Communication/review Biomath 1 (2012), 1210017, 1–5

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Volume ░, Number ░, 20░░ 

BIOMATH

 ISSN 1314-684X

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BIOMATH
h t t p : / / w w w . b i o m a t h f o r u m . o r g / b i o m a t h / i n d e x . p h p / b i o m a t h / Biomath Forum

Blagovest Sendov – Pioneer of Mathematical
Modeling in Bulgaria

Svetoslav Markov
Institute of Mathematics and Informatics-BAS

Acad. G. Bonchev st., block 8, 1113 Sofia, Bulgaria
Email: smarkov@bio.bas.bg

I. MY TEACHER PROF. SENDOV

In February 2012 Prof. Blagovest Sendov turned 80. I
first met him in 1963 as a student in mathematics at
the Department of Physics and Mathematics of Sofia
University. I was fascinated by his lectures in Numerical
Methods. His first lecture was devoted to Mathematical
modeling. On several realistic case studies Prof. Sendov
revealed what was to me the philosophy of science. This
lecture was crucial for my orientation in mathematical
research. I was deeply impressed and I started to collect
material for a book based on the ideas of Prof. Sendov,
which I published later on [14]. During the years that
followed, mathematical modeling became my main topic
of interest. Thanks to Prof. Sendov, I was equipped with
many useful ideas, tools and insights that I used in the
study of real-life problems. Prof. Sendov’s “philosophy”
included a deep understanding of the mechanisms of the
underlying real processes, the mathematical description
of these processes using contemporary mathematical
theories and the solution of the formulated mathematical
problems using advanced numerical and computational
tools.

An important area of mathematical applications is the
one of biology. In the sequei I shall try to briefly survey
Prof. Sendov’s achievements in the field of mathematical
modeling in biology and also mention his contributions
to the field of “Interval analysis”, which field is tightly
related to Sendov’s main topic of interest “Approxima-
tion theory” [25].

Prof. Sendov possesses the enormous ability to for-

mulate difficult tasks and problems, playing a key role
in mathematics and its applications, and requiring years
of efforts to be resolved. At his weekly seminar on
“Mathematical modeling” he used to pose such difficult
problems and to make us young collaborators enthusias-
tic about working on them. He never pressed anybody of
us to work on something particular, but he waited that
everyone himself/herself chooses a topic of interest.

II. THE CONTRIBUTIONS OF PROF. BLAGOVEST
SENDOV TO BIOMATHEMATICS

In the period 1965–1971 Prof. Sendov collaborated
actively with Prof. Dr. Roumen Tsanev, an excellent
molecular biologist, and also a very competent math-
ematician. In the summer of 1965 Prof. Sendov and Dr.
Tsanev began jointly to study a hypothetical mechanisms
for cellular proliferation, differentiation and carcinogen-
esis, suggested by Dr. Tsanev. The two scientists wanted
to establish whether a mechanism for cellular activity
based on interrelated genes is logically feasible. They
decided to use the newly installed computer in the
Institute of Mathematics at the Bulgarian Academy of
Sciences to study a model of cellular activity based on a
network of genes interrelated on the basis of equations
describing the synthesis of mRNA, controlled by DNA-
protein interactions and programming the ribosomes
for the synthesis of proteins. During the next several
years they had many discussions on the formulation
of a suitable mathematical model. Prof. Sendov tried
many formulations and performed multiple computer
experiments.

Citation: S. Markov, Blagovest Sendov – Pioneer of Mathematical Modeling in Bulgaria, Biomath 1 (2012),
1210017, http://dx.doi.org/10.11145/j.biomath.2012.10.017

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S. Markov, Blagovest Sendov – Pioneer of Mathematical Modeling in Bulgaria

The results of this active collaboration with lengthy
discussions and computer experiments led to several
modifications of the models, which were reported in
a series of joint papers [1]–[10]. These papers are
devoted to modeling of different biological objects such
as epidermis and liver, or different processes such as
cellular activity, cellular differentiation and carcinogen-
esis. The main result of the investigation was that the
process has to be controlled by an independent car-
rier of genetic information, which is not necessarily
semantically connected to the genetic information. This
independent carrier of information was postulated as
an epigenetic code. The mathematical model of living
cells in a multi-cellular organism, based on the existence
of an epigenetic code, was able to explain uniformly
the processes of embryonic development, cytodifferen-
tiation, vegetative reproduction, somatic embryogenesis,
carcinogenesis and even the emergence of new forms of
natural selection. All this is explained in [10] with more
than 300 references to experimental results showing good
agreement with the results produced by the mathematical
model.

