Surgical suture abstract
The application concerns surgical suture coated with one or more
biologically active compounds. The application discloses methods
of making coated suture, placing the coated suture in an organism,
and methods of using the coated suture in the treatment of diseases
such as cancer.
Surgical suture claims
What is claimed is:
1. A method of coating surgical suture with a biologically active
compound comprising: placing a length of surgical suture into a
solution comprising the biologically active compound; and incubating
the suture in the solution until the biologically active compound
is bound to the suture.
2. The method of claim 1 wherein the surgical suture is selected
from the group consisting of polyester suture, vicryl suture, nylon
suture, plain gut suture, polyglactin suture, chromic gut suture
and silk suture.
3. The method of claim 1 wherein the solution is phosphate buffered
saline.
4. The method of claim 3 wherein the phosphate buffered saline
is Ca.sup.2+ and Mg.sup.2+ free.
5. The method of claim 1 wherein the incubation is carried out
for about 18 hours.
6. The method of claim 1 wherein the incubation is carried out
at about 37.degree. C.
7. The method of claim 1 wherein the solution comprises about 2
.mu.g/ml of the biologically active compound.
8. The method of claim 1 wherein the biologically active compound
is defensin.
9. The method of claim 1 wherein the biologically active compound
is an antibody.
10. The method of claim 9 wherein the antibody is a monoclonal
antibody.
11. The method of claim 9 wherein the biologically active compound
is selected from the group consisting of .alpha.CD3 and .alpha.CD28
antibodies.
12. The method of claim 1 wherein the suture is coated with two
or more biologically active compounds.
13. The method of claim 12 wherein the suture is coated with .alpha.CD3
and .alpha.CD28 antibodies.
14. The method of claim 1 further comprising modifying the suture
such that it is visible on a radiograph.
15. A method of placing a surgical suture coated with one or more
biologically active compounds into a patient comprising: passing
a needle with a trochar into the desired location in the patient;
removing the trochar; passing the suture down the barrel of the
needle; removing the needle over the suture while leaving the suture
in position.
16. The method of claim 15 wherein the position of the needle is
determined prior to removing the needle.
17. The method of claim 16 wherein the position of the needle is
determined by a technique selected from the group consisting of
manual palpation, ultrasound, CT scan and radiography.
18. The method of claim 15 additionally comprising securing the
proximal end of the suture to the skin of the patient.
19. The method of claim 15 wherein the suture is labeled such that
it is visible on a radiograph.
20. The method of claim 19 further comprising determining the location
of the suture with a radiograph.
21. A method of reducing rejection of transplanted organs comprising
placing a suture coated with an immunosuppressive compound into
the organ bed or regional lymphatics of a patient receiving a donor
organ.
22. The method of claim 21 wherein the suture is coated with an
immunosuppressive antibody.
23. The method of claim 22 wherein the suture is coated with .mu.CD3
monoclonal antibody.
24. The method of claim 21 wherein the suture is placed in the
pelvic lymph node of the patient.
25. A surgical suture coated with at least one biologically active
compound.
26. The suture of claim 25 wherein the biologically active compound
is selected from the group consisting of antibiotic, anti-fungal,
anti-malarial, anti-tubercular, anti-viral and anti-microbial compounds.
27. The suture of claim 25 wherein the biologically active compound
is defensin.
28. The suture of claim 25 wherein the biologically active compound
is selected from the group consisting of the epitope specific sequences
p53 E75 E6 E7 and EBV associated antigens.
29. The suture of claim 25 wherein the biologically active compound
is an antibody.
30. The suture of claim 29 wherein the antibody is selected from
the group consisting of anti-CD3 anti-CD28 anti-CD40 anti-CD40L
and 41-BB.
31. The suture of claim 25 wherein the suture is non-covalently
coated with the biologically active compound.
32. The suture of claim 31 wherein the suture is coated with anti-CD28
and anti-CD3 antibodies.
33. The suture of claim 25 wherein the suture is modified such
that it is visible on a radiograph.
34. A method of treating a patient suffering from a disease that
is characterized by suppression of the immune system comprising
placing a suture coated with one or more immuno-stimulating compounds
into a lymph node in the patient.
35. The method of claim 34 wherein the suture is coated with anti-CD3
and anti-CD28.
36. The method of claim 34 wherein the disease is cancer.
37. A method of treating a patient suffering from head and neck
cancer comprising: placing a first suture coated with human defensin
into a palpable regional lymph node; and placing a second suture
coated with anti-CD3 and anti-CD28 antibodies into a palpable regional
lymph node.
38. The method of claim 37 wherein the first suture is removed
prior to placing the second suture.
39. The method of claim 37 additionally comprising placing a third
suture in the palpable regional lymph node, said third suture being
coated with antigens specific to the type of cancer that the patient
is suffering from.
40. The method of claim 39 additionally comprising placing a fourth
suture in the palpable regional lymph node, said fourth suture being
coated with anti-CD3 and anti-CD28 antibodies.
41. The method of claim 37 wherein the head and neck cancer is
head and neck squamous cell carcinoma.
42. The method of claim 37 additionally comprising: removing the
palpable regional lymph node during tumor resection; expanding the
lymph-node lymphocytes in vitro; and infusing the expanded lymphocytes
into the patient.
43. A method of adoptive immunotherapy comprising: placing a suture
coated with one or more immuno-stimulating molecules into the lymph
node of a patient; removing the lymph node of the patient; expanding
the lymph-node lymphocytes in vitro; and infusing the expanded lymphocytes
into the patient.
44. The methods of claim 43 wherein the suture is coated with anti-CD3
and anti-CD28.
45. A method of expanding lymphocytes in vitro comprising contacting
the lymphocytes with surgical suture coated with anti-CD3 and anti-CD28.
46. A method of treating cancer in a patient comprising: surgically
resecting the tumor; and placing a suture coated with an immuno-modulating
compound in the floor of the wound created by the resection.
47. The method of claim 46 wherein the suture is coated with anti-CD3
and anti-CD28 monoclonal antibodies.
48. The method of claim 46 additionally comprising placing a suture
coated with anti-microbial compounds in the wound.
Surgical suture description
RELATED APPLICATION
[0001] The present application claims the benefit under 35 U.S.C.
