Med-Real2Sim / app.py
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import os
os.system('pip uninstall -y gradio')
os.system('pip install gradio==5.0.1')
import gradio as gr
import matplotlib.pyplot as plt
from scipy.integrate import odeint
import torch
from torch.utils import data
from torch.utils.data import DataLoader, Dataset
from torch import nn, optim
from skimage.transform import rescale, resize
from torch import nn, optim
import torch.nn.functional as F
from torch.utils.data import Subset
from scipy.interpolate import interp1d
import collections
import numpy as np
import random
#for pvloop simulator:
import pandas as pd
from scipy.integrate import odeint
import torchvision
import echonet
import matplotlib.animation as animation
from functools import partial
device = torch.device("cuda:0" if torch.cuda.is_available() else "cpu")
sequences_all = []
info_data_all = []
path = 'EchoNet-Dynamic'
output_path = ''
class Echo(torchvision.datasets.VisionDataset):
"""EchoNet-Dynamic Dataset.
Args:
root (string): Root directory of dataset (defaults to `echonet.config.DATA_DIR`)
split (string): One of {``train'', ``val'', ``test'', ``all'', or ``external_test''}
target_type (string or list, optional): Type of target to use,
``Filename'', ``EF'', ``EDV'', ``ESV'', ``LargeIndex'',
``SmallIndex'', ``LargeFrame'', ``SmallFrame'', ``LargeTrace'',
or ``SmallTrace''
Can also be a list to output a tuple with all specified target types.
The targets represent:
``Filename'' (string): filename of video
``EF'' (float): ejection fraction
``EDV'' (float): end-diastolic volume
``ESV'' (float): end-systolic volume
``LargeIndex'' (int): index of large (diastolic) frame in video
``SmallIndex'' (int): index of small (systolic) frame in video
``LargeFrame'' (np.array shape=(3, height, width)): normalized large (diastolic) frame
``SmallFrame'' (np.array shape=(3, height, width)): normalized small (systolic) frame
``LargeTrace'' (np.array shape=(height, width)): left ventricle large (diastolic) segmentation
value of 0 indicates pixel is outside left ventricle
1 indicates pixel is inside left ventricle
``SmallTrace'' (np.array shape=(height, width)): left ventricle small (systolic) segmentation
value of 0 indicates pixel is outside left ventricle
1 indicates pixel is inside left ventricle
Defaults to ``EF''.
mean (int, float, or np.array shape=(3,), optional): means for all (if scalar) or each (if np.array) channel.
Used for normalizing the video. Defaults to 0 (video is not shifted).
std (int, float, or np.array shape=(3,), optional): standard deviation for all (if scalar) or each (if np.array) channel.
Used for normalizing the video. Defaults to 0 (video is not scaled).
length (int or None, optional): Number of frames to clip from video. If ``None'', longest possible clip is returned.
Defaults to 16.
period (int, optional): Sampling period for taking a clip from the video (i.e. every ``period''-th frame is taken)
Defaults to 2.
max_length (int or None, optional): Maximum number of frames to clip from video (main use is for shortening excessively
long videos when ``length'' is set to None). If ``None'', shortening is not applied to any video.
Defaults to 250.
clips (int, optional): Number of clips to sample. Main use is for test-time augmentation with random clips.
Defaults to 1.
pad (int or None, optional): Number of pixels to pad all frames on each side (used as augmentation).
and a window of the original size is taken. If ``None'', no padding occurs.
Defaults to ``None''.
noise (float or None, optional): Fraction of pixels to black out as simulated noise. If ``None'', no simulated noise is added.
Defaults to ``None''.
target_transform (callable, optional): A function/transform that takes in the target and transforms it.
external_test_location (string): Path to videos to use for external testing.
"""
def __init__(self, root=None,
split="train", target_type="EF",
mean=0., std=1.,
length=16, period=2,
max_length=250,
clips=1,
pad=None,
noise=None,
target_transform=None,
external_test_location=None):
if root is None:
root = path
super().__init__(root, target_transform=target_transform)
self.split = split.upper()
if not isinstance(target_type, list):
target_type = [target_type]
self.target_type = target_type
self.mean = mean
self.std = std
self.length = length
self.max_length = max_length
self.period = period
self.clips = clips
self.pad = pad
self.noise = noise
self.target_transform = target_transform
self.external_test_location = external_test_location
self.fnames, self.outcome = [], []
if self.split == "EXTERNAL_TEST":
self.fnames = sorted(os.listdir(self.external_test_location))
else:
# Load video-level labels
with open(f"{self.root}/FileList.csv") as f:
data = pd.read_csv(f)
data["Split"].map(lambda x: x.upper())
if self.split != "ALL":
data = data[data["Split"] == self.split]
self.header = data.columns.tolist()
self.fnames = data["FileName"].tolist()
self.fnames = [fn + ".avi" for fn in self.fnames if os.path.splitext(fn)[1] == ""] # Assume avi if no suffix
self.outcome = data.values.tolist()
# Check that files are present
"""
missing = set(self.fnames) - set(os.listdir(os.path.join(self.root, "Videos")))
if len(missing) != 0:
print("{} videos could not be found in {}:".format(len(missing), os.path.join(self.root, "Videos")))
for f in sorted(missing):
print("\t", f)
raise FileNotFoundError(os.path.join(self.root, "Videos", sorted(missing)[0]))
"""
# Load traces
self.frames = collections.defaultdict(list)
self.trace = collections.defaultdict(_defaultdict_of_lists)
with open(f"{self.root}/VolumeTracings.csv") as f:
header = f.readline().strip().split(",")
assert header == ["FileName", "X1", "Y1", "X2", "Y2", "Frame"]
for line in f:
filename, x1, y1, x2, y2, frame = line.strip().split(',')
x1 = float(x1)
y1 = float(y1)
x2 = float(x2)
y2 = float(y2)
frame = int(frame)
if frame not in self.trace[filename]:
self.frames[filename].append(frame)
self.trace[filename][frame].append((x1, y1, x2, y2))
for filename in self.frames:
for frame in self.frames[filename]:
self.trace[filename][frame] = np.array(self.trace[filename][frame])
# A small number of videos are missing traces; remove these videos
keep = [len(self.frames[f]) >= 2 for f in self.fnames]
self.fnames = [f for (f, k) in zip(self.fnames, keep) if k]
self.outcome = [f for (f, k) in zip(self.outcome, keep) if k]
def __getitem__(self, index):
# Find filename of video
if self.split == "EXTERNAL_TEST":
video = os.path.join(self.external_test_location, self.fnames[index])
elif self.split == "CLINICAL_TEST":
video = os.path.join(self.root, "ProcessedStrainStudyA4c", self.fnames[index])
else:
video = os.path.join(self.root, "Videos", self.fnames[index])
# Load video into np.array
video = echonet.utils.loadvideo(video).astype(np.float32)
# Add simulated noise (black out random pixels)
# 0 represents black at this point (video has not been normalized yet)
if self.noise is not None:
n = video.shape[1] * video.shape[2] * video.shape[3]
ind = np.random.choice(n, round(self.noise * n), replace=False)
f = ind % video.shape[1]
ind //= video.shape[1]
i = ind % video.shape[2]
ind //= video.shape[2]
j = ind
video[:, f, i, j] = 0
# Apply normalization
if isinstance(self.mean, (float, int)):
video -= self.mean
else:
video -= self.mean.reshape(3, 1, 1, 1)
if isinstance(self.std, (float, int)):
video /= self.std
else:
video /= self.std.reshape(3, 1, 1, 1)
# Set number of frames
c, f, h, w = video.shape
if self.length is None:
# Take as many frames as possible
length = f // self.period
else:
# Take specified number of frames
length = self.length
if self.max_length is not None:
# Shorten videos to max_length
length = min(length, self.max_length)
if f < length * self.period:
# Pad video with frames filled with zeros if too short
# 0 represents the mean color (dark grey), since this is after normalization
video = np.concatenate((video, np.zeros((c, length * self.period - f, h, w), video.dtype)), axis=1)
c, f, h, w = video.shape # pylint: disable=E0633
if self.clips == "all":
# Take all possible clips of desired length
start = np.arange(f - (length - 1) * self.period)
else:
# Take random clips from video
start = np.random.choice(f - (length - 1) * self.period, self.clips)
# Gather targets
target = []
for t in self.target_type:
key = self.fnames[index]
if t == "Filename":
target.append(self.fnames[index])
elif t == "LargeIndex":
# Traces are sorted by cross-sectional area
# Largest (diastolic) frame is last
target.append(int(self.frames[key][-1]))
elif t == "SmallIndex":
# Largest (diastolic) frame is first
target.append(int(self.frames[key][0]))
elif t == "LargeFrame":
target.append(video[:, self.frames[key][-1], :, :])
elif t == "SmallFrame":
target.append(video[:, self.frames[key][0], :, :])
elif t in ["LargeTrace", "SmallTrace"]:
if t == "LargeTrace":
t = self.trace[key][self.frames[key][-1]]
else:
t = self.trace[key][self.frames[key][0]]
x1, y1, x2, y2 = t[:, 0], t[:, 1], t[:, 2], t[:, 3]
x = np.concatenate((x1[1:], np.flip(x2[1:])))
y = np.concatenate((y1[1:], np.flip(y2[1:])))
r, c = skimage.draw.polygon(np.rint(y).astype(np.int), np.rint(x).astype(np.int), (video.shape[2], video.shape[3]))
mask = np.zeros((video.shape[2], video.shape[3]), np.float32)
mask[r, c] = 1
target.append(mask)
else:
if self.split == "CLINICAL_TEST" or self.split == "EXTERNAL_TEST":
target.append(np.float32(0))
else:
target.append(np.float32(self.outcome[index][self.header.index(t)]))
if target != []:
target = tuple(target) if len(target) > 1 else target[0]
if self.target_transform is not None:
target = self.target_transform(target)
# Select clips from video
video = tuple(video[:, s + self.period * np.arange(length), :, :] for s in start)
if self.clips == 1:
video = video[0]
else:
video = np.stack(video)
if self.pad is not None:
# Add padding of zeros (mean color of videos)
# Crop of original size is taken out
# (Used as augmentation)
c, l, h, w = video.shape
temp = np.zeros((c, l, h + 2 * self.pad, w + 2 * self.pad), dtype=video.dtype)
temp[:, :, self.pad:-self.pad, self.pad:-self.pad] = video # pylint: disable=E1130
i, j = np.random.randint(0, 2 * self.pad, 2)
video = temp[:, :, i:(i + h), j:(j + w)]
return video, target
def __len__(self):
return len(self.fnames)
def extra_repr(self) -> str:
"""Additional information to add at end of __repr__."""
lines = ["Target type: {target_type}", "Split: {split}"]
return '\n'.join(lines).format(**self.__dict__)
def _defaultdict_of_lists():
"""Returns a defaultdict of lists.