During the next several years a number of scientific
papers are published, amongst them four papers in
the Journal of Theoretical Biology, a survey paper in
“Uspehi Mathematicheskih Nauk” and a monograph in
Russian.

The studies of Sendov and Tsanev can be subdivided
into four steps. The first step was to construct a math-
ematical model of living cells, based on the concept
of Jacob and Monod for the existence of conjugate
operons, working as a flip-flop. An operon has two
states: repressed as inactive and derepressed as active.
The mathematical realization of such flip-flop is by
formulating a well-known set of nonlinear differential
equations. The interaction between the different cells
in an organism and the role of the nuclear membrane
are important for eukaryotic cells. To this end a special
variable for the diffusion through the membrane has
been introduced. This variable depends on the functional
state of the cell. It is known that when the eukaryotic
cell enters in the mitotic cycle, the diffusion through its
dissolved membrane stops. So they added to the system
of differential equations, describing the activity of a cell,
some additional differential equations with discontinuous
right-hand side. The goal of this first model was to find
out whether it is possible to choose the constants in the
mathematical model of a system of synchronized cells,
which divide and interact between themselves by the
substances going through the membranes, in such a way

that they reach a homeostasis. The result of the computer
experiment is that the model is adequate under a suitable
choice of the model parameters. The results obtained
were in good agreement with the observed reaction of
real tissues, such as the epidermal tissue, which was
studied extensively by Dr Tsanev.

On the second stage a model of non-synchronized
cells imitating the liver was constructed [11]. This model
demonstrated a good agreement with experimental data,
especially the reaction after a “partial hepatectomy”. All
this was achieved on the basis of the idea for repression
and derepression.

The third stage was to model the mechanism of
cytodifferentiation. Here the two scientists introduce
the mechanisms of blocking and deblocking of the
operons. In this situation, every operon has four dif-
ferent states: repressed-blocked, repressed-deblocked,
derepressed-blocked and derepressed-deblocked. Only in
the state derepressed-deblocked, the operon is active. To
test these mechanisms, they constructed a mathemati-
cal model of a set of cells, which interacted between
themselves. Every cell in the model has eight operons,
one mitotic, responsible for the division of the cell, and
seven functional operons. Every operon, when active,
produces substances which may repress or deblock an-
other operon. This interconnection between the operons
is prescribed in the model by a matrix and represents
the meaning of the epigenetic code. In other words, the
existence of an epigenetic code means that the operons
in a cell form a genetic network. Different types of cells
in a organism have the same genetic information and
differ by the set of blocked operons.

To define the interaction between the cells, a special
geometrical arrangement of the cells has been proposed
and the place of a new cell produced after division is
prescribed. To make it simple, a population of cells
called “Cylindros” has been created. To avoid the three
dimensional geometry, an infinite cylinder is considered
and a plane intersection of it is studied. Thus the Cylin-
dros was a ring of two-dimensional cells on the plane
with an interior space in the middle. The diffusion of
all substances produced in the cells was possible only in
the middle space and between the neighbor cells. In this
way, the interaction between different cells was fulfilled.
After division of a cell, the two new cells stayed on the
same place on the ring as neighbors.

Choosing a particular matrix for the genetic net in
the Cylindros, all important behaviors as embryonic de-
velopment, cytodifferenciation, vegetative reproduction,
somatic embryogenesis and carcinogenesis have been

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S. Markov, Blagovest Sendov – Pioneer of Mathematical Modeling in Bulgaria

demonstrated.
Mathematically the Cylindros was a system of ordi-

nary differential equations of first order with discontin-
uous right hand sides and the number of the equations
in this system depended on the time.