.sctn.119(e) of U.S. Provisional Application No. 60/246543 filed
Nov. 6 2000.
BACKGROUND OF THE INVENTION
[0002] 1. Field of the Invention
[0003] The present invention relates to surgical suture coated
with one or more biologically active compounds. More particularly
the present invention relates to methods of producing biologically
active suture, placing biologically active suture in a patient and
using biologically active suture in the treatment of disease.
[0004] 2. Background
[0005] The induction of a T-cell immune response by antigen-presenting
cells (APCs) occurs in three distinct stages. In the first stage,
a nonspecific adhesion occurs when APCs and T-cells randomly interact
in the circulation and in lymphoid tissues. Cell surface ligands
and adhesion receptors mediate the adhesion. Adhesion is followed
by recognition when the antigen-major histocampatibility complex
of the APC crosslinks with the T-cell receptor (TcR). Thus the APCs
must first process, transport, and present a sufficient quantity
of a specific antigen. Endogenous peptides (derived from intracellular
proteins) are generally presented with MHC class I (HLA-A, B, or
C), whereas exogenously processed peptide antigens (derived from
circulating proteins) are generally presented with MHC class II
(HLA-DR, DP, or DQ). The final stage occurs when a second or costimulatory
signal is provided by the APC to the T-cell, enhancing activation.
[0006] The best-characterized second signal for T-cell activation
occurs via interaction between the B7.1 or B7.2 ligand of the APCs
and CD28 of the T-cell. CD28 is a 44 kDa subunit found on the surface
of most CD4.sup.+ cells and 70% of CD8.sup.+ cells. The immune response
initiated may be characterized as a type 1 (T.sub.H1) or 2 (T.sub.H2)
response based on the cytokines secreted from the CD4.sup.+ cells.
A T.sub.H1 response is characterized by the secretion of inter-leukin
2 (IL-2), tumor necrosis factor .alpha. (TNF.alpha.) and interferon
.gamma. (IFN-.gamma.) and represents a cytotoxic response against
cancer or microbes. A T.sub.H2 type response is characterized by
the secretion of IL-4 IL-5 IL-6 IL-10 and IL-13 and enhances
antibody production from B cells as well as an allergic response.
Anti-CD28 (.alpha.CD28 or 9.3) monoclonal antibodies (MoAbs) can
substitute for the B7 ligands to stimulate CD28 and to provide a
strong stimulatory signal to T-cells (Hara et al. J. Exp. Med. 161:513-1524
(1985)). Costimulation also lowers the concentration of anti-CD3
(.alpha.CD3) required to induce a proliferative response in culture.
[0007] The generation of cytotoxic T lymphocytes (CTLs) by .alpha.CD3/.alpha.CD28
costimulation has been established (Azuma et al. Curr. Top. Microbiol.
Immunol. 198:59-74 (1995)). One of the advantages of costimulation
with anti-CD3/anti-CD28 has been resistance to immunosuppression,
such as that seen in patients with head and neck squamous cell carcinoma
(HNSCC). A "hierarchy of immunosuppression" exists in
HNSCC patients. Immune reactivity as measured by proliferation,
cytotoxicity, and natural killer (NK) cell activity is maximally
suppressed in tumor infiltrating lymphocytes (TIL), followed by
proximal lymph node lymphocytes (LNL), distal LNL and peripheral
blood lymphocytes (PBL) (Wang et al. Otolaryngol. Head Neck Surg.
105:517-527 (1991)). The function of NK cells from regional lymph
nodes is also inhibited. TIL, LNL, and PBL activity is significantly
less in HNSCC patients than controls. In particular, IL-2 induced
cytotoxicity is suppressed in LNLs proximal to the tumor compared
to LNLs distal to the tumor.
[0008] Co-activation of resting T-cells with .alpha.CD3/.alpha.CD28
has enhanced proliferation, cytokine production, and cytotoxicity.
.alpha.CD3/.alpha.CD28 costimulation enhances expression of IL-1.alpha.,
IL-2 IFN-.gamma., GM-CSF, lymphotoxin, and chemokines. Several
of these cytokines have demonstrated benefit in the treatment of
HNSCC. Costimulation also enhances the production of lymphokines
by CD4.sup.+ cells through transcriptional and post-transcriptional
regulation of gene expression.
[0009] The cytolytic activity of .alpha.CD3/.alpha.CD28 activated
cells is from small resting T-cells and CD4.sup.+ cells. The lymph
nodes of HNSCC patients are filled with small resting T-cells and
CD4.sup.+ cells that have tremendous potential for transformation
into anti-tumor cytotoxic T-lymphocytes. Thus patients with HNSCC
are prime candidates for an effective, targeted treatment with .alpha.CD3
and .alpha.CD28.
[0010] Anti-viral effects of .alpha.CD3/.alpha.CD28 have also been
identified. CD4.sup.+ T-cells from HIV+ patients have been activated
and expanded ex vivo using .alpha.CD3/.alpha.CD28 coated beads.
HIV-1 viral load declined in the expanded T-cell population in the
absence of any anti-retroviral agents. Additionally, .alpha.CD3/.alpha.CD28
stimulated CD4.sup.+ T-cells, from uninfected donors, appear to
be resistant to HIV-1 infection.
[0011] The therapeutic efficacy of T-cells activated by costimulation
with .alpha.CD3/.alpha.CD28 is being evaluated in patients with
melanoma, lymphoma and various solid tumors (Renner et al. Science
264:833-835 (1994)). For example, T-cells have been stimulated ex
vivo with .alpha.CD3/.alpha.CD28 immobilized on magnetic beads or
tissue culture plastic and used in adoptive immunotherapy trials
(Levine et al. Science 272:1939-1943 (1996); Thompson et al. Proc.
Natl. Acad. Sci. U.S.A. 86:1333-1337 (1989)). Immobilized .alpha.CD3/.alpha.CD28
is used because it has been found that .alpha.CD3 and .alpha.CD28
have a stronger immunologic effect when they are immobilized. However,
there are several problems with .alpha.CD3/.alpha.CD28 immobilized
on beads or plastic. For example, if stimulation is done ex vivo,
there are risks of contamination and infection. If the stimulation
is done in vivo, it is difficult to remove the beads if an undesired
reaction occurs. Because the beads are small, it is not feasible
to remove them individually. Removal thus requires an invasive surgical
procedure and often requires the removal of tissue along with the
beads.
