SBS or death. I second this with
a slightly qualified statement that among some 70-odd cases of SBS for which I
have prepared a report, only two were cases of birth injury and were
unvaccinated. Also, a few of the SBS babies died more than 21 days after their
last vaccinations. Indeed, days 42 to 48 after vaccination represent important
critical days with increasing numbers of deaths (as discussed above).
Most of those who have been involved in the study of SIDS or SBS, including
those who have participated in the present and very much needed BMJ.com
cathartic debate on SBS, have been rather shy or silent about the administered
vaccines, even though those vaccine injections are, as a rule, the only
documented facts. The act of shaking is undocumented and it is indeed (as Dr
Innis correctly states) a little more than a figment of bizarre imagination by
the accusing doctors, child protection agencies and police.
Some responders in this debate have questioned whether doctors are out to
victimise innocent carers. The simple answer is that they are. As pointed out by
Kirschner and Stein (1985): "...the treating physicians in the emergency room
mistook life-threatening illness or postmortem artifacts for inflicted injury...
Although the histories related by the parents in the emergency room were in all
cases truthful and consistent with the results of physical examinations of the
child, the involved physicians failed to make a correct diagnosis. Not only lack
of experience with severe childhood illness and death but also an attitude of
suspicion and/or hostility probably contributed to these misdiagnoses."
So what are the causes and mechanisms of what is considered the pathognomic
triad of symptoms by the proponents of SBS, such as subdural and retinal
haemorrhages and broken bones?
As I wrote in my previous papers on this subject (J ACNEM 2002; bmj.com Rapid
Responses. 2 April 2004: and elsewhere), the whole idea of subdural haematomas
and bizarre bone fractures as a result of child abuse was started by Caffey in
1946. He considered fractures in the long bones as a complication of the
infantile subdural haematoma associated with the fractures of the cranium. Even
though his own illustrations show what is generally considered typical scurvy
fractures, he denied any "Roentgen signs of scurvy". Caffey (1946), without
going into any more detail, concluded: "The fractures appear to be of traumatic
origin but the traumatic episodes and the causal mechanism remain obscure." It
is difficult to understand why such classical scurvy fractures as shown in his
own photographs were misinterpreted. However, Caffey admitted in his 1965
article, "Significance of the history in the diagnosis of traumatic injury in
children", that "it is still a wonder to me that Ross Golden welcomed me, a
pediatrician without either formal or informal training or experience in
radiology, into his department of traditionally and highly trained expert
radiologists". Indeed, why?
The fact remains that Caffey made a mess of things which will take years to
rectify. The sooner the rectification begins, the better not only for all those
thousands of victims of Caffey's obvious ignorance and closed mindedness but
also for those formally trained radiologists who blindly followed
misinterpretations of formally untrained Caffey. Moreover, Silverman (1965)
attested to Caffey's close mindedness when he wrote about Caffey: "A classic
example of his attitude...occurred at the end of a hot discussion at an 11
o'clock conference at Babies Hospital...when he was heard to remark to someone
with whom he had been debating a point, 'I wouldn't believe it even if you
proved it to me1."
Killer (1972), a formally trained Australian radiologist, demonstrated that
Caffey's bizarre fractures are in fact caused by scurvy, although he did not
explain what actually caused scurvy in the affected babies.
It was Hess (1920) who pointed out in his elegant, almost 300-page tome on
scurvy, which was much ahead of its time, the inadequacies of "antiscorbutic"
vitamin (vitamin C) content of the usual infant food..
Later on, Pekarek and Rezabek (1959) demonstrated that the administration of DPT
vaccine to rats caused them to develop acute scurvy which rectified itself
within 24 hours.
However, human babies do not have the advantage the rats have of being able to
produce their own vitamin C within their bodies; humans and other primates,
fruit bats and guinea pigs, to mention the most important examples, do not
produce their own vitamin C and depend on their food having adequate content of
this important, essential vitamin.