This is used to avoid issues with Windows (if this function is anonymous,
the Echo dataset cannot be used in a dataloader).
"""
return collections.defaultdict(list)
##
print("Done loading training data!")
# define normalization layer to make sure output xi in an interval [ai, bi]:
# define normalization layer to make sure output xi in an interval [ai, bi]:
class IntervalNormalizationLayer(torch.nn.Module):
def __init__(self):
super().__init__()
# new_output = [Tc, start_p, Emax, Emin, Rm, Ra, Vd]
self.a = torch.tensor([0.4, 0., 0.5, 0.02, 0.005, 0.0001, 4.], dtype=torch.float32) #HR in 20-200->Tc in [0.3, 4]
self.b = torch.tensor([1.7, 280., 3.5, 0.1, 0.1, 0.25, 16.], dtype=torch.float32)
#taken out (initial conditions): a: 20, 5, 50; b: 400, 20, 100
def forward(self, inputs):
sigmoid_output = torch.sigmoid(inputs)
scaled_output = sigmoid_output * (self.b - self.a) + self.a
return scaled_output
class NEW3DCNN(nn.Module):
def __init__(self, num_parameters):
super(NEW3DCNN, self).__init__()
self.conv1 = nn.Conv3d(3, 8, kernel_size=3, padding=1)
self.batchnorm1 = nn.BatchNorm3d(8)
self.conv2 = nn.Conv3d(8, 16, kernel_size=3, padding=1)
self.batchnorm2 = nn.BatchNorm3d(16)
self.conv3 = nn.Conv3d(16, 32, kernel_size=3, padding=1)
self.batchnorm3 = nn.BatchNorm3d(32)
self.conv4 = nn.Conv3d(32, 64, kernel_size=3, padding=1)
self.batchnorm4 = nn.BatchNorm3d(64)
self.conv5 = nn.Conv3d(64, 128, kernel_size=3, padding=1)
self.batchnorm5 = nn.BatchNorm3d(128)
self.pool = nn.AdaptiveAvgPool3d(1)
self.fc1 = nn.Linear(128, 512)
self.fc2 = nn.Linear(512, num_parameters)
self.norm1 = IntervalNormalizationLayer()
def forward(self, x):
x = F.relu(self.batchnorm1(self.conv1(x)))
x = F.max_pool3d(x, kernel_size=2, stride=2)
x = F.relu(self.batchnorm2(self.conv2(x)))
x = F.max_pool3d(x, kernel_size=2, stride=2)
x = F.relu(self.batchnorm3(self.conv3(x)))
x = F.max_pool3d(x, kernel_size=2, stride=2)
x = F.relu(self.batchnorm4(self.conv4(x)))
x = F.max_pool3d(x, kernel_size=2, stride=2)
x = F.relu(self.batchnorm5(self.conv5(x)))
x = self.pool(x)
x = x.view(x.size(0), -1)
x = F.relu(self.fc1(x))
x = self.fc2(x)
x = self.norm1(x)
return x
# Define a neural network with one hidden layer
class Interpolator(nn.Module):
def __init__(self):
super().__init__()
self.fc1 = nn.Linear(6, 250).double()
self.fc2 = nn.Linear(250, 2).double()
def forward(self, x):
x = torch.relu(self.fc1(x))
x = self.fc2(x)
return x
# Initialize the neural network
net = Interpolator()
net.load_state_dict(torch.load('final_model_weights/interp6_7param_weight.pt'))
print("Done loading interpolator!")
weights_path = 'final_model_weights/202_full_echonet_7param_Vloss_epoch_200_lr_0.001_weight_best_model.pt'
model = NEW3DCNN(num_parameters = 7)
model.load_state_dict(torch.load(weights_path))
model.to(device)
## PV loops
#returns Plv at time t using Elastance(t) and Vlv(t)-Vd=x1
def Plv(volume, Emax, Emin, t, Tc, Vd):
return Elastance(Emax,Emin,t, Tc)*(volume - Vd)
#returns Elastance(t)
def Elastance(Emax,Emin, t, Tc):
t = t-int(t/Tc)*Tc #can remove this if only want 1st ED (and the 1st ES before)
tn = t/(0.2+0.15*Tc)
return (Emax-Emin)*1.55*(tn/0.7)**1.9/((tn/0.7)**1.9+1.0)*1.0/((tn/1.17)**21.9+1.0) + Emin
def solve_ODE_for_volume(Rm, Ra, Emax, Emin, Vd, Tc, start_v, t):
# the ODE from Simaan et al 2008
def heart_ode(y, t, Rs, Rm, Ra, Rc, Ca, Cs, Cr, Ls, Emax, Emin, Tc):
x1, x2, x3, x4, x5 = y #here y is a vector of 5 values (not functions), at time t, used for getting (dy/dt)(t)
P_lv = Plv(x1+Vd,Emax,Emin,t,Tc,Vd)
dydt = [r(x2-P_lv)/Rm-r(P_lv-x4)/Ra, (x3-x2)/(Rs*Cr)-r(x2-P_lv)/(Cr*Rm), (x2-x3)/(Rs*Cs)+x5/Cs, -x5/Ca+r(P_lv-x4)/(Ca*Ra), (x4-x3-Rc*x5)/Ls]
return dydt
# RELU for diodes
def r(u):
return max(u, 0.)