On the fourth stage of the study Prof. Sendov analyzes
the system of ordinary differential equations for stability
with respect to the number of the equations [11]–[12].
He shows that if the system is not stable, which means
that the number of the equations goes to infinity, this case
can be physiologically interpreted as cancerogenesis.

The collaborative work of Sendov and Tsanev is a
typical example of tight interaction between the two
sciences biology and mathematics. On one side biology
benefits from mathematics, on the other side mathe-
matics also benefits, as novel interesting problems and
suitable tools for their solution appear. Such a tool is the
analysis of Hausdorff-continuous functions and interval
analysis. The contributions of Prof. Sendov to Hausdorff
approximations are well known. Here I would like to
mention some of his contributions to interval analysis.

III. NOVEL TOOLS FOR MATHEMATICAL MODELING

In many instances Sendov–Tsanev models make use of
partially continuos functions of one variable, that is func-
tions which are continuous in certain subintervals of their
domain and have “jumps” in between. A typical such
function is the Heaviside step function (function “jump”)
s(x) = {0, x < 0; 1, x ≥ 0}. Another famous function
is the Dirac’s function: δ(x) = {0, x 6= 0; 1, x = 0}.
The interest of Prof. Sendov to such functions is well
known. It can be assumed that it is this interests that led
him to numerous results about these functions, and many
scientific papers and books, in particular the integrated
“Theory of Hausdorff Approximations” developed by
him [25]. Sendov’s approach to such functions is to
consider their complete graphs by filling the jumps by
intervals. Thus the complete graphs of the functions s
and δ are interval functions defined resp. as follows:
s(x) = {0, x < 0; [0, 1], x = 0; 1, x > 0}, δ(x) =
{0, x 6= 0; [0, 1], x = 0}. Then Sendov measures the
distance between the complete graphs and the approx-
imating function using the Hausdorff distance between
the graphs as plane sets. A famous result obtained by
prof Sendov in 1964 is that the Heaviside step function
and the Dirac’s function (and any bounded function in
fact) can be approximated by algebraic polynomials of
order n in Hausdorff metric with accuracy: C.(ln n/n),
C = const. An important role in Sendov’s theory of
Hausdorff Approximations is played by the so-called

Hausdorff continuous functions, which are a special case
of interval functions. In this way the theory of Hausdorff
aproximations is tightly related to interval analysis.

Incidentally, the first difficult problem that was given
to me by Prof. Sendov in my master thesis about finding
a numerical algorithm for the Hausdorff approximation
of the Heaviside step function using algebraic polynomi-
als. At that time we performed numerical computations
related to this problem using computer [13]. Many papers
have been devoted to this problem, untill successfully
solved [16]. The numerical approximation of functions
like s and δ still caue difficulties on contemporary
computer platforms [15].

The investigations in the field of interval analysis were
initiated by Prof. Sendov during 1976-1980. Interval
functions have often been discussed in relation to Haus-
dorff approximations at Sendovs seminar on Approxima-
tion Theory held regularly at the Institute of Mathematics
since 1964. Numerical computations related to the best
polynomial Hausdorff approximations of certain interval
functions require special attention to round-off errors.
In 1975 Sendov, who was my PhD supervisor, gave me
reprints of papers by T. Sunaga, H. Ratschek and G.
Schroeder on interval arithmetic and differentiation of
interval functions. I was very impressed by these papers,
especially by the famous paper by T. Sunaga, which I
studied thoroughly and later on I published (jointly with
K. Okumura) a review of this extraordinary paper [17].

In the years to follow Prof. Sendov actively worked in
the field of interval analysis and published several papers
on the so-called S-limit and S-derivative of interval
functions — terms that are tightly related to the theory
of Hausdorff approximations, [18]–[20].

In this papers Sendov established a theory for analysis
of interval functions. His studies have been continued by
some of his many collaborators and during the years a lot
of scientific papers have been published. Here I would
like to mention some of the developments about the
relations between Hausdorff continuous functions and
interval analysis obtained in the past decade thanks to a
new property established in 2004 by Roumen Anguelov.