[0012] Surgical suture is ordinarily composed of an inert substance,
and was created for the purpose of closing wounds. It is commonly
used to facilitate wound healing by the approximation of tissues.
Suture may be resorbable or permanent in nature depending upon the
type of material from which it is made. Suture is typically designed
to cause minimal tissue reaction, so wound healing is not impaired
by its presence.
SUMMARY OF THE INVENTION
[0013] One aspect of the present invention is a method of coating
surgical suture with one or more biologically active compounds.
A length of surgical suture is placed into a solution comprising
the biologically active compounds and the suture is incubated in
the solution until the biologically active compounds are bound to
the suture.
[0014] The suture used may be selected from the group consisting
of polyester suture, vicryl suture, nylon suture, plain gut suture,
polyglactin suture, chromic gut suture and silk suture.
[0015] The solution in which the suture is incubated may be phosphate
buffered saline. In another embodiment the phosphate buffered saline
is Ca.sup.2+ and Mg.sup.2+ free.
[0016] The incubation may be carried out for 18 hours. In another
embodiment the incubation is carried out at 37.degree. C.
[0017] In one embodiment the biologically active compounds are
present in the solution at a concentration of 2 .mu.g/ml.
[0018] At least one of the biologically active compounds may be
a monoclonal antibody. In one embodiment the biologically active
compounds are .alpha.CD3 and .alpha.CD28.
[0019] Another aspect of the present invention is a method of placing
a surgical suture coated with one or more biologically active compounds
into a patient. A needle with a trochar is passed into the desired
location in the patient. The trochar is removed and the suture is
passed down the barrel of the needle. The needle is then removed
over the suture, leaving the suture in the desired position.
[0020] In one embodiment the position of the needle is determined
prior to its removal from the patient. The position of the needle
may be determined by manual palpation, ultrasound, CT scan or radiograph.
In another embodiment the suture itself is labeled such that its
location can be determined by radiography.
[0021] In yet another embodiment the proximal end of the suture
is secured to the skin of the patient.
[0022] Another aspect of the invention is a method of reducing
rejection of transplanted organs. A suture coated with one or more
immunosuppressive compounds is placed in the organ donor bed or
the regional lymphatics of a patient. The suture may be coated with
an antibody. In one embodiment the antibody is .alpha.CD3.
BRIEF DESCRIPTION OF THE DRAWINGS
[0023] FIG. 1 A, B and C present the .sup.3H-thymidine incorporation
of representative normal peripheral blood mononuclear cells after
exposure to a monofilament nylon suture (A), chromic gut suture
(B) or plain gut suture (C). .sup.3H-thymidine incorporation increased
the most following exposure to nylon suture coated with .alpha.CD3
and .alpha.CD28 monoclonal antibodies.
[0024] FIG. 2A and B show the proliferative response of peripheral
blood mononuclear cells to monofilament nylon suture either uncoated
(A) or coated with .alpha.CD3/.alpha.CD28 monoclonal antibodies
(B).
[0025] FIG. 3 presents the proliferative responses on day 6 of
LNMCs and PBMCs from 11 patients with head and neck squamous cell
carcinoma and PBMCs from 6 normal subjects. PBMC indicates peripheral
blood mononuclear cells and LNMC indicates lymph node mononuclear
cells. The large bar is the PBMC mean, the large circle is the normal
control PBMC mean and the large triangle is the LNMC mean.
[0026] FIG. 4 shows the phenotype of T-cells on days 0 and 6 after
anti-CD3/anti-CD28 nylon suture stimulation. All data are given
as the mean .+-. the standard deviation. The dagger indicates a
significant increase on day 6.
[0027] FIG. 5 shows cytokines present on day 6 following stimulation
of patients with HNSCC with .alpha.CD3/.alpha.CD28 nylon suture
or plastic. The dagger represents a significant increase above untreated
controls. The double dagger represents a significant increase above
coated plastic stimulation.
[0028] FIG. 6 shows cytokines present on day 6 after stimulation
of controls with .alpha.CD3/.alpha.CD28 nylon suture or plastic.
The dagger represents a significant increase above untreated controls.
NT indicates an untested value.
[0029] FIG. 7 demonstrates the cytotoxicity of .alpha.CD3/.alpha.CD28
stimulated lymph node lymphocytes and peripheral blood lymphocytes
to autologous tumor cells. The effector:target (E:T) ratio is presented
on the X-axis and represents the ratio of stimulated effector cells
to tumor cells.
[0030] FIG. 8 shows the proliferation of lymph node lymphocytes
along nylon (A) and polyester (B) suture coated with anti-CD3 and
anti-CD28 monoclonal antibody.
[0031] FIG. 9 demonstrates the proliferation of peripheral blood
lymphocytes in response to nylon suture coated with anti-CD3 and
anti-CD28 monoclonal antibodies and polyester suture coated with
interferon-gamma.
[0032] FIG. 10 shows that anti-interferon-PE binds to polyester
suture coated with interferon-gamma (B), but not to control polyester
suture (A).
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT
[0033] The present invention is based on the discovery that suture
can be coated with one or more biologically active compounds, for
example antibodies (Abs). The resulting coated suture is a "bioactive
surgical suture." The compounds maintain their biological activity
when present on the suture.
[0034] The term "antibody" is used in the broadest sense
possible and covers, without limitation, monoclonal antibodies (including
agonist, antagonist, and neutralizing antibodies), antibody compositions
with polyepitopic specificity, single chain antibodies, and fragments
of antibodies. The term "monoclonal antibody" as used
herein refers to an antibody wherein the individual antibodies comprising
the population are identical except for possible naturally occurring
mutations that may be present in minor amounts.
[0035] "Coated suture" refers to a piece of surgical
suture that has been coated with one or more biologically active
compounds according to the methods of the present invention. The
suture is "coated" if one or more molecules of a biologically
active compound are bound to the suture. Preferably, the biologically
active compound is non-covalently bound to the suture.
[0036] The suture used in the present invention may be made of
any material known in the art. The suture material is preferably
vicryl, polyester, nylon, polyglactin, chromic gut, plain gut or
silk. More preferably the suture material is nylon. The suture may
be of any length. In one embodiment the suture is 1 cm in length.