# Define fixed parameters
Rs = 1.0
Rc = 0.0398
Ca = 0.08
Cs = 1.33
Cr = 4.400
Ls = 0.0005
startp = 75.
# Initial conditions
start_pla = float(start_v*Elastance(Emax, Emin, 0., Tc))
start_pao = startp
start_pa = start_pao
start_qt = 0 #aortic flow is Q_T and is 0 at ED, also see Fig5 in simaan2008dynamical
y0 = [start_v, start_pla, start_pa, start_pao, start_qt]
# Solve
sol = odeint(heart_ode, y0, t, args = (Rs, Rm, Ra, Rc, Ca, Cs, Cr, Ls, Emax, Emin, Tc)) #t: list of values
# volume is the first state variable plus theoretical zero pressure volume
volumes = np.array(sol[:, 0]) + Vd
return volumes
def pvloop_simulator(Rm, Ra, Emax, Emin, Vd, Tc, start_v, animate=True, loop_simulated=False):
# Define initial parameters
init_Emax = Emax # 3.0 # .5 to 3.5
init_Emin = Emin # 0.04 # .02 to .1
# init_Tc = Tc # .4 # .4 to 1.7
init_Vd = Vd # 10.0 # 0 to 25
# DUMMY VOLUME
# def volume(t, Tc):
# return 50*np.sin(2 * np.pi * t*(1/Tc))+100
# SOLVE the ODE model for the VOLUME CURVE
N = 100
t = np.linspace(0, Tc*N, int(60000*N)) #np.linspace(1, 100, 1000000)
volumes = solve_ODE_for_volume(Rm, Ra, Emax, Emin, Vd, Tc, start_v, t)
# FUNCTIONS for PRESSURE CURVE
vectorized_Elastance = np.vectorize(Elastance)
vectorized_Plv = np.vectorize(Plv)
def pressure(t, volume, Emax, Emin, Tc, Vd):
return vectorized_Plv(volume, Emax, Emin, t, Tc, Vd)
# calculate PRESSURE
pressures = pressure(t, volumes, init_Emax, init_Emin, Tc, init_Vd)
# Create the figure and the loop that we will manipulate
fig, ax = plt.subplots(figsize=(6, 4))
plt.ylim((0,220))
plt.xlim((0,250))
start = (N-2)*60000
end = (N)*60000
if animate or loop_simulated:
line = ax.plot(volumes[start:(start+1)], pressures[start:(start+1)], lw=1, color='b')
point = ax.scatter(volumes[start:(start+1)], pressures[start:(start+1)], c="b", s=5)#, label='End Diastole')
#point = ax.scatter(volumes[start:(start+1)], pressures[start:(start+1)], c="b", s=5, label='End Systole')
else:
line = ax.plot(volumes[start:end], pressures[start:end], lw=1, color='b')
plt.title('Predicted PI-SSL LV Pressure Volume Loop', fontsize=16)
#plt.rcParams['fig.suptitle'] = -2.0
#ax.set_title(f'Mitral valve circuit resistance (Rm): {Rm} mmHg*s/ml \n Aortic valve circuit resistance (Ra): {Ra} mmHg*s/ml', fontsize=6)
ax.set_xlabel('LV Volume (ml)')
ax.set_ylabel('LV Pressure (mmHg)')
# adjust the main plot to make room for the sliders
# fig.subplots_adjust(left=0.25, bottom=0.25)
def update(frame):
# update to add more of the loop
end = (N-2)*60000+1000 * frame
x = volumes[start:end]
y = pressures[start:end]
ax.plot(x, y, lw=1, c='b')
if animate:
anim = animation.FuncAnimation(fig, partial(update), frames=100, interval=30)
anim.save("prediction.mp4")
if loop_simulated:
plt.title('Simulated LV Pressure Volume Loop', fontsize=16)
anim = animation.FuncAnimation(fig, partial(update), frames=100, interval=30)
anim.save("simulated.mp4")
return plt, Rm, Ra, Emax, Emin, Vd, Tc, start_v
def pvloop_simulator_plot_only(Rm, Ra, Emax, Emin, Vd, Tc, start_v):
plot,_,_,_,_,_,_,_ =pvloop_simulator(Rm, Ra, Emax, Emin, Vd, Tc, start_v, animate=False, loop_simulated=True)
animated_sim = "simulated.mp4"
return animated_sim
#########################################
# LVAD functions
# RELU for diodes
def r(u):
return max(u, 0.)
def heart_ode0(y, t, Rs, Rm, Ra, Rc, Ca, Cs, Cr, Ls, Emax, Emin, Tc, Vd):
x1, x2, x3, x4, x5 = y #here y is a vector of 5 values (not functions), at time t, used for getting (dy/dt)(t)
P_lv = Plv(x1+Vd,Emax,Emin,t,Tc,Vd)
dydt = [r(x2-P_lv)/Rm-r(P_lv-x4)/Ra, (x3-x2)/(Rs*Cr)-r(x2-P_lv)/(Cr*Rm), (x2-x3)/(Rs*Cs)+x5/Cs, -x5/Ca+r(P_lv-x4)/(Ca*Ra), (x4-x3-Rc*x5)/Ls]
return dydt
def getslope(y1, y2, y3, x1, x2, x3):
sum_x = x1 + x2 + x3
sum_y = y1 + y2 + y3
sum_xy = x1*y1 + x2*y2 + x3*y3
sum_xx = x1*x1 + x2*x2 + x3*x3
# calculate the coefficients of the least-squares line
n = 3
slope = (n*sum_xy - sum_x*sum_y) / (n*sum_xx - sum_x*sum_x)
return slope
### ODE: for each t (here fixed), gives dy/dt as a function of y(t) at that t, so can be used for integrating the vector y over time
#it is run for each t going from 0 to tmax
def lvad_ode(y, t, Rs, Rm, Ra, Rc, Ca, Cs, Cr, Ls, Emax, Emin, Tc, Vd, ratew):
#from simaan2008dynamical:
Ri = 0.0677
R0 = 0.0677
Rk = 0.0
x1bar = 1.