The above mentioned novel property is that the set
of Hausdorff-continuous functions is complete after
Dedekind with respect to the familiar order relation.
Let us note that the familiar functional spaces such as
the space of continuous functions, the Sobolev spaces
etc, with very few exceptions, are incomplete w.r.t. the
order relation. Thus, a possibility appeared to solve a
number of open problems in real analysis and the general
theory of PDE or to improve previous results using

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S. Markov, Blagovest Sendov – Pioneer of Mathematical Modeling in Bulgaria

Hausdorff continuous functions. An important result is
the introduction of algebraic operations with Hausdorff-
continuous functions and their application for numerical
computations.

Let us mention that Hausdorff continuous functions
form a special class of interval functions. It is well-
known that interval functions do not form a linear space.
Thus it is an important fact that the algebraic operations
for addition and multiplication by scalars in the set of
continuous functions can be extended over the set of
Hausdorff-continuous functions in such a way that they
form a linear space. In several papers (jointly with Prof.
Sendov) it has been shown that the space of Hausdorff
continuous functions is the largest linear space of interval
functions [21]–[23]. The obtained results have been
applied to numerical computations [24].

IV. THE CONFERENCE BIOMATH-2012

During the years Prof. Sendov supported the bio-
mathematical research in the Bulgarian Academy of
Sciences. He co-chaired the first international conference
BIOMATH 1995 [26] and took active part in many
biomathematical workshops and seminars held at the
Academy.

The present conference BIOMATH-2012 [27] proves
that the pioneering work of Prof. Sendov in the field of
mathematical modelling is alive. Our wish is the BIO-
MATH Conferences to become a forum for biologists
and mathematicians, chemists and physicists, computer
scientists and others, working together as partners in
research connected with living organisms and the ap-
plications of the results to medicine, biology, ecology,
agriculture and elsewhere. It is natural in such collabo-
rations that the leading ideas come from the biologists.
However, success depends on the abilities of both sides,
especially when complicated mathematical models are
involved.

In this article we tried to outline part of Prof. Sendov’s
activities related to Mathematical Modelling. The inter-
ested reader may find more about Prof Sendov’s activities
in the article [27] where also some of his contributions
to Bulgarian education are presented in some detail.

Let us wish Prof. Sendov good health and still more
future success in his scientific and social activities.

REFERENCES

[1] Tsanev, R. and Bl. Sendov: A model of the regulatory mech-
anism of cellular proliferation, C. r. Acad. Bulgare Sci., 19,
(1966), no. 9, 835–838.

[2] Tsanev, R. and Bl. Sendov: A model of the regulatory mech-
anism of cellular multiplication, J. Theoret. Biol., New York,
12, (1966), 327–341.

[3] Sendov, Bl. and R. Tsanev: Modeling of the regulatory mecha-
nism of the cellular proliferation in the liver, Central. Biochem.
Lab. BAS, 3, (1968), 21–35 (in Bulgarian).

[4] Tsanev, R. and Bl. Sendov: Computer studies on the mechanism
controlling cellular proliferation, in: Effects on radiation on
cellular proliferation and differentiation. Vienna, Int. Atomic
Energy Agency. 1968, 453–461.

[5] Sendov, Bl. and R. Tsanev: Computer simulation of the regen-
erative processes in the liver, J. Theoret. Biol., New York, 18,
(1968), 90–104.

[6] Sendov, Bl. and R. Tsanev: Computer simulation of the regula-
tory mechanisms of cellular proliferation, Inform. Processing,
Amsterdam, 68 (1969), 1506–1507.

[7] Tsanev, R. and Bl. Sendov: A model of cancer studies by a
computer, J. Theoret. Biol. 23, (1969), 124–134.
http://dx.doi.org/10.1016/0022-5193(69)90071-X

[8] Tsanev, R. and Bl. Sendov: A possible mechanism for cellular
differentiation, C. r. Acad. Bulgare Sci., 22, (1969), no. 12,
1433–1436.

[9] Sendov, Bl., R. Tsanev and E. Mateeva: A mathematical model
of the regulation of cellular proliferation of the epidermis, Izv.
Math. Inst., BAS, 11, (1970), 221–246.