Preferably the suture is long enough to reach from the site of placement
to the surface of the skin of the organism in which it is placed.
[0037] The suture may be of any thickness. Preferably the suture
is 3-0 suture.
[0038] One aspect of the present invention provides a method of
coating suture with one or more biologically active compounds. The
"biologically active" or "bioactive" compounds
used in the present invention may be any compounds that produce
a biological response when administered to an organism. There is
no limitation on the type of molecules or compounds that may be
used. For example, the biologically active compounds may be small
molecule organic or inorganic molecules or compounds, nucleic acids,
peptides, antibodies or any combination thereof. Preferably the
biologically active compounds are peptides. More preferably the
biologically active compounds are antibodies, such as anti-CD3
anti-CD28 41-BB, anti-CD40L and anti-CD40. Even more preferably
the biologically active compounds are anti-CD3 and anti-CD28 monoclonal
antibodies. Several non-limiting examples of other types of biologically
active molecules or compounds that may be used are antibiotic, anti-fungal,
anti-malarial, anti-tubercular, anti-viral and anti-microbial compounds,
cephalosporins, aminoglycosides, penicillin, defensins, chemokines,
cytokines, interleukin-2 interleukin-12 interferon-gamma, epitope
specific sequences such as p53 E75 E6 and E7 and EBV associated
antigens.
[0039] In the preparation of coated suture, the suture is contacted
with the biologically active compounds. In the preferred embodiment,
lengths of suture are incubated in a solution that contains the
biologically active compounds. The biologically active compounds
are preferably present in the solution at a concentration at which
they remain soluble. More preferably the biologically active compounds
are present in the solution at a concentration of from 0.01 to 500
.mu.g/ml. Even more preferably the concentration of the biologically
active compounds is from 1 to 50 .mu.g/ml and yet more preferably
from 2 to 10 .mu.g/ml.
[0040] In the preferred embodiment the biological activity of the
biologically active compounds is maintained in the solution. The
solution is preferably a buffer. In one embodiment the suture is
incubated in phosphate buffered saline (PBS) containing the desired
biologically active compound. More preferably the solution is Ca.sup.2+
and Mg.sup.2+ free PBS. One skilled in the art will recognize that
the amount of buffer used will vary depending on the size of the
container in which the incubation takes place, the total length
of suture being incubated and the desired concentration of the biologically
active compounds in the buffer. Preferably from 0.1 to 10 ml of
buffer is used for every 1 cm of suture incubated, more preferably
from 1 to 5 ml of buffer for every 1 cm of suture and even more
preferably 2 ml of buffer for every 1 cm of suture.
[0041] The suture is incubated in the buffer containing the biologically
active compounds for a length of time sufficient to allow the compound
to adhere to the suture. Preferably the incubation is continued
for from 0.1 to 120 hours. More preferably the incubation is continued
for from 1 to 36 hours and even more preferably for from 4.5 to
18 hours.
[0042] In the preferred embodiment the incubation is carried out
at a temperature at which the biologically active compound is the
most thermally stable. This temperature may readily be determined
by one skilled in the art. The incubation preferably takes place
at from 10 to 90.degree. C., more preferably from 30 to 50.degree.
C. and even more preferably at 37.degree. C.
[0043] The incubation may be carried out in any container capable
of holding the suture and the buffer containing the biologically
active compounds. Preferably the container is made of a material
that does not interact with the biologically active compounds. More
preferably the incubation is carried out in a tissue culture dish.
One skilled in the art will recognize that the preferred tissue
culture dish will be chosen based on the amount of suture that is
to be coated with the biologically active compound. For example,
single, 1 cm long pieces of suture are preferably incubated in single
wells of 96 well plates, while from 3 to 6 1 cm long pieces of
suture may be incubated in a single well of a 24 well tissue culture
plate. Longer pieces of suture are incubated in appropriately larger
containers.
[0044] In the preferred embodiment, the coated suture is washed
in buffer that does not contain the biologically active compounds
before use. Preferably the coated suture is washed from 1 to 10
times in an excess of PBS, more preferably from 2 to 5 times and
even more preferably 3 times.
[0045] In one aspect of the invention the coated suture is used
in vitro or ex vivo. The coated suture is brought into contact with
cells that are responsive to the biologically active compounds on
the suture. In one embodiment, suture coated with one or more immuno-stimulating
molecules or compounds is used ex vivo under sterile conditions
to expand immunocompetent cells. For example, a lymph node may be
removed from a patient and contacted with a suture that is coated
with molecules that stimulate lymphocytes. FIG. 8 shows the proliferation
of lymph-node lymphocytes following placement of a suture coated
with anti-CD3 and anti-CD28 monoclonal antibodies in a lymph node
ex vivo. The lymphocytes may then be expanded and the expanded cells
may be used for adoptive cellular therapy to treat cancer or other
illnesses, such as infection, immunodeficiencies or chronic illnesses.
[0046] In another aspect of the invention, the coated suture is
placed into an organism to provide in vivo therapy. Preferably the
organism is a mammal and even more preferably a human.
[0047] In one embodiment the organism is a human patient. The coated
suture may be placed in the patient as part of a course of treatment
for a disease or disorder. Alternatively, the coated suture may
be placed in the patient to prevent the development of a disease
or disorder. The coated suture may also be placed in a human patient
who is receiving an organ transplant.
[0048] In one embodiment the human patient has cancer. In particular,
the human patient may have head and neck cancer, more particularly
squamous cell carcinoma.
[0049] The coated suture may be placed in an organism by any method
known in the art. In the preferred embodiment a hollow needle with
a trochar is passed into the desired location in the organism. One
skilled in the art will recognize that the length of the needle
will vary depending on the depth at which the coated suture is to
be placed. The trochar is then removed and the suture is passed
down the barrel of the needle to the end. The needle is then removed
over the coated suture, leaving the coated suture in the desired
position. The coated suture preferably extends from the desired
position to the surface of the skin.
[0050] One or more coated sutures may be placed in the same organism
by the method of the present invention. In particular the desired
biological activity in the organism may be modified by adding or
removing coated sutures.