alpha = -3.5
Li = 0.0127
L0 = 0.0127
b0 = -0.296
b1 = -0.027
b2 = 9.9025e-7
x1, x2, x3, x4, x5, x6, x7 = y #here y is a vector of 5 values (not functions), at time t, used for getting (dy/dt)(t)
P_lv = Plv(x1+Vd,Emax,Emin,t,Tc,Vd)
if (P_lv <= x1bar): Rk = alpha * (P_lv - x1bar)
Lstar = Li + L0 + b1
Lstar2 = -Li -L0 +b1
Rstar = Ri + R0 + Rk + b0
dydt = [-x6 + r(x2-P_lv)/Rm-r(P_lv-x4)/Ra, (x3-x2)/(Rs*Cr)-r(x2-P_lv)/(Cr*Rm), (x2-x3)/(Rs*Cs)+x5/Cs, -x5/Ca+r(P_lv-x4)/(Ca*Ra) + x6/Ca, (x4-x3)/Ls-Rc*x5/Ls, -P_lv / Lstar2 + x4/Lstar2 + (Ri+R0+Rk-b0) / Lstar2 * x6 - b2 / Lstar2 * x7**2, ratew]
return dydt
#returns pv loop and ef when there is no lvad:
def f_nolvad(Rs, Rm, Ra, Rc, Ca, Cs, Cr, Ls, Emin, Vd, Tc, start_v, Emax, showpvloop):
N = 20
start_pla = float(start_v*Elastance(Emax, Emin, 0.0, Tc))
start_pao = 75.
start_pa = start_pao
start_qt = 0.0 #aortic flow is Q_T and is 0 at ED, also see Fig5 in simaan2008dynamical
y0 = [start_v, start_pla, start_pa, start_pao, start_qt]
t = np.linspace(0, Tc*N, int(60000*N)) #spaced numbers over interval (start, stop, number_of_steps), 60000 time instances for each heart cycle
#changed to 60000 for having integer positions for Tmax
#obtain 5D vector solution:
sol = odeint(heart_ode0, y0, t, args = (Rs, Rm, Ra, Rc, Ca, Cs, Cr, Ls, Emax, Emin, Tc,Vd)) #t: list of values
result_Vlv = np.array(sol[:, 0]) + Vd
result_Plv = np.array([Plv(v+Vd, Emax, Emin, xi, Tc, Vd) for xi,v in zip(t,sol[:, 0])])
#if showpvloop: plt.plot(result_Vlv[18*60000:20*60000], result_Plv[18*60000:20*60000], color='black', label='Without LVAD')
ved = sol[19*60000, 0] + Vd
ves = sol[200*int(60/Tc)+9000+19*60000, 0] + Vd
ef = (ved-ves)/ved * 100.
minv = min(result_Vlv[19*60000:20*60000-1])
minp = min(result_Plv[19*60000:20*60000-1])
result_pao = np.array(sol[:, 3])
pao_ed = min(result_pao[(N-1)*60000:N*60000-1])
pao_es = max(result_pao[(N-1)*60000:N*60000-1])
return ef, pao_ed, pao_es, ((ved - ves) * 60/Tc ) / 1000, sol[19*60000, 0], sol[19*60000, 1], sol[19*60000, 2], sol[19*60000, 3], sol[19*60000, 4], result_Vlv[18*60000:20*60000], result_Plv[18*60000:20*60000]
#returns the w at which suction occurs: (i.e. for which the slope of the envelopes of x6 becomes negative)
def get_suctionw(Rs, Rm, Ra, Rc, Ca, Cs, Cr, Ls, Emin, Vd, Tc, start_v, Emax, y00, y01, y02, y03, y04, w0, x60, ratew): #slope is slope0 for w
N = 70
start_pla = float(start_v*Elastance(Emax, Emin, 0.0, Tc))
start_pao = 75.