[10] Tsanev, R. and Bl. Sendov: Possible molecular mechanism for
cell differentiation in multicellular organisms, J. Theoret. Biol.,
New York, 30, (1971), 337–193.

[11] Sendov, Bl.: Mathematical models of the cellular proliferation
and differentiation, Uspehi Math. Nauk, Moscow, 31 no. 3,
(1976), 255–256 (in Russian).

[12] Sendov, Bl.: Mathematical models of the processes for cellular
proliferation and differentiation, Publ. Moscow University, 1976
(in Russian).

[13] Markov, S., Bl. Sendov, On the numerical computation of a
class of polynomials of best approximation, Ann. Univ. Sofia,
Math. Fac., 61, 1966/67, 17-27 (in Bulgarian).

[14] Markov, S., Mathematical Modeling, Nauka i Izkustvo, Sofia,
1977. (In Bulgarian).

[15] Dimitrova, N., S. Markov, Verified Computation of Fast De-
creasing Polynomials, Reliable Computing 5 (3), 229–240,
1999.
http://dx.doi.org/10.1023/A:1009972120539

[16] Ivanov, K., V. Totik, Fast decreasing polynomials, Constructive
Approximations 6 (1990), 1–20.
http://dx.doi.org/10.1007/BF01891406

[17] Markov, S., K. Okumura, The contribution of T. Sunaga to
interval analysis and reliable computing, In: Csendes, T. (Ed.),
Developments in Reliable Computing, Kluwer, 1999, 167-188.

[18] Sendov, Bl., Segment arithmetic and segment limit. C. R. Acad.
bulg. sci., 1977, 30, 955-968.

[19] Sendov, Bl., Segment derivatives and Taylor’s formula. C. R.
Acad. bulg. sci., 1977, 30, 1093-1096.

[20] Sendov, Bl., Some topics of segment analysis. In: Interval
Mathematics’80 (Ed. by K. Nickel), Academic Press, 1980,
236–245.

[21] Anguelov, R., S. Markov, Bl. Sendov, On the Normed Linear
Space of Hausdorff Continuous Functions, Lecture Notes in
Computer Science 3743, Springer, 2005, 281–288;

[22] Anguelov, R., S. Markov, Bl. Sendov, The Set of Hausdorff
Continuous Functions - the Largest Linear Space of Interval
Functions, Reliable Computing 12 (2006), 337–363;

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http://dx.doi.org/10.1016/0022-5193(69)90071-X
http://dx.doi.org/10.1023/A:1009972120539
http://dx.doi.org/10.1007/BF01891406
http://dx.doi.org/10.11145/j.biomath.2012.10.017


S. Markov, Blagovest Sendov – Pioneer of Mathematical Modeling in Bulgaria

[23] Anguelov, R., S. Markov, Bl. Sendov, Algebraic operations on
the space of Hausdorff continuous interval functions, In: B. D.
Bojanov (Ed.), Constructive theory of functions, Varna 2005,
Prof. Marin Drinov Academic Publ. House, 2006, 35–44.

[24] Anguelov, R., S. Markov, Numerical Computations with Haus-
dorff Continuous Functions, In: T. Boyanov et al. (Eds.), NMA
2006, Lecture Notes in Computer Science 4310, 2007, 279–286.

[25] Sendov, Bl., Hausdorff Approximations, Kluwer, 1990.

http://dx.doi.org/10.1007/978-94-009-0673-0
[26] http://www.biomath.bg/1995/BIOMATH95.php
[27] http://www.biomath.bg/2012
[28] Kenderov, P, A. Andreev, S. Dimova, S. Markov, Academician

Blagovest Sendov at 80, In: J. Revalski (Ed.) Mathematics and
Education in Mathematics, Sofia, UMB, 7–22 (In Bulgarian).

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http://dx.doi.org/10.1007/978-94-009-0673-0
http://www.biomath.bg/1995/BIOMATH95.php
http://www.biomath.bg/2012
http://dx.doi.org/10.11145/j.biomath.2012.10.017

	 My Teacher Prof. Sendov 
	 The Contributions of Prof. Blagovest Sendov to Biomathematics
	Novel Tools for Mathematical Modeling
	The Conference BIOMATH-2012
	References