[0051] The coated suture may remain in the organism for any length
of time. However, it is anticipated that the biological activity
will decrease over time once a coated suture has been placed in
an organism. Thus to maintain the desired biological activity the
old coated suture may be removed and replaced with new coated suture
at regular intervals. This may be accomplished without subjecting
the patient to a major surgery. The coated suture may also be removed
if the organism experiences an adverse reaction to the coated suture
or if the coated suture has an unforeseen biological activity.
[0052] In the preferred embodiment, the location of the coated
suture in the organism is confirmed during or after placement. For
example, manual palpation, ultrasound, or CT scan may be used to
confirm the location of the coated suture. In one embodiment the
distal end of the coated suture is modified to be radio-opaque,
thus allowing the location of the suture to be determined by radiograph.
[0053] The proximal end of the coated suture may be secured to
the skin, for example with a piece of tape or a bandage. In this
embodiment the coated suture may be easily removed by pulling on
the proximal end of the suture. In another embodiment the coated
suture is removed by passing the proximal end of the coated suture
into a sterile 18-20 gauge spinal needle which is then passed over
the coated suture to core it out.
[0054] The suture of the present invention is coated with a particular
compound and placed in a specific location such that it produces
a desired biological response. For example, the coated suture may
find use in modulating the immune system of a patient in which it
is placed. Thus the suture may be coated with an immuno-modulating
agent and placed in a location in the body where the immuno-modulating
agent would be expected to have a biological activity, for example
in the lymph node. In another examples the suture is coated with
anti-microbial compounds, such as antibiotics and placed in a wound
to prevent infection. In a further example the suture may be coated
with a compound that facilitates wound healing and placed into a
wound.
[0055] In particular the coated suture of the present invention
may find use in stimulating the immune system of a human patient
suffering from a disease that is characterized by suppression of
the immune system. More particularly the suture may find use in
treating cancer patients. For example, immuno-modulating sutures
may be placed in the regional lymph nodes of cancer patients to
stimulate cytotoxic T lymphocytes, helper T lymphocytes, Natural
Killer cells, dendritic cells and other immune competent cells in
the fight against cancer. Immuno-modulating coated sutures have
been shown to generate a T.sub.H1 type immune response that is effective
in the rejection of multiple cancer varieties (see Example 3).
[0056] In one embodiment, immuno-modulating coated suture is used
to treat a cancer patient by placing the suture by injection into
identified lymphatics where they stimulate an anti-cancer response.
Preferably the coated suture comprises one or more pieces small
enough to be injected. One advantage of this method is that it may
be performed in vivo and thus does not require the labor intensive
step of adoptive cellular therapy and cellular expansion. Additionally,
the risks of contamination and infection are significantly reduced
compared to in vitro cellular expansion and infusion.
[0057] In another embodiment immuno-modulating coated sutures of
the present invention are placed in the regional lymph nodes of
cancer patients prior to surgery. This stimulates the immune system
and enhances a population of immunocompetent cells that are immune
specific for the particular cancer being treated. The immunocompetent
cells are harvested from the lymph node following surgical removal
and are expanded ex vivo using any method known in the art, for
example .alpha.CD3 and IL-2 treatment or incubation with .alpha.CD3
and .alpha.CD28 coated beads. The expanded cells are then reinfused
into the patient to help fight the cancer.
[0058] The immuno-modulating coated suture of the present invention
may also find use when combined with tumor specific peptide in a
vaccine regimen. Patients are immunized according to a standard
immunization protocol. In addition the immune system is stimulated
by placing one or more of the coated sutures of the present invention,
providing for a stronger anti-cancer immune response.
[0059] In another embodiment, sutures coated with specific peptides
are placed into a surgical wound following resection. The coated
sutures stimulate the residual memory cells present in the wound
area, which leads to the death of any residual microscopic cancer.
[0060] In another embodiment the immuno-modulating coated suture
is used to suppress the immune system. A suture is coated with .alpha.CD3
by the method of the present invention. .alpha.CD3 is commonly used
in organ transplantation to prevent host rejection of the donor
organ. At the time of transplant surgery the anti-CD3 coated suture
is strategically placed into the donor organ bed or into the regional
lymphatics to cause a local or regional immunosuppressed environment
and thus reduce the chance of donor organ rejection.
EXAMPLES
Example 1
[0061] Monofilament nylon suture is coated with .alpha.CD3 and
.alpha.CD28 antibodies. .alpha.CD3 antibody is added to Ca.sup.2+
and Mg.sup.2+ free PBS to a concentration of 2 .mu.g/ml. An equivalent
amount of .alpha.CD28 antibody is then added to the solution. A
5 cm suture is incubated in 1 ml of the antibody-containing PBS
solution in one well of a 24 well tissue culture plate. The incubation
is continued for 6 hours at 37.degree. C.
Example 2
[0062] Chromic gut or plain gut suture is coated with .alpha.CD3
and .alpha.CD28 antibodies. .alpha.CD3 antibody is added to Ca.sup.2+
and Mg.sup.2+ free PBS to a concentration of 10 .mu.g/ml. An equivalent
amount of .alpha.CD28 antibody is then added to the solution. A
5 cm suture is incubated in 1 ml of the antibody-containing PBS
solution in one well of a 24 well tissue culture plate. The incubation
is continued for 6 hours at 37.degree. C.
Example 3
[0063] T-cells can be stimulated ex vivo with .alpha.CD3/.alpha.CD28
monoclonal antibodies. The resulting cells have been used in adoptive
immunotherapy trials. The coated surgical suture of the present
invention was used as a novel carrier for .alpha.CD3/.alpha.CD28
monoclonal antibodies (MoAbs). The coated suture allows in vivo
immune stimulation and bypasses the need for in vitro expansion
and re-infusion. To test the properties of .alpha.CD3/.alpha.CD28
coated suture the activation of peripheral blood mononuclear cells
(PBMCs) from normal patients was measured. In addition, PBMCs and
lymph node mononuclear cells (LNMCs) from patients with advanced
head and neck squamous cell carcinoma (HNSCC) were incubated in
vitro with the antibody-coated suture and the patients' responses
were measured. Patients with HNSCC were chosen because of the known
immunosuppression that exists in this patient population. The immune
responses measured were proliferation, cytokine production and cellular
phenotype.