start_pa = start_pao
start_qt = 0 #aortic flow is Q_T and is 0 at ED, also see Fig5 in simaan2008dynamical
y0 = [start_v, start_pla, start_pa, start_pao, start_qt, x60, w0]
y0 = [y00, y01, y02, y03, y04, x60, w0]
ncycle = 20000
n = N * ncycle
sol = np.zeros((n, 7))
t = np.linspace(0., Tc * N, n)
for j in range(7):
sol[0][j] = y0[j]
result_Vlv = []
result_Plv = []
result_x6 = []
result_x7 = []
envx6 = []
timesenvx6 = []
slopes = []
ws = []
minx6 = 99999
tmin = 0
tlastupdate = 0
lastw = w0
update = 1
#solve the ODE step by step by adding dydt*dt:
for j in range(0, n-1):
#update y with dydt * dt
y = sol[j]
dydt = lvad_ode(y, t[j], Rs, Rm, Ra, Rc, Ca, Cs, Cr, Ls, Emax, Emin, Tc, Vd, ratew)
for k in range(7):
dydt[k] = dydt[k] * (t[j+1] - t[j])
sol[j+1] = sol[j] + dydt
#update the min of x6 in the current cylce. also keep the time at which the min is obtained (for getting the slope later)
if (minx6 > sol[j][5]):
minx6 = sol[j][5]
tmin = t[j]
#add minimum of x6 once each cycle ends: (works). then reset minx6 to 99999 for calculating again the minimum
if (j%ncycle==0 and j>1):
envx6.append(minx6)
timesenvx6.append(tmin)
minx6 = 99999
if (len(envx6)>=3):
slope = getslope(envx6[-1], envx6[-2], envx6[-3], timesenvx6[-1], timesenvx6[-2], timesenvx6[-3])
slopes.append(slope)
ws.append(y[6])
for i in range(n):
result_x6.append(sol[i, 5])
result_x7.append(sol[i, 6])
suction_w = 0
for i in range(2, len(slopes)):
if (slopes[i] < 0):
suction_w = ws[i-1]
break
return suction_w
def f_lvad(Rs, Rm, Ra, Rc, Ca, Cs, Cr, Ls, Emin, Vd, Tc, start_v, Emax, c, slope, w0, x60, y00, y01, y02, y03, y04): #slope is slope0 for w
N = 70
y0 = [y00, y01, y02, y03, y04, x60, w0]
ncycle = 10000
n = N * ncycle
sol = np.zeros((n, 7))
t = np.linspace(0., Tc * N, n)
for j in range(7):
sol[0][j] = y0[j]
result_Vlv = []
result_Plv = []
result_x6 = []
result_x7 = []
envx6 = []
timesenvx6 = []
minx6 = 99999
tmin = 0
tlastupdate = 0
lastw = w0
update = 1
ratew = 0 #6000/60
#solve the ODE step by step by adding dydt*dt:
for j in range(0, n-1):
#update y with dydt * dt
y = sol[j]
dydt = lvad_ode(y, t[j], Rs, Rm, Ra, Rc, Ca, Cs, Cr, Ls, Emax, Emin, Tc, Vd, ratew)
for k in range(7):
dydt[k] = dydt[k] * (t[j+1] - t[j])
sol[j+1] = sol[j] + dydt
#update the min of x6 in the current cylce. also keep the time at which the min is obtained (for getting the slope later)
if (minx6 > sol[j][5]):
minx6 = sol[j][5]
tmin = t[j]
#add minimum of x6 once each cycle ends: (works). then reset minx6 to 99999 for calculating again the minimum
if (j%ncycle==0 and j>1):
envx6.append(minx6)
timesenvx6.append(tmin)
minx6 = 99999
#update w (if 0.005 s. have passed since the last update):
if (slope<0):
update = 0
if (t[j+1] - tlastupdate > 0.005 and slope>0 and update==1): #abs(slope)>0.0001
# if there are enough points of envelope: calculate slope:
if (len(envx6)>=3):
slope = getslope(envx6[-1], envx6[-2], envx6[-3], timesenvx6[-1], timesenvx6[-2], timesenvx6[-3])
sol[j+1][6] = lastw + c * slope
#otherwise: take arbitrary rate (see Fig. 16a in simaan2008dynamical)
else:
sol[j+1][6] = lastw + 0.005 * slope
#save w(k) (see formula (8) simaan2008dynamical) and the last time of update t[j] (will have to wait 0.005 s for next update of w)
tlastupdate = t[j+1]
lastw = sol[j+1][6]
#save functions and print MAP, CO:
map = 0
Pao = []
for i in range(n):
result_Vlv.append(sol[i, 0] + Vd)
result_Plv.append(Plv(sol[i, 0]+Vd, Emax, Emin, t[i], Tc, Vd))
result_x6.append(sol[i, 5])
result_x7.append(sol[i, 6])
Pao.append(sol[i, 3])
colors0=np.zeros((len(result_Vlv[65*ncycle:70*ncycle]), 3))
for col in colors0:
col[0]=41/255
col[1]=128/255
col[2]=205/255
#get co and ef:
ved = max(result_Vlv[50 * ncycle:52 * ncycle])
ves = min(result_Vlv[50 * ncycle:52 * ncycle])
#ves = result_Vlv[50 * ncycle + int(ncycle * 0.2 /Tc + 0.15 * ncycle)]
ef = (ved-ves)/ved*100
CO = ((ved - ves) * 60/Tc ) / 1000
#get MAP:
for i in range(n - 5*ncycle, n):
map += sol[i, 2]
map = map/(5*ncycle)
result_pao = np.array(sol[:, 3])
pao_ed = min(Pao[50 * ncycle:52 * ncycle])
pao_es = max(Pao[50 * ncycle:52 * ncycle])
return ef, pao_ed, pao_es, CO, map, result_Vlv[65*ncycle:70*ncycle], result_Plv[65*ncycle:70*ncycle]
#############################
## Demo functions
def generate_example():
# get random input
data_path = 'EchoNet-Dynamic'
image_data = Echo(root = data_path, split = 'all', target_type=['Filename','LargeIndex','SmallIndex'])
image_loaded_data = DataLoader(image_data, batch_size=30, shuffle=True)
val_data = next(iter(image_loaded_data))
#create_echo_clip(val_data,'test')
val_seq = val_data[0]
val_tensor = torch.tensor(val_seq, dtype=torch.float32)
n=random.randint(0, 27)
results = model(val_tensor)[n]
filename = val_data[1][0][n]
video = f"EchoNet-Dynamic/Videos/{filename}"
plot, Rm, Ra, Emax, Emin, Vd,Tc, start_v = pvloop_simulator(Rm=round(results[4].item(),2), Ra=round(results[5].item(),2), Emax=round(results[2].item(),2), Emin=round(results[3].item(),2), Vd=round(results[6].item(),2), Tc=round(results[0].item(),2), start_v=round(results[1].item(),2))
video = video.replace("avi", "mp4")