When human babies are given the same DPT vaccine as Pekarek and Rezabek's rats,
they develop acute scurvy which does not rectify itself unless the babies are
given sufficiently large amounts of vitamin C. This, of course, never happens
because when babies with vaccine reactions are admitted to hospitals they are
given antibiotics instead, further aggravating their vitamin C deficiency.
Scurvy affects all systems in the body. It causes depletion of collagen,
resulting in vascular wall fragility, blood clotting and other haematological
derangements resulting in bruising; it causes brain, retinal and other organ
bleeding and many other malfunctions of all systems of the body, including
derangement of the central control of temperature, blood pressure, etc.
Injecting foreign antigens (and other proteins) directly into the bloodstream
causes immunological derangements—among others, the reversal of T4 and T8 cells
ratio (Jefferys, 2001), which results in the whole cascade of untoward events
resulting in death. I am surprised that any babies survive the intense
vaccination programs they are subjected to these days. Others have mentioned
haemophagocytic lymphohistiocytosis (HLH) as the syndrome which is accompanied
by the same symptoms as SBS, without going into details as to what actually
causes HLH.
New diseases for old
Medicine is known for repeatedly introducing new names for old diseases. It is
probably due to the well-known failure of medical researchers to study medical
literature (yes, I've heard American medicos bragging in court that they don't
study "that stuff", meaning medical research, and in particular the foreign
Journals; as a matter of interest, they considered BMJ not worthy of their
scientific curiosity). This situation is relevant to the study of subdural and
retinal haemorrhages of SBS.
Sparacio et al. (1971) described acute subdural haematoma in infancy. They
described six cases in infants aged three months, 10 months, one year, 10
months, six months and nine months, of which two had a documented fall while the
rest did not.
Hart and Earle (1975) described haemorrhagic and perivenous encephalitis in a
clinical-pathological review of 38 cases. They wrote that haemorrhagic
leucoencephalitis (AHL) and post-infectious perivenous encephalitis (PVS)
associated with childhood mumps, measles, chickenpox and vaccination are
important diseases of the central nervous system.
Graham et al. (1979) described acute haemorrhagic (also known as necrotising)
leucoencephalitis as a complication of the generalised Schwartzman reaction
which may occur after sensitisation (anaphylaxis) to drugs, such as
sulphonamides and para-amino salicylic acid, and which has also followed
pertussis vaccination and the administration of the antitetanus serum.
Levin et al. (1983) described haemorrhagic shock and encephalopathy as a new
syndrome with a high mortality in young children. Interestingly, the children
from whom polio virus was isolated had all been recently vaccinated. This means
that other cases could have been vaccinated longer than a few days before
developing symptoms of haemorrhagic shock.
In the 1970's and 1980's, a number of authors described so-called
haemophagocytic syndrome or lymphohistiocytosis syndrome. The symptoms in
haemorrhagic shock and encephalopathy and HLH are very similar; general feeling
of malaise, fever, listlessness and vomiting, pallor, tachycardia, tachypnoea,
convulsions, low blood pressure, glove and sock syndrome (hot body and cold
extremities), distended abdomen, enlarged liver, tense fontanelle, hypotonia,
watery, blood-stained diarrhoea, haematemesis, liquid unclotting blood (bleeding
from venipuncture sites), deranged coagulation with deranged prothrombin and
thromboplastin time, very low fibrinogen and fibrin degradation products very
elevated, indicating severe disseminated intravascular coagulation. Other
characteristic findings are severe metabolic acidosis (pH less than 7.35 or even
less than 7), low bicarbonate, base deficit with compensatory respiratory
alkalosis, impaired renal function, raised plasma urea and creatinine and
especially hyperglycaemia, indicating central diabetes insipidus, cerebral
oedema and internal haemorrhaging into the brain, retina, lungs and other
organs, and diffuse macular cutaneous haemorrhages. All organs may be
infiltrated with lymphocytes and histiocytes. At necropsy, the brain is
oedematous, soft and virtually liquid. More severe cases have meningeal and
perivascular infiltration of lymphoid cells in the brain.