[0064] Peripheral blood was drawn from healthy volunteers or patients
with HNSCC before surgery. Blood was suspended in an equal volume
of PBS and PBMCs were isolated by centrifugation over a Ficoll-Hypaque
(Pel-Freez, Brown Deer, Wis.) density gradient for 10 minutes at
2400 rpm. PBMCs were cultured at a density of 1.times.10.sup.5 in
200 .mu.l of culture media in 96-well flat-bottom plates (Costar,
Cambridge, Mass.). Culture media consisted of RPMI 1640 (Gibco,
Paisley, Scotland) supplemented with 10% fetal calf serum (Hyclone),
2 mmol/L glutamide (Gibco), 100 U/ml penicillin (Gibco), 100 .mu.g/ml
streptomycin (Gibco) and 100 U/ml amphotericin B (Gibco).
[0065] Lymph nodes from HNSCC patients were harvested at the time
of surgery. The mean age of all the patients studied was 51.7 years,
with a range of 38 to 65 years. All patients had advanced stage
III or IV HNSCC. The site of the HNSCC primary cancers included
the oropharynx, the larynx, the oral cavity and an unknown primary
cancer. Harvested lymph nodes were immediately placed in balanced
salt solution with 20% heat inactivated fetal calf serum (Hyclone,
Logan, Utah), a combination of 1% penicillin potassium and streptomycin
sulfate and 1% amphotericin B. Lymph nodes were then minced, filtered
through a nylon mesh and washed twice in a balanced salt solution
with 5% fetal calf serum, 1% penicillin-streptomycin and 1% amphotericin
B. Lymph node mononuclear cells (LNMCs) were obtained by Ficoll-Hypaque
density gradient centrifugation. Only pathologically confirmed negative
lymph nodes were used in this study. For phenotyping and cytokine
quantification, 7.5.times.10.sup.5 PBMCs or LNMCs were cultured
in 2.0 ml of culture media in 24 well tissue culture plates for
6 days. All cultures were maintained at 37.degree. C. in a 5% carbon
dioxide atmosphere.
[0066] The immune response of cells was measured over an 8-day
period. On days 2 4 6 and 8 cell cultures were pulsed with 7.4.times.10.sup.4
Bq of .sup.3[H]-thymidine (tritium-thymidine) for 4 hours and harvested
onto glass fiber disks using a cell harvester (Cambridge Technology,
Cambridge, Mass.). The glass fiber disks were placed in vials containing
6 ml of scintillation cocktail and counted in a scintillation counter
(Beckman, Fullerton, Calif.).
[0067] For phenotypic analysis, cell suspensions were prepared
from LNMC or PBMC cultures on days 0 and 6 after incubation. The
cells were stained with anti-CD3-phycoerythrin (PE), anti-CD4-PE,
anti-CD8-PE, anti-CD28-PE or anti-CD45RO-PE (PharMingen, San Diego,
Calif.). The expression of surface markers was measured by flow
cytometry (FACScan, Becton Dickinson, San Jose, Calif.).
[0068] For cytokine analysis, cell culture supernatants were harvested
on days 2 4 and 6. The quantities of IL-2 IL-4 TNF.alpha., IL-12
and IFN-.gamma. present in the supernatant was determined by enzyme-linked
immunosorbent assay (R&D Systems, Minneapolis, Minn.).
[0069] Suture coated with .alpha.CD3 was prepared by incubating
sterile suture in PBS containing .alpha.CD3 (Caltag Corp., Burlingame,
Calif.) at various concentrations for 18 hours at 37.degree. C.
The suture was washed 3 times in phosphate buffered saline (PBS)
before culturing with mononuclear cells. Monofilament nylon, chromic
gut and plain gut sutures (Ethicon Inc., Somerville, N.J.) were
found to consistently activate T cells after coating with .alpha.CD3
MoAbs (FIG. 1 A-C). Uncoated suture did not stimulate normal PBMCs
(FIG. 2A). All 3 suture types stimulated maximal proliferation on
day 4 (FIG. 1 A-C).
[0070] Because .alpha.CD3-coated nylon, chromic gut and plain gut
sutures stimulated consistently, the efficacy of coating with .alpha.CD3/.alpha.CD28
was examined (FIG. 1 A-C). Suture coated with .alpha.CD3/.alpha.CD28
was prepared by incubating sterile suture in PBS at various concentrations
and ratios of the .alpha.CD3 and .alpha.CD28 (private gift) antibodies
for 18 hours at 37.degree. C. The optimal coating condition was
achieved by incubating nylon suture with 2 .mu.g/ml .alpha.CD3/.alpha.CD28
(1:1). The types of suture studied included nylon, polyglactin,
chromic gut, plain guy and silk (Ethicon Inc, Somerville, N.J.).
The suture was washed 3 times in phosphate buffered saline (PBS)
before culturing with mononuclear cells. Nylon suture exhibited
the strongest MoAb carrier function (FIG. 2B). Proliferation of
PBMCs induced by .alpha.CD3/.alpha.CD28-coated nylon suture exceeded
that by .alpha.CD3-coated suture (FIG. 1A).
[0071] In order to compare the stimulating capacity of coated suture
to a known .alpha.CD3/.alpha.CD28 carrier, proliferative responses
of PBMCs and LNMCs from patients with HNSCC were measured after
exposure to .alpha.CD3/.alpha.CD28 coated suture or .alpha.CD3/.alpha.CD28
coated tissue culture plastic. Tissue culture plastic is a recognized
carrier of .alpha.CD3/.alpha.CD28 monoclonal antibodies. Tissue
culture plastic was coated with 100 .mu.l of varying concentration
s of .alpha.CD3 or .alpha.CD3/.alpha.CD28 and incubated at 37.degree.
C. for 18 hours. Plates were washed three times with PBS before
use in the assays.
[0072] Proliferative responses of LNMCs and PBMCs peaked on day
6 for both coated suture and tissue culture plastic and no differences
were observable between the two carriers (FIG. 3). Normal donor
PBMCs were also stimulated using .alpha.CD3/.alpha.CD28 on both
carriers and similar results were obtained, with no significant
difference between the tissue culture plastic and the coated suture
(FIG. 3).
[0073] In order to identify the T-cell population from the lymph
node that is expanded after .alpha.CD3/.alpha.CD28 suture stimulation,
T-cells were characterized before activation and on day 6 after
stimulation. Lymph node mononuclear cells stimulated with .alpha.CD3/.alpha.CD28
coated suture revealed significant enhancement in all T-cell subpopulations.