#video = f"""<video height='500' width='500' autoplay loop muted>
# <source src={video_file} type='video/mp4'/>
# </video>"""
animated = "prediction.mp4" #"""<!DOCTYPE html>
#<html>
#<body>
#<video height='500' width='500' controls>
#<source src='prediction.mp4' type='video/mp4'/>
# Your browser does not support the video tag.
#</video>
# </body>
# </html>
# """
#"prediction.mp4"
#<video height='500' width='500' autoplay loop muted>
# <source src='prediction.mp4' type='video/mp4'/>
# </video>""" # style="width:48px;height:48px;" # "<img src='prediction.gif' alt='pv_loop'>" # "prediction.mp4"
return video, animated, Rm, Ra, Emax, Emin, Vd, Tc, start_v
def lvad_plots(Rm, Ra, Emax, Emin, Vd, Tc, start_v, beta, loop_simulated=True):
ncycle = 10000
Rs = 1.
Rc = 0.0398
Ca= 0.08
Cs= 1.33
Cr= 4.4
Ls=0.0005
#get values for periodic loops:
ef_nolvad, pao_ed, pao_es, co_nolvad, y00, y01, y02, y03, y04, Vlv0, Plv0 = f_nolvad(Rs, Rm, Ra, Rc, Ca, Cs, Cr, Ls, Emin, Vd,Tc, start_v, Emax, 0.0)
#pao_eds = [pao_ed]
#pao_ess = [pao_es]
#get suction w: (make w go linearly from w0 to w0 + maxtime * 400, and find w at which suction occurs)
w0 = 5000.
ratew = 400.
x60 = 0.
suctionw = get_suctionw(Rs, Rm, Ra, Rc, Ca, Cs, Cr, Ls, Emin, Vd, Tc, start_v, Emax, y00, y01, y02, y03, y04, w0, x60, ratew)
#gamma = 1.8
c = 0.065 #(in simaan2008dynamical: 0.67, but too fast -> 0.061 gives better shape)
slope0 = 100.
w0 = suctionw * beta #if doesn't work (x6 negative), change gamma down to 1.4 or up to 2.1 # switch to beta = 1/gamma 3/12 for interpretability
#compute new pv loops and ef with lvad added:
new_ef, pao_ed, pao_es, CO, MAP, Vlvs, Plvs = f_lvad(Rs, Rm, Ra, Rc, Ca, Cs, Cr, Ls, Emin, Vd, Tc, start_v, Emax, c, slope0, w0, x60, y00, y01, y02, y03, y04)
# Create the figure and the loop that we will manipulate
N = 2
fig, ax = plt.subplots(figsize=(6, 4))
plt.ylim((0,220))
plt.xlim((0,250))
start = (N-2)*60000
end = (N)*60000
#point1 = ax.scatter(Vlv0[start:(start+1)], Plv0[start:(start+1)], c="b", s=5)#, label='End Diastole')
if loop_simulated:
#line1 = ax.plot(Vlv0[start:end], Plv0[start:end], lw=1, color='b',label='No LVAD')
#point1 = ax.scatter(Vlv0[start:end], Plv0[start:end], c="b", s=5)#, label='End Diastole')
line2 = ax.plot(Vlvs[start:(start+1)], Plvs[start:(start+1)], lw=1, color=(78/255, 192/255, 44/255), label=f"LVAD, ω(0)= {round(w0,2)}r/min")
point2 = ax.scatter(Vlvs[start:(start+1)], Plvs[start:(start+1)], color=(78/255, 192/255, 44/255), s=5)#, label='End Diastole')
#point = ax.scatter(volumes[start:(start+1)], pressures[start:(start+1)], c="b", s=5, label='End Systole')
#else:
#line1 = ax.plot(Vlv0, Plv0, color='blue', label='No LVAD') #blue
#line2 = ax.plot(Vlvs, Plvs, color=(78/255, 192/255, 44/255), label=f"LVAD, ω(0)= {round(w0,2)}r/min") #green
ax.set_xlabel('LV Volume (ml)')
ax.set_ylabel('LV Pressure (mmHg)')
# adjust the main plot to make room for the sliders
# fig.subplots_adjust(left=0.25, bottom=0.25)
def update(frame):
# update to add more of the loop
end = (N-2)*60000+800 * frame
#x = Vlv0[start:end]
#y = Plv0[start:end]
x2 = Vlvs[start:end]
y2 = Plvs[start:end]
#ax.plot(x2, y2, lw=1, color='b',label='No LVAD')
ax.plot(Vlv0[start:(N)*60000], Plv0[start:(N)*60000], lw=1, color='b',label='No LVAD')
ax.plot(x2, y2, lw=1, color=(78/255, 192/255, 44/255), label=f"LVAD, ω(0)= {round(w0,2)}r/min")
plt.legend(loc='upper left', framealpha=1)
if loop_simulated:
# plt.title('', fontsize=16)
anim = animation.FuncAnimation(fig, partial(update), frames=110, interval=30)
anim.save("simulated_lvad.mp4")
anim_plot = "simulated_lvad.mp4"
return anim_plot, round(ef_nolvad,2), round(new_ef,2), round(co_nolvad,2), round(CO, 2)
else:
return plt, round(ef_nolvad,2), round(new_ef,2), round(co_nolvad,2), round(CO, 2)
title = "<h1 style='text-align: center; margin-bottom: 1rem'> Med-Real2Sim: Non-Invasive Medical Digital Twins using Physics-Informed Self-Supervised Learning </h1>"
description = """