Akima and Sumi (1984) described a number of cases of babies aged six months,
four months, four-and-a-half months (readmitted at six-and-a-half months and
died 11 days after admission), five months (readmitted at eight months and died
two months later), six weeks of age with recurrence of symptoms at
four-and-a-half months of age (died at five-and-a-half months) and seven weeks
(died four days after admission to hospital). All cases clearly developed their
symptoms after vaccination, based on their ages at the first admission and the
time of readmission.
Some authors have called HLH a familial disease; however, this definition was a
reflection of the familial habit of vaccinating all children, rather than some
special familial genetic predisposition other then predisposition to react
violently to vaccines (Renter and Blinder, 1991).
Liao and Thompson (1997) described retinal haemorrhages as ophthalmic
manifestations of virus-induced haemophagocytic syndrome.
Renter and Blinder (1992) described cerebromeningeal haemophagocytic
lymphohistiocytosis as an immunological disorder, and Sperling (1997) described
it as a "runaway" immune system.
Rosen (1997) quoted a number of vaccines (vaccinia, polio, measles and BCG) as
the causal agents in HLH, and described the disease as a severe, combined
immunodeficiency.
Comans-Bitter et al. (1997) described immunotyping of blood lymphocytes in
childhood to be used as a yardstick in the diagnosis of haematological and
immunological disorders.
Bonilla and Oettgen (1997) analysed the above article and wrote that T cells, B
cells and natural killer (NK) cells interact with each other and with L a
diverse array of "accessory cells", such as monocyte-derived cells, to generate
an immune response. T cells may be identified by the CDS marker associated with
the antigen receptor and are further divided into two populations: CD4+ and
CD8+.
CD4+ T cells (also known as "cytotoxic" or "suppressor" cells) execute important
effector functions such as the lysis of infected host cells (part of the
cellular immune response). After interaction with CD4+ T cells, B cells give
rise to plasma cells which produce antibodies (the humoral immune response). The
NK cells are important in the early phases of immune responses to viruses and
malignancy.
Since vaccines derange these elements of the immune system, it is not difficult
to understand why they are implicated as causal agents in all those modern ills
of children, such as asthma and allergies, a number of cancers, gastrointestinal
problems, autism and other behavioural problems to mention just a few so-called
new diseases.
In summary, there is a wealth of scientific data to demonstrate that vaccines
cause serious derangements of all systems of the body, which result in serious
injuries, including deaths—and in babies in particular—being misinterpreted as
being caused by inflicted trauma. °°
About the Author:
Viera Scheibner, PhD, is a retired principal research scientist with a doctorate
in natural sciences. During her distinguished career she has written three books
and had over 90 papers published in refereed scientific journals. She has been
researching vaccines and vaccinations since the early 1980s and is the author of
Vaccination: 100 Years of Orthodox Research Shows that Vaccines Represent a
Medical Assault on the System (1993; reviewed in NEXUS 2/16) and Behavioural
Problems in Childhood (2000; reviewed in 7/05).
Dr Scheibner's article on the dynamics of critical days was first published in
the Journal of the Australasian College of Nutritional & Environmental Medicine
(J ACNEM) 23(3):1-5, December 2004.
Previous articles by Dr Scheibner on vaccines and vaccinations have been
published in NEXUS: "Adverse Effects of Adjuvants in Vaccines" (NEXUS 8/01-02),
"Shaken Baby Syndrome" (5/05); "Brain-eating Bugs" (3/03), and (with Leif
Karlsson) "Cot Deaths Linked to Vaccinations" (2/05).
Dr Scheibner is often asked by lawyers to provide expert reports for
vaccine-damage court cases, and she regularly conducts lectures. She was a
speaker at the 2005 NEXUS Conference in Brisbane in September.
Dr Scheibner can be contacted by mail at 178 Govetts Leap Road, Blackheath, NSW
2785, Australia, by telephone on +61 (0)2 4787 8203 or by fax on +61 (0)2 4787
8988. She is happy to provide additional references for this article as well as
accompanying diagrams on request.
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