In particular, a significant increase occurred in the CD3 CD4
CD8 CD28 and CD45RO populations as measured by flow cytometry (FIG.
4). A similar increase in T-cells was observed after PBMC stimulation,
with significant increases observed by day 6 in the CD3 CD4 CD28
and CD45RO populations. The largest increase was noted in the CD45RO
or memory cell population of T-cells. Stimulation with .alpha.CD3/.alpha.CD28
coated plastic did not produce adequate expansion of peripheral
blood and lymph node T-cells to allow phenotyping.
[0074] The immunologic response enhanced by .alpha.CD3/.alpha.CD28
coated suture and plastic was further characterized by harvesting
cell culture supernatants following stimulation. Cell culture supernatants
were harvested on day 6 following stimulation and the quantity of
IL-2 IL-4 IL-12 IFN-.gamma. and TNF.alpha. was measured by enzyme-linked
immunosorbent assay. Unstimulated cultures revealed minimal expression
of cytokines (FIG. 5). Stimulation of LNMCs with .alpha.CD3/.alpha.CD28
coated suture enhanced the secretion of IL-2 significantly compared
to both unstimulated cells and cells stimulated with .alpha.CD3/.alpha.CD28
coated plastic (FIG. 5). Stimulation of LNMCs with .alpha.CD3/.alpha.CD28
coated suture induced significantly higher levels of IFN-.gamma.
production than those seen in unstimulated controls, as did .alpha.CD3/.alpha.CD28
coated plastic (FIG. 5).
[0075] These results indicate that stimulation with .alpha.CD3/.alpha.CD28
suture resulted in a T.sub.H1 cytokine expression pattern in the
LNMCs studied. Stimulation of PBMCs with coated suture also induced
significantly higher production of IL-2 and IFN-.gamma. compared
to unstimulated controls (FIG. 5). As can be seen in FIG. 5 suture
stimulated PBMCs also produced significantly higher levels of IL-2
than coated plastic stimulation. This indicates that stimulation
with .alpha.CD3/.alpha.CD28 suture produced a T.sub.H1 cytokine
expression pattern in PBMCs as well.
[0076] Stimulated cytokine expression was also measured in normal
donor PBMCs in vitro after 6 days (FIG. 6). .alpha.CD3/.alpha.CD28
stimulation significantly increased expression of IFN-.gamma. above
unstimulated control levels. Coated plastic stimulation increased
expression of both IFN-.gamma. and TNF.alpha. levels above those
seen in unstimulated controls (FIG. 6). There was no significant
difference in the quantity of IFN-.gamma. secreted after coated
suture stimulation or coated plastic stimulation.
[0077] The induction of T.sub.H1 cytokines (IL-2 and IFN-.gamma.)
by .alpha.CD3/.alpha.CD28 coated suture is significant. T.sub.H1
cytokines have been associated with cytotoxic immune responses against
cancer. There are at least 2 active FDA approved adoptive immunotherapeutic
trials using .alpha.CD3/.alpha.CD28 coated beads as immunostimulants
for the treatment of human immunodeficiency virus and advanced end-stage
solid cancers. .alpha.CD3/.alpha.CD28 coated surgical suture as
a carrier will allow cellular activation to be performed in vivo,
bypassing the need for ex vivo expansion and reinfusion. Targeted
areas could be the primary cancer site or regional lymph nodes.
Example 4
[0078] The antibody-coated sutures of the present invention may
be used effectively to kill tumor cells from a patient with head
and neck squamous cell carcinoma (HNSCC). A cytotoxicity assay was
performed using lymph node lymphocytes (LNL) or peripheral blood
lymphocytes (PBL) against autologous tumor. LNL and PBL from a HNSCC
patient were stimulated with suture coated with .alpha.CD3/.alpha.CD28
according to the method of the present invention. Stimulated cells
were used in a .sup.51Cr cytotoxicity assay to measure their ability
to kill autologous tumor cells. Briefly, tumor cells from the patient's
own tumor were labeled with .sup.51Cr. The tumor cells were then
contacted with the stimulated LNL or PBL cells and the resulting
.sup.51Cr release was measured. Stimulated PBL were able to kill
77%, 73% and 62% of all tumor cells at 50:1 25:1 and 12:1 ratios
of effector or activated T-cells to tumor cells (effector:target;
E:T ratio) respectively (FIG. 7). Stimulated LNL were able to lyse
4% of tumor cells at a 50:1 E:T ratio (FIG. 7).
Example 5
[0079] Antibody coated suture is used in the treatment of residual
cancer present in the neck as a large palpable mass. The tumor is
localized with 1% lidocaine. An 18-20 gauge spinal needle approximately
6-8 inches in length is placed into the center of the tumor. Placement
into a large tumor is confirmed by simple palpation. In smaller
tumors placement is confirmed by ultrasound, CT scan or plan radiograph.
The trochar is removed and .alpha.CD3/.alpha.CD28 coated suture
is passed down the barrel of the needle. The needle is then removed
over the suture. The suture has thus been placed without any abrading
through the skin or soft tissue. The suture is secured to the skin
with a piece of tape or bandage.
Example 6
[0080] Immunomodulating suture of the present invention is used
in the treatment of a patient with head and neck cancer. First,
a suture coated with human defensin is placed into the palpable
regional lymph node. This attracts immature CD34+ antigen presenting
cells that are believed to be immunosuppressive. After several days
of attracting these cells to the area within the lymph node near
the suture, the defensin coated suture is removed and replaced with
an .alpha.CD3/.alpha.CD28 coated suture. This suture stimulates
the immature cells to become more mature antigen presenting cells.
The .alpha.CD3.alpha.CD28 suture is removed after several days and
replaced with a suture coated with antigens specific to the type
of cancer found in the patient. This suture produces an immune specific
response. A second suture is then added to help boost the specific
immune response. The second suture is coated with .alpha.CD3/.alpha.CD28
antibody. This combination of immuno-modulating sutures stimulates
the lymph node lymphocytes to kill the cancer.
Example 7
[0081] The therapy presented in Example 5 may be followed by adoptive
immunotherapy. The patient suffering from head and neck cancer is
taken to surgery and a neck dissection and tumor resection is performed.