<p style='text-align: center'> Keying Kuang, Frances Dean, Jack B. Jedlicki, David Ouyang, Anthony Philippakis, David Sontag, Ahmed Alaa <br></p>
<p> We develop methodology for predicting digital twins from non-invasive cardiac ultrasound images in <a href='https://arxiv.org/abs/2403.00177'>Non-Invasive Medical Digital Twins using Physics-Informed Self-Supervised Learning</a>. Check out our <a href='https://github.com/AlaaLab/CardioPINN' target='_blank'>code.</a> \n \n
We demonstrate the ability of our model to predict left ventricular pressure-volume loops using image data here. To run example predictions on samples from the <a href='https://echonet.github.io/dynamic/'>EchoNet</a> dataset, click the first button. \n \n
</p>
"""
title2 = "<h3 style='text-align: center'> Physics-based model simulation</h3>"
description2 = """
\n \n
Our model uses a hydraulic analogy model of cardiac function from <a href='https://ieeexplore.ieee.org/document/4729737/keywords#keywords'>Simaan et al 2008</a>. Below you can input values of predicted parameters and output a simulated pressure-volume loop predicted from the <a href='https://ieeexplore.ieee.org/document/4729737/keywords#keywords'>Simaan et al 2008</a> model, which is an ordinary differential equation. Tune parameters and press 'Run simulation.'
"""
description3 = """
\n\n
This model can incorporate a tunable left-ventricular assistance device (LVAD) for in-silico experimentation. Click to view the effect of adding an LVAD to the simulated PV loop.
"""
gr.Markdown(title)
gr.Markdown(description)
with gr.Blocks() as demo:
# text
gr.Markdown("<h1 style='text-align: center; margin-bottom: 1rem'>" + title + "</h1>")
gr.Markdown(description)
with gr.Row():
with gr.Column(scale=1.5, min_width=100):
generate_button = gr.Button("Load sample echocardiogram and generate result")
with gr.Row():
video = gr.PlayableVideo(autoplay='true',loop='true',width=300,height=300) # gr.HTML() #
plot = gr.PlayableVideo(autoplay='true',loop='true',width=300,height=300) # gr.HTML() #
with gr.Row():
Rm = gr.Number(label="Mitral valve circuit resistance (Rm) mmHg*s/ml:")
Ra = gr.Number(label="Aortic valve circuit resistance (Ra) mmHg*s/ml:")
Emax = gr.Number(label="Maximum elastance (Emax) mmHg/ml:")
Emin = gr.Number(label="Minimum elastance (Emin) mmHg/ml:")
Vd = gr.Number(label="Theoretical zero pressure volume (Vd) ml:")
Tc = gr.Number(label="Cycle duration (Tc) s:")
start_v = gr.Number(label="Initial volume (start_v) ml:")
gr.Markdown(title2)
gr.Markdown(description2)
simulation_button = gr.Button("Run simulation")
with gr.Row():
sl1 = gr.Slider(0.005, 0.1, value=.005, label="Rm (mmHg*s/ml)")
sl2 = gr.Slider(0.0001, 0.25, value=.0001, label="Ra (mmHg*s/ml)")
sl3 = gr.Slider(0.5, 3.5, value=.5, label="Emax (mmHg/ml)")
sl4 = gr.Slider(0.02, 0.1, value= .02, label="Emin (mmHg/ml)")
sl5 = gr.Slider(4.0, 25.0, value= 4.0, label="Vd (ml)")
sl6 = gr.Slider(0.4, 1.7, value= 0.4, label="Tc (s)")
sl7 = gr.Slider(0.0, 280.0, value= 140., label="start_v (ml)")
with gr.Row():
simulation = gr.PlayableVideo(autoplay='true',loop='true',width=300,height=300) # gr.Plot()
gr.Markdown(description3)
LVAD_button = gr.Button("Add LVAD")
with gr.Row():
beta = gr.Slider(.4, 1.0, value= 1.4, label="Pump speed parameter:")
with gr.Row():
lvad = gr.PlayableVideo(autoplay='true',loop='true',width=300,height=300) # gr.Plot()
with gr.Row():
EF_o = gr.Number(label="Ejection fraction (EF) before LVAD:")
EF_n = gr.Number(label="Ejection fraction (EF) after LVAD:")
CO_o = gr.Number(label="Cardiac output before LVAD:")
CO_n = gr.Number(label="Cardiac output after LVAD:")
#MAP_n = gr.Number(label="Mean arterial pressure (MAP) after LVAD:")
generate_button.click(fn=generate_example, outputs = [video,plot,Rm,Ra,Emax,Emin,Vd,Tc,start_v])
simulation_button.click(fn=pvloop_simulator_plot_only, inputs = [sl1,sl2,sl3,sl4,sl5,sl6,sl7], outputs = [simulation])
LVAD_button.click(fn=lvad_plots, inputs = [sl1,sl2,sl3,sl4,sl5,sl6,sl7,beta], outputs = [lvad, EF_o, EF_n, CO_o, CO_n])
demo.launch()