During the neck dissection the lymph nodes that were the site of
the suture placement in Example 5 are harvested and the immuno-stimulated
lymphocytes are expanded in vitro. The immuno-modulating suture
will have increased the population of anti-cancer lymphocytes in
the lymph node, thus providing more cells for the in vitro expansion.
The expansion is carried out using standard protocols well known
in the art. The expanded population of lymphocytes will have been
exposed to the tumor and will have an enhanced ability to kill the
cancer. The expanded anti-cancer cells are then infused into the
patient.
Example 8
[0082] Patients with a cancer that presents specific tumor antigens
are vaccinated with antigen coated suture. The vaccination may be
done in conjunction with the use of immuno-stimulating suture as
described above. Epstein Bar Virus (EBV) associated proteins are
commonly found on the tumor cells of patients with nasopharyngeal
carcinoma. P53 E75 E6 and E7 antigens have also been associated
with head and neck carcinoma and other cancers. Suture coated with
one or more peptides selected from the group consisting of EBV peptide,
p53 E75 E6 E7 and other cancer specific peptides is placed in
the regional neck lymph node before, during and after standard treatment
with radiation therapy. The peptide-coated suture stimulates the
immune system to kill any cancer that develops after treatment and
thus "vaccinates" the patient. Simultaneously the patient
is treated with immuno-modulating suture as described in Example
5. The patient may receive intermittent booster immuno-modulating
suture during the course of the year.
Example 9
[0083] Following standard surgical resection of a tumor in a patient
with head and neck cancer, immuno-modulating sutures are place directly
in the wound. At least one suture is coated with tumor specific
peptides and at least one suture is coated with .alpha.CD3/.alpha.CD28.
The sutures are placed directly in the floor of the wound and the
ends of the sutures are brought out the incision site. The sutures
located in the wound bed stimulates the residual memory cells present
in the wound area and enhance the anti-tumor response of the immune
system as healing occurs.
Example 10
[0084] Following standard surgical resection of a tumor in a patient
with head & neck cancer, sutures coated with biologically active
compounds are place directly in the wound. Immuno-stimulating suture
has been shown to induce a Th1 type of immunological response. This
response is effective at killing foreign bodies, such as bacteria,
that may contaminate a surgical wound. Suture coated with .alpha.CD3/.alpha.CD28
is placed in the desired location in the surgical bed and brought
out the incision site in the same manner as a surgical drain. Additional
sutures coated with anti-microbial peptides, such as defensins,
or antibiotics may be placed in the surgical bed as well.
Example 11
[0085] .alpha.CD3 is presently used to reduce transplant rejection
and is administered by systematic infusion. An immuno-modulating
suture of the present invention may be used to specifically suppress
the lymphatic most commonly associated with a particular organ rejection.
At the time of placing a donor kidney into the recipient's pelvis,
.alpha.CD3 coated suture is placed into the pelvic lymph nodes or
the organ bed. This causes regional immunosuppression and reduces
the incidence of host rejection of the donor organ.
Example 12
[0086] Severe combined immune-deficiency (SCID) mouse model for
testing bioactive suture.
[0087] A first group of SCID mice is inoculated subcutaneously
with head and neck squamous cell carcinoma (HNSCC) take from cancer
patient A in the flank, thigh or back. This group of mice functions
as a cancer control group.
[0088] Lymph node tissue harvested from cancer patient A is implanted
into the flank, thigh or back of a second group of SCID mice. This
group of mice functions as a non-cancer control group.
[0089] A third group of SCID mice has both HNSCC and lymph node
tissue from patient A implanted into the flank, thigh or back. The
cancerous tissue and lymph node tissue are placed adjacent to one
anther. This third set of mice represents the baseline immune response
of lymph node lymphocytes to HNSCC from cancer patient A. The cancer
and lymph node are allowed to grow for 3-5 days in vivo proximal
to each other. Then on day 6 .alpha.CD3/.alpha.CD28 coated suture
is placed into the lymph node bed using the suture placing technique
described above. .alpha.CD3/.alpha.CD28 suture is left in place
for the next 10 days and the anti-cancer response is measured by
sequential measurement of tumor size. Animals are sacrificed at
selected time points and the anti-cancer response is measured histologically.
Immune responsive cells are phenotyped by flow cytometry and the
immune environment is characterized by measuring the cytokine profile
using intra-cellular stains and enzyme linked immunosorbent assay
techniques well known in the art.
[0090] In addition to using suture coated with .alpha.CD3/.alpha.CD28
suture coated with interleukin-2 interferon-gamma, interleukin-12
4-1-BB, anti-CD40 anti-CD40L, or p53 E75 E6 E7 or EBV antigens,
is used as an immune stimulant individually or in combinations.
[0091] A fourth group of SCID mice with both HNSCC and lymph node
tissue from patient A implanted adjacent to one another in the flank,
thigh or back is treated with uncoated suture. This group of mice
functions as a non-stimulating suture control group. The immune
response in this group is analyzed in the same way as in the group
receiving the stimulating suture.
Example 13
[0092] Lymph nodes were removed from a patient with advanced stage
head and neck squamous cell carcinoma. Sutures coated with biologically
active compounds were placed in the lymph node and the proliferation
of lymph node lymphocytes was observed. The proliferation of lymph
node lymphocytes along anti-CD3/anti-CD28 monoclonal antibody coated
(a) nylon and (b) polyester suture is shown in FIG. 8.
Example 14
[0093] The response of peripheral blood lymphocytes to suture coated
with biologically active compounds was measured in vitro. FIG. 9
shows that the peripheral blood lymphocytes proliferated in response
to nylon suture coated with anti-CD3 and anti-CD28 monoclonal antibody
and polyester suture that was coated with interferon-gamma.
[0094] The binding of interferon-gamma to 5-0 polyester suture
was confirmed by immunofluorescence. FIG. 10 shows that anti-interferon-PE
bound to interferon-gamma coated polyester suture (B) but not to
control polyester suture (A).
Conclusion
[0095] As can be seen from the foregoing discussion, the coated
sutures of the present invention can be used for long-term delivery
of a variety of different biologically active compounds in a wide
variety of local and systemic environments. As such, those of ordinary
skill in the art will appreciate upon access to the present disclosure
that a large number of specific treatments can be carried out using
these sutures, in addition to those specifically exemplified herein